"uuid","repository link","title","author","contributor","publication year","abstract","subject topic","language","publication type","publisher","isbn","issn","patent","patent status","bibliographic note","access restriction","embargo date","faculty","department","research group","programme","project","coordinates"
"uuid:a8e45e20-4b95-4341-9a0a-89a99486d883","http://resolver.tudelft.nl/uuid:a8e45e20-4b95-4341-9a0a-89a99486d883","Effect of H2S and HCl contaminants on nickel and ceria pattern anode solid oxide fuel cells","Tabish, A.N. (TU Delft Energy Technology; University of Engineering & Technology Lahore); Patel, H.C. (TU Delft Energy Technology; SBM Offshore, Schiedam); Mani, A. (Energy Academy Europe (ESRIG)); Schoonman, J. (TU Delft ChemE/Materials for Energy Conversion and Storage); Aravind, P.V. (TU Delft Energy Technology; Rijksuniversiteit Groningen)","","2022","In this study, with the motivation of elucidating the effect of H2S and HCl on solid oxide fuel cell anodes, nickel and ceria pattern anodes are prepared on yttrium-stabilized zirconia electrolyte, and the effect of H2S and HCl on their performance is tested using electrochemical impedance spectroscopy. However, it has been found that while H2S adversely impacts both nickel and ceria, the poisoning caused is reversible for nickel and only partially reversible for ceria. Poisoning kinetics are similar and fast for both materials, while recovery kinetics are slower for ceria than nickel. High sulfur coverage is the rate-limiting factor inferred from the elementary kinetic modeling. Unlike H2S, the presence of HCl appeared to be favorable for electrochemical oxidation as the polarization resistance of both pattern electrode cells decreased upon feeding HCl contaminated hydrogen gas. Similar behavior has not been reported previously, and the conclusion regarding underlying mechanisms requires further investigation.","Ceria; HS; HCl; Pattern anode; SOFC poisoning","en","journal article","","","","","","Green Open Access added to TU Delft Institutional Repository 'You share, we take care!' - Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.","","2023-07-01","","","Energy Technology","","",""
"uuid:0505980b-ec35-4fff-977a-2bb8cb694677","http://resolver.tudelft.nl/uuid:0505980b-ec35-4fff-977a-2bb8cb694677","Thermodynamics of a fast-moving Greenlandic outlet glacier revealed by fiber-optic distributed temperature sensing","Law, Robert (Scott Polar Research Institute); Christoffersen, Poul (Scott Polar Research Institute); Hubbard, Bryn (Aberystwyth University); Doyle, Samuel H. (Aberystwyth University); Chudley, Thomas R. (Scott Polar Research Institute); Schoonman, Charlotte M. (Scott Polar Research Institute); Bougamont, Marion (Scott Polar Research Institute); des Tombe, B.F. (TU Delft Water Resources); Schilperoort, B. (TU Delft Geoscience and Remote Sensing); Kechavarzi, Cedric (University of Cambridge); Booth, Adam (University of Leeds); Young, Tun Jan (Scott Polar Research Institute)","","2021","Measurements of ice temperature provide crucial constraints on ice viscosity and the thermodynamic processes occurring within a glacier. However, such measurements are presently limited by a small number of relatively coarse-spatial-resolution borehole records, especially for ice sheets. Here, we advance our understanding of glacier thermodynamics with an exceptionally high-vertical-resolution (∼0.65 m), distributed-fiber-optic temperature-sensing profile from a 1043-m borehole drilled to the base of Sermeq Kujalleq (Store Glacier), Greenland. We report substantial but isolated strain heating within interglacial-phase ice at 208 to 242 m depth together with strongly heterogeneous ice deformation in glacial-phase ice below 889 m. We also observe a high-strain interface between glacial- and interglacial-phase ice and a 73-m-thick temperate basal layer, interpreted as locally formed and important for the glacier's fast motion. These findings demonstrate notable spatial heterogeneity, both vertically and at the catchment scale, in the conditions facilitating the fast motion of marine-terminating glaciers in Greenland.","","en","journal article","","","","","","","","","","Geoscience and Remote Sensing","Water Resources","","",""
"uuid:a69468ad-23b1-420d-89b1-3da453ac442c","http://resolver.tudelft.nl/uuid:a69468ad-23b1-420d-89b1-3da453ac442c","A detailed look into hydrogen electrochemical oxidation on ceria anodes","Tabish, A.N. (TU Delft Energy Technology; University of Engineering and Technology Lahore); Patel, H.C. (Dutch Institute for Fundamental Energy Research); Schoonman, J. (TU Delft ChemE/Materials for Energy Conversion and Storage); Aravind, P.V. (TU Delft Energy Technology)","","2018","Using the Nernst-Planck-Poisson model and a detailed reaction mechanism, we studied the hydrogen electrochemical oxidation on a ceria anode. Resistances caused by surface kinetics, and bulk transport of oxide-ion vacancies and electrons are computed individually to identify the dominant resistive process. The effect of operating conditions like temperature and gas-phase composition on the polarization resistance is evaluated and compared with the experimental data obtained by Electrochemical Impedance Spectroscopy (EIS). The rate-determining step is found to be the charge-transfer reaction in which hydrogen adsorbs at the surface oxide ions and forms hydroxyls along with the charge-transfer to adjacent cerium ions. Based on the rate-determining step, the exchange-current density is also calculated and validated with the experimental data.","Ceria; Elementary kinetics; NPP model; Pattern anodes; SOFC","en","journal article","","","","","","Accepted Author Manuscript","","2020-07-07","","","Energy Technology","","",""
"uuid:efa89af9-1006-4cb4-8cc9-4dd15061ee62","http://resolver.tudelft.nl/uuid:efa89af9-1006-4cb4-8cc9-4dd15061ee62","Simultaneous Voltammetric Detection of Carbaryl and Paraquat Pesticides on Graphene-Modified Boron-Doped Diamond Electrode","Pop, Aniela (Politehnica University of Timisoara); Manea, Florica (Politehnica University of Timisoara); Flueras, Adriana (Politehnica University of Timisoara); Schoonman, J. (TU Delft ChemE/Materials for Energy Conversion and Storage)","","2017","Monitoring of pesticide residues in food, beverages, and the environment requires fast, versatile, and sensitive analyzing methods. Direct electrochemical detection of pesticides could represent an efficient solution. Adequate electrode material, electrochemical technique, and optimal operation parameters define the detection method for practical application. In this study, cyclic voltammetric and differential pulse voltammetric techniques were used in order to individually and simultaneously detect two pesticides, i.e., carbaryl (CR) and paraquat (PQ), from an acetate buffer solution and also from natural apple juice. A graphene-modified boron-doped diamond electrode, denoted BDDGR, was obtained and successfully applied in the simultaneous detection of CR and PQ pesticides, using the differential pulse voltammetric technique with remarkable electroanalytical parameters in terms of sensitivity: 33.27 μA μM−1 cm−2 for CR and 31.83 μA μM−1 cm−2 for PQ. These outstanding results obtained in the acetate buffer supporting electrolyte allowed us to simultaneously detect the targeted pesticides in natural apple juice.","direct electrochemical detection; carbaryl; paraquat; simultaneous detection; pesticide residues; natural juice","en","journal article","","","","","","","","","","","ChemE/Materials for Energy Conversion and Storage","","",""
"uuid:ee965457-b664-4856-a067-0f031e6b22b0","http://resolver.tudelft.nl/uuid:ee965457-b664-4856-a067-0f031e6b22b0","Fast simultaneous electrochemical detection of tetracycline and fluoxetine in water","Ardelean, Magdalena (Politehnica University of Timisoara); Pode, Rodica (Politehnica University of Timisoara); Schoonman, J. (TU Delft ChemE/Materials for Energy Conversion and Storage); Pop, Aniela (Politehnica University of Timisoara); Manea, Florica (Politehnica University of Timisoara)","","2017","The electrochemical methods-based protocol for simultaneous detection of tetracycline (TC) from antibiotics class and fluoxetine (FXT) from anti-depressive pharmaceuticals class, which belongs to emerging pollutants from water, was developed in this study using carbon nanofiber-epoxy composite electrode (CNF). The electrochemical behaviour of each pharmaceutical on CNF was considered the basis for simultaneous detection of both pharmaceuticals from water. TC electrooxidation on CNF occurred in two steps and, consequently, two detection potentials are considered. FXT electrooxidation occurred in one step that is overlaid to the first step of TC detection, this step being considered as cumulative for both pharmaceuticals. Each electrochemical method of cyclic voltammetry (CV) and differential-pulsed voltammetry (DPV) allowed detecting cumulative presence of TC and FXT at the detection potential ranged between 0.65 and 0.815 V vs. SCE and the selective detection of TC at the detection potential ranged between 0.956 and 1.14 V vs. SCE. The electroanalytical parameters related to the lowest limit of detection and sensitivity recommended this electrode to exhibit the potential for practical applications in the electrochemical detection of certain pharmaceuticals as emerging pollutants from water.","Carbon nanofiber composite electrode.; Fluoxetine; Simultaneous electrochemical detection; Tetracycline","en","journal article","","","","","","","","","","","ChemE/Materials for Energy Conversion and Storage","","",""
"uuid:47f7e8cc-8092-49ab-93d9-699e5f86e25f","http://resolver.tudelft.nl/uuid:47f7e8cc-8092-49ab-93d9-699e5f86e25f","TIO2-modified zeolite-carbon nanotubes composite electrode for photoelectrodegradation of pentachlorophenol from water under uv irradiation","Jakab, Agnes (Politehnica University of Timisoara); Pode, Rodica (Politehnica University of Timisoara); Pop, Aniela (Politehnica University of Timisoara); Schoonman, J. (TU Delft ChemE/Materials for Energy Conversion and Storage); Orha, Corina (National Institute for Research and Development in Electrochemistry and Condensed Matter); Manea, Florica (Politehnica University of Timisoara)","","2017","Three types of composite electrode materials, i.e. carbon nanotubes-epoxy (CNT), zeolite-carbon nanotubes-epoxy (ZCNT) and TiO2-modified zeolite-carbon nanotubes-epoxy (TiZCNT), were synthesized, morphologically and electrically characterized, and tested in the photoelectrodegradation of pentachlorophenol (PCP) from water. The electrode composite materials were synthesized by the two-roll mill method, and a higher porosity of zeolite-modified electrode, caused by the zeolite incorporation, was noticed by means of scanning electron microscopy. Electroactive surface area, determined by classical methods using cyclic voltammetry (CV), and electric conductivity, determined by the four-point method, were negatively affected by the presence of zeolite. The photoelectrochemical behaviour of the electrodes, under ultraviolet (UV) irradiation, towards the pentachlorophenol oxidation was studied, and the photoelectrocatalytic activity of each electrode was determined. The PCP oxidation occurred in two steps at +0.65 V and +0.94 V vs. saturated calomel electrode SCE under UV irradiation. The oxidation peak recorded at +0.65 V vs. SCE appeared only under UV irradiation and it is considered that the photoelectrooxidation peak corresponded to PCP photoelectrooxidation. Also, the enhancement of PCP electrooxidation at +0.94 V vs. SCE was noticed under UV irradiation, which confirmed the photelectrocatalytic activity. The performance of the PCP degradation process, expressed as degradation efficiency and electrochemical efficiency, recommended the operation of photoelectrocatalysis at a bias voltage application of +0.8 V/SCE, while the mineralization degree recommended a bias voltage value of +1.5 V/SCE.","Pentachlorophenol; Photoelectrodegradation.; TiO2-modified zeolite-carbon nanotubes-epoxy composite electrode; Wastewater treatment","en","journal article","","","","","","","","","","","ChemE/Materials for Energy Conversion and Storage","","",""
"uuid:51d08c0b-f457-42ea-bceb-4c1ce75aed34","http://resolver.tudelft.nl/uuid:51d08c0b-f457-42ea-bceb-4c1ce75aed34","Electrochemical Selective and Simultaneous Detection of Diclofenac and Ibuprofen in Aqueous Solution Using HKUST-1 Metal-Organic Framework-Carbon Nanofiber Composite Electrode","Motoc, Sorina (Romanian Academy); Manea, F. (Politehnica University of Timisoara); Iacob, Adriana (S.C. DATCOMP S.R.L); Martinez Joaristi, A.E. (TU Delft ChemE/Catalysis Engineering); Gascon, Jorge (TU Delft ChemE/Catalysis Engineering); Pop, A.C. (Politehnica University of Timisoara); Schoonman, J. (TU Delft ChemE/Materials for Energy Conversion and Storage)","","2016","In this study, the detection protocols for the individual, selective, and simultaneous determination of ibuprofen (IBP) and diclofenac (DCF) in aqueous solutions have been developed using HKUST-1 metal-organic framework-carbon nanofiber composite (HKUST-CNF) electrode. The morphological and electrical characterization of modified composite electrode prepared by film casting was studied by scanning electronic microscopy and four-point-probe methods. The electrochemical characterization of the electrode by cyclic voltammetry (CV) was considered the reference basis for the optimization of the operating conditions for chronoamperometry (CA) and multiple-pulsed amperometry (MPA). This electrode exhibited the possibility to selectively detect IBP and DCF by simple switching the detection potential using CA. However, the MPA operated under optimum working conditions of four potential levels selected based on CV shape in relation to the potential value, pulse time, and potential level number, and order allowed the selective/simultaneous detection of IBP and DCF characterized by the enhanced detection performance. For this application, the HKUST-CNF electrode exhibited a good stability and reproducibility of the results was achieved.","Chronoamperometry; Cyclic voltammetry; Diclofenac; Electrochemical selective and simultaneous detection; Ibuprofen; Metal-organic framework-carbon nanofiber composite electrode; Multiple-pulsed amperometry","en","journal article","","","","","","","","","","","ChemE/Catalysis Engineering","","",""
"uuid:04e2693b-5c1e-4fbc-b80a-27e6a9524ff6","http://resolver.tudelft.nl/uuid:04e2693b-5c1e-4fbc-b80a-27e6a9524ff6","Diffusion of solar energy use in the urban built environment supported by new design","Van Geenhuizen, M.S.; Schoonman, J.; Reinders, A.H.M.E.","","2012","Places of large potentials of sustainable energy production and places of energy consumption are often very different and separated by large distances across the globe. This paper first discusses potentials of solar technology in terms of global availability using PV technology and actual energy production. Solar energy is widely under-used and one way to reduce this is to improve production in low-energy places with high demand: large cities. According to this option, about 40% of the electricity consumption in the built environment could be produced by solar PV systems. To reach this goal we need appropriate solar PV energy conversion devices and energy storage systems. This paper discusses conditions in the built environment and functional and design qualities enabling an increased diffusion of the technologies. In a comparative analysis of PV technologies, the criteria taken into account encompass efficiency of the type of solar cell and commercial availability. Special attention is paid to the design features of different PV systems, like flexibility, colour and transparency that might help in their utilization as integrated in building material and ornaments in modern architecture. The same procedure is followed for electricity storage devices. The preliminary conclusion is that at present the freedom of design is largest for a combination of crystalline silicon PV cells and Li-ion batteries.","solar PV energy systems, battery storage systems, design qualities for the built environment","en","conference paper","Regional Science Association","","","","","","","","Industrial Design Engineering","Design Engineering","","","",""
"uuid:4310f877-1bf6-403b-bf41-8261d9effa74","http://resolver.tudelft.nl/uuid:4310f877-1bf6-403b-bf41-8261d9effa74","Silver-functionalized carbon nanofiber composite electrodes for ibuprofen detection","Manea, F.; Motoc, S.; Pop, A.; Remes, A.; Schoonman, J.","","2012","The aim of this study is to prepare and characterize two types of silver-functionalized carbon nanofiber (CNF) composite electrodes, i.e., silver-decorated CNF-epoxy and silver-modified natural zeolite-CNF-epoxy composite electrodes suitable for ibuprofen detection in aqueous solution. Ag carbon nanotube composite electrode exhibited the best electroanalytical parameters through applying preconcentration/differential-pulsed voltammetry scheme.","carbon nanofiber composite electrodes; Ssilver particles; electrochemical determination; ibuprofen","en","journal article","SpringerOpen","","","","","","","","Applied Sciences","Chemical Engineering","","","",""
"uuid:1f022094-6c7d-49c5-8d67-ae864d5f5f5f","http://resolver.tudelft.nl/uuid:1f022094-6c7d-49c5-8d67-ae864d5f5f5f","Diffusion of solar energy use in the urban built environment supported by new design","Van Geenhuizen, M.S.; Schoonman, J.; Reinders, A.H.M.E.","","2012","Places of large potentials of sustainable energy production and places of energy consumption are often very different and separated by large distances across the globe. This paper first discusses potentials of solar technology in terms of global availability using PV technology and actual energy production. Solar energy is widely under-used and one way to reduce this is to improve production in low-energy places with high demand: large cities. According to this option, about 40% of the electricity consumption in the built environment could be produced by solar PV systems. To reach this goal appropriate solar PV energy conversion devices and energy storage systems are needed. This paper discusses conditions in the built environment and functional and design qualities enabling an increased diffusion of the technologies. In a comparative analysis of PV technologies, the criteria taken into account encompass efficiency of the type of solar cell and commercial availability. Special attention is paid to the design features of different PV systems, like flexibility, colour and transparency that might help in their utilization as integrated in building material and ornaments in modern architecture. The same procedure is followed for electricity storage devices. The preliminary conclusion is that at present the freedom of design is largest for a combination of crystalline silicon PV cells and Li-ion batteries. Implications for urban policy will be discussed.","solar PV systems; battery storage systems; design qualities; built environment; cities","en","conference paper","","","","","","","","","Technology, Policy and Management","Innovation Systems","","","",""
"uuid:2592406a-960a-4aae-8ef6-0e53d6493090","http://resolver.tudelft.nl/uuid:2592406a-960a-4aae-8ef6-0e53d6493090","Copper-decorated carbon nanotubes-based composite electrodes for nonenzymatic detection of glucose","Pop, A.; Manea, F.; Orha, C.; Motoc, S.; Llinoiu, E.; Vaszilcsin, N.; Schoonman, J.","","2012","The aim of this study was to prepare three types of multiwall carbon nanotubes (CNT)-based composite electrodes and to modify their surface by copper electrodeposition for nonenzymatic oxidation and determination of glucose from aqueous solution. Copper-decorated multiwall carbon nanotubes composite electrode (Cu/CNT-epoxy) exhibited the highest sensitivity to glucose determination.","multiwall carbon nanotubes composite electrodes, copper particles, glucose, electrochemical determination","en","journal article","Springer-Verlag","","","","","","","","Applied Sciences","Chemical Engineering","","","",""
"uuid:875d52ca-852a-4c32-b929-9d7d02839bda","http://resolver.tudelft.nl/uuid:875d52ca-852a-4c32-b929-9d7d02839bda","Electrochemical Determination of Pentachlorophenol in Water on a Multi-Wall Carbon Nanotubes-Epoxy Composite Electrode","Remes, A.; Pop, A.; Manea, F.; Baciu, A.; Picken, S.J.; Schoonman, J.","","2012","The aim of this study was the preparation, characterization, and application of a multi-wall carbon nanotubes-epoxy composite electrode (MWCNT-EP) with 25%, wt. MWCNTs loading for the voltammetric/amperometric determination of pentachlorophenol (PCP) in aqueous solutions. The structural and morphological aspects of the MWCNT-EP composite electrode were examined by scanning electron microscopy. The electrical properties were characterized by direct-current conductivity measurements in relation with the percolation threshold. The electrochemical behavior of PCP at the MWCNT-EP composite electrode was investigated using cyclic voltammetry in 0.1 M Na2SO4 supporting electrolyte in order to establish the parameters for amperometric/voltammetric determination of PCP. The linear dependence of current vs. PCP concentrations was reached in a wide concentration range from 0.2 to 12 ?M PCP using cyclic voltammetry, differential-pulsed voltammetry, square-wave voltammetry, chronoamperometry, and multiple-pulsed amperometry techniques. The best electroanalytical performances of this composite electrode were achieved using a pre-concentration/square-wave voltammetric technique and also multiple-pulsed amperometry techniques envisaging the practical applications. The ease of preparation, high sensitivity, and stability of this composite electrode should open novel avenues and applications for fabricating robust sensors for detection of many important species.","multi-wall carbon nanotubes-epoxy composite electrode; electrochemical determination; pentachlorophenol; square-wave voltammetry; cyclic voltammetry","en","journal article","MDPI","","","","","","","","Applied Sciences","ChemE/Chemical Engineering","","","",""
"uuid:c32d353f-358c-48ad-a3f2-720656510f4b","http://resolver.tudelft.nl/uuid:c32d353f-358c-48ad-a3f2-720656510f4b","Electrical conductivity and defect chemistry of BaxSr1 - xCoyFe1 - yO3 - dBaxSr1?xCoyFe1?yO3? perovskites","Yáng, Z.; Harvey, A.S.; Infortuna, A.; Schoonman, J.; Gauckler, L.J.","","2010","Bulk BaxSr1 - xCoyFe1 - yO3 - dBaxSr1?xCoyFe1?yO3? compositions (BSCF) were synthesized by the solid-state reaction method. The electrical conductivity of ceramic bars was measured using a dc four-probe method as a function of temperature in air up to 970 °C. All compositions showed thermally activated p-type semi-conductivity up to ~450 °C and then a transition to metal-like conductivity. The small-polaron hopping p-type semi-conductivity depends on the oxygen nonstoichiometry, which increases with increasing temperature. Metal-like conductivity is attributed to the overlap of the transition metal d-electron orbitals with the oxygen p-orbitals. Strontium-rich compositions show higher conductivity. The Co/Fe ratio does not influence much the p-type semi-conduction. Iron-rich compositions revealed more metal-like conduction behavior. The degree of overlap between transition metal d-orbitals and oxygen p-orbitals depends on the Ba/Sr as well as on the Co/Fe ratios.","electrical conductivity; BSCF; mixed ionic and electronic conduction; perovskite; metal-insulator transition; cathode; solid oxide fuel cell; catalysis","en","journal article","Springer","","","","","","","","Applied Sciences","Chemical Engineering","","","",""
"uuid:6efc99ae-7b8a-440f-a2a4-4e5a0d4e2b34","http://resolver.tudelft.nl/uuid:6efc99ae-7b8a-440f-a2a4-4e5a0d4e2b34","Publisher's Note: Diffusion Impedance on Nickel/Gadolinia-Doped Ceria Anodes for Solid Oxide Fuel Cells [J. Electrochem. Soc., 156, B1417 (2009)]","Aravind, P.V.; Ouweltjes, J.P.; Schoonman, J.","","2009","","anodes; cerium compounds; diffusion; doping; gadolinium compounds; nickel; solid oxide fuel cells","en","journal article","The Electrochemical Society","","","","","","","","Mechanical, Maritime and Materials Engineering","Process and Energy","","","",""
"uuid:3e31f289-9f5c-4b24-a7d9-21c41d6a9a4d","http://resolver.tudelft.nl/uuid:3e31f289-9f5c-4b24-a7d9-21c41d6a9a4d","Electrosprayed Metal Oxide Semiconductor Films for Sensitive and Selective Detection of Hydrogen Sulfide","Ghimbeu, C.M.; Lumbreras, M.; Schoonman, J.; Siadat, M.","","2009","Semiconductor metal oxide films of copper-doped tin oxide (Cu-SnO2), tungsten oxide (WO3) and indium oxide (In2O3) were deposited on a platinum coated alumina substrate employing the electrostatic spray deposition technique (ESD). The morphology studied with scanning electron microscopy (SEM) and atomic force microscopy (AFM) shows porous homogeneous films comprising uniformly distributed aggregates of nano particles. The X-ray diffraction technique (XRD) proves the formation of crystalline phases with no impurities. Besides, the Raman cartographies provided information about the structural homogeneity. Some of the films are highly sensitive to low concentrations of H2S (10 ppm) at low operating temperatures (100 and 200 °C) and the best response in terms of Rair/Rgas is given by Cu-SnO2 films (2500) followed by WO3 (1200) and In2O3 (75). Moreover, all the films exhibit no cross-sensitivity to other reducing (SO2) or oxidizing (NO2) gases.","semiconductor metal oxide; electrostatic spray depositio; gas sensors; pollutant gases","en","journal article","MDPI AG","","","","","","","","Applied Sciences","ChemE/Chemical Engineering","","","",""
"uuid:35e3c4df-4504-4651-a4de-9d6643e5384a","http://resolver.tudelft.nl/uuid:35e3c4df-4504-4651-a4de-9d6643e5384a","Diffusion Impedance on Nickel/Gadolinia-Doped Ceria Anodes for Solid Oxide Fuel Cells","Aravind, P.V.; Ouweltjes, J.P.; Schoonman, J.","","2009","Electrochemical impedance measurements were carried out on symmetrical nickel/gadolinia-doped ceria test cells. For H2, N2, and H2O mixtures, the diffusion length obtained based on the impedance measurements is on the order of centimeters. This high value of the diffusion length is attributed to the flow field in the reactor. It is suggested that a detailed analysis of the gas flow field inside the test reactor is essential before interpreting the impedance measurements with various solid oxide fuel cell test configurations.","cerium compounds; electrochemical electrodes; electrochemical impedance spectroscopy; gadolinium compounds; nickel; solid oxide fuel cells","en","journal article","The Electrochemical Society","","","","","","","","Mechanical, Maritime and Materials Engineering","Process and Energy","","","",""
"uuid:75ab7d41-fd77-4fdc-aab2-301d1a0ca59b","http://resolver.tudelft.nl/uuid:75ab7d41-fd77-4fdc-aab2-301d1a0ca59b","Voltammetric Detection of Urea on an Ag-Modified Zeolite- Expanded Graphite-Epoxy Composite Electrode","Manea, F.; Pop, A.; Radovan, C.; Malchev, P.G.; Bebeselea, A.; Burtica, G.; Picken, S.J.; Schoonman, J.","","2008","In this paper, a modified expanded graphite composite electrode based on natural zeolitic volcanic tuff modified with silver (EG-Ag-Z-Epoxy) was developed. Cyclic voltammetry measurements revealed a reasonably fast electron transfer and a good stability of the electrode in 0.1 M NaOH supporting electrolyte. This modified electrode exhibited moderate electrocatalytic effect towards urea oxidation, allowing its determination in aqueous solution. The linear dependence of the current versus urea concentration was reached using square-wave voltammetry in the concentrations range of urea between 0.2 to 1.4 mM, with a relatively low limit of detection of 0.05 mM. A moderate enhancement of electroanalytical sensitivity for the determination of urea at EG-Ag-Z-Epoxy electrode was reached by applying a chemical preconcentration step prior to voltammetric/amperometric quantification.","urea determination; expanded graphite-Ag-zeolite-epoxy composite electrode; electrocatalytic effect","en","journal article","MDPI AG","","","","","","","","Applied Sciences","ChemE/Chemical Engineering","","","",""
"uuid:2d458a68-dbc4-4478-81d3-1b4122c2b7ed","http://resolver.tudelft.nl/uuid:2d458a68-dbc4-4478-81d3-1b4122c2b7ed","Time-of-flight studies on TiO2/CuInS2 heterojunctions","Hofhuis, J.; Schoonman, J.; Goossens, A.","","2008","Time-of-Flight (TOF) measurements have been performed on n-type TiO2/p-type CuInS2 heterojunctions. The TiO2 film thickness has been varied between 200 and 400 nm, while the CuInS2 film thickness has been fixed at 500 nm. The TOF response can be accurately modeled, if the potential drop across the p-n heterojunction with a large density of interface states is properly accounted for. Also electron transport in a space-charge region for a not fully depleted semiconductor has to be considered. The electron mobility in TiO2 is found to be 10?2?cm2?V?1?s?1, independent of the TiO2 layer thickness. The interface-state densities are 5×1011, 2×1012, and 6×1012?eV?1?cm?2 for 200, 300, and 400 nm thick TiO2 films, respectively.","copper compounds; electron mobility; indium compounds; interface states; p-n heterojunctions; titanium compounds","en","journal article","American Institute of Physics","","","","","","","","Applied Sciences","","","","",""
"uuid:0fdb47d8-2140-4abb-8325-9b59c1cab2b4","http://resolver.tudelft.nl/uuid:0fdb47d8-2140-4abb-8325-9b59c1cab2b4","Carbon-based Composite Electrodes: Preparation, Characterization and Application in Electroanalysis","Corb, I.; Manea, F.; Radovan, C.; Pop, A.; Burtica, G.; Malchev, P.G.; Picken, S.J.; Schoonman, J.","","2007","Electrodes based on carbon, i.e., expanded graphite (20%, wt.)-epoxy composite (20EG-Epoxy) and expanded graphite (20%, wt.)-polystyrene composite (20EG-PS) have been prepared, characterized using scanning electron microscopy (SEM) and cyclic voltammetry (CV), and tested as anodic sensors. The electrodes exhibited good mechanical resistance and low electrical resistances. Scan rate dependent cyclic voltammetry responses at 20EG-Epoxy and 20EG-PS composite electrodes, which were exemplified for thiourea (TU), a toxic sulphur organic compound selected as testing target analyte in 0.1 M Na2SO4 supporting electrolyte, were investigated. The obtained voltammetric data were in accordance with those for a random array of microelectrodes. The voltammetric and chronoamperometric detection results of TU in tap water samples, without a supplementary addition of supporting electrolyte, at 20EG-Epoxy electrode proved its use for direct analysis of environmental samples.","carbon-based composite electrode; microelectrode array behavio; thiourea; electroanalysis","en","journal article","MDPI AG","","","","","","","","Applied Sciences","ChemE/Chemical Engineering","","","",""
"uuid:71cefe99-bcc3-4f3d-bf1c-b604a6644e19","http://resolver.tudelft.nl/uuid:71cefe99-bcc3-4f3d-bf1c-b604a6644e19","Elucidation of homojunction formation in CuInS2 with impedance spectroscopy","Loef, R.; Schoonman, J.; Goossens, A.","","2007","Type transformation in CuInSe2 and CuInS2 solar cells is an important issue with far reaching consequences. In the present study, the presence of a p-n homojunction inside CuInS2 in a TiO2/CuInS2 device is revealed with a detailed impedance spectroscopy and capacitance study. A n-type CuInS2 film with a thickness of 40?nm is found at the TiO2 (n-type)/CuInS2 (p-type) interface. The effective donor density of this n-type film is 2×1017?cm?3 at 400?K and is higher than the effective acceptor density in the remaining p-type CuInS2, being 4×1016?cm?3 at 400?K. Both densities decrease upon increasing the temperature. This is explained by the activation of a CuIn? acceptor state in n-type CuInS2 and a thermally activated hole trap in p-type CuInS2.","capacitance; copper compounds; electric impedance; hole traps; impurity states; indium compounds; p-n junctions; solar cells; ternary semiconductors","en","journal article","American Institute of Physics","","","","","","","","Applied Sciences","DelftChemTech","","","",""
"uuid:fe0ee588-becc-440e-8a9d-7ff10671a66e","http://resolver.tudelft.nl/uuid:fe0ee588-becc-440e-8a9d-7ff10671a66e","A time-resolved microwave conductivity study of the optoelectronic processes in TiO2?In2S3?CuInS2 heterojunctions","Savenije, T.J.; Nanu, M.; Schoonman, J.; Goossens, A.","","2007","Photoinduced interfacial charge carrier generation, separation, trapping, and recombination in TiO2?In2S3?CuInS2 cells have been studied with time-resolved microwave conductivity (TRMC). Single layer, double layer, and complete triple layer configurations have been studied. Selective electronic excitation in one of the components is accomplished by using monochromatic pulsed laser excitation. In bare CuInS2 films and in TiO2?CuInS2 double layers, photoinduced charge carriers recombine on a subnanosecond time scale. This fast recombination slows down significantly when an In2S3 buffer layer is applied between TiO2 and CuInS2. In that case, the charge separation lifetime increases by more than one order of magnitude. A superlinear dependence of the TRMC signals on the incident laser intensity is observed for the triple layer configuration, which indicates saturation of electron traps in In2S3 or hole traps in CuInS2. Furthermore, TRMC signals from TiO2?In2S3?CuInS2 triple junctions and those from In2S3?CuInS2 double layers are identical, which shows that charge carrier separation exclusively takes place at the In2S3?CuInS2 interface.","titanium compounds; indium compounds; copper compounds; III-VI semiconductors; ternary semiconductors; semiconductor heterojunctions; high-frequency effects; electron traps; hole traps; electron-hole recombination","en","journal article","American Institute of Physics","","","","","","","","Applied Sciences","DelftChemTech","","","",""
"uuid:71313580-e49e-476b-898c-8a8ba3059404","http://resolver.tudelft.nl/uuid:71313580-e49e-476b-898c-8a8ba3059404","Electrochemical Oxidation and Determination of Oxalic Acid at an Exfoliated Graphite-Polystyrene Composite Electrode","Schoonman, J.; Manea, F.; Radovan, C.; Corb, I.; Pop, A.; Burtica, G.; Malchev, P.G.; Picken, S.J.","","2007","An exfoliated graphite-polystyrene composite electrode was evaluated as analternative electrode in the oxidation and the determination of oxalic acid in 0.1 M Na2SO4supporting electrolyte. Using CV, LSV, CA procedures, linear dependences I vs. C wereobtained in the concentrations range of oxalic acid between 0.5 to 3 mM, with LOD =0.05mM, and recovery degree of 98%, without need of surface renewing between successiveruns. The accuracy of the methods was evaluated as excellent comparing the detection resultswith that obtained using conventional KMnO4 titration method. In addition, the apparentdiffusion coefficient of oxalic acid D was found to be around 2.89 · 10-8 cm2·s-1 by CA andCV.","exfoliated graphite-polystyrene composite electrode; oxalic acid; electrochemical oxidation; electrochemical determination","en","journal article","MDPI","","","","","","","","Applied Sciences","","","","",""
"uuid:f614dbb4-1380-4177-bc85-3e7a21962ecd","http://resolver.tudelft.nl/uuid:f614dbb4-1380-4177-bc85-3e7a21962ecd","A parametric study of TiO2/CuInS2 nanocomposite solar cells: How cell thickness, buffer layer thickness, and TiO2 particle size affect performance","O'Hayre, R.; Nanu, M.; Schoonman, J.; Goossens, A.","","2007","","","en","journal article","IOP","","","","","","","","Applied Sciences","","","","",""
"uuid:35d25ade-32d3-4ae6-8e5a-04bbe490b711","http://resolver.tudelft.nl/uuid:35d25ade-32d3-4ae6-8e5a-04bbe490b711","Process for the production of thin layers, preferably for a photovoltaic cell","Nanu, M.; Meester, B.; Goossens, A.; Schoonman, J.","","2006","The invention is directed to a process for the production of a thin layer, preferably for a photovoltaic cell, which cell has at least a first contact layer, a p-type semiconductor layer, an n-type semiconductor layer, or a combined p-type/n-type semiconductor layer, and a second contact layer, said process comprising applying the layer or the various layers on top of each other, wherein at least one of the layers is applied using pulsed spraying of a solution of precursor material for the layer.","","en","patent","European Patent Office","","","","","","","","Applied Sciences","","","","",""
"uuid:677c3450-431e-4331-87e4-71964de18ea9","http://resolver.tudelft.nl/uuid:677c3450-431e-4331-87e4-71964de18ea9","Varkensvet","Schoonman, Jules","Goldschmidt, Tijs (contributor)","2006","Gastschrijver TU Delft 2006","","nl","book","Athenaeum-Polak & Van Gennep","","","","","","","","","","","","",""
"uuid:9370a88b-dbbc-4e65-bc2d-7e1042b7f21a","http://resolver.tudelft.nl/uuid:9370a88b-dbbc-4e65-bc2d-7e1042b7f21a","Deep-level transient spectroscopy of TiO2/CuInS2 heterojunctions","Nanu, M.; Boulch, F.; Schoonman, J.; Goossens, A.","","2005","Deep-level transient spectroscopy (DLTS) has been used to measure the concentration and energy position of deep electronic states in CuInS2. Flat TiO2?CuInS2 heterojunctions as well as TiO2-CuInS2 nanocomposites have been investigated. Subband-gap electronic states in CuInS2 films are mostly due to antisite point defects and vacancies. Substitution of indium with copper, CuInII, leads to an acceptor state 0.15 eV above the valence band, while copper vacancies, VCuI, are acceptor states at 0.1 eV. Furthermore, indium on a copper position, InCu?, yields a donor state at 0.07 eV below the conduction band, while sulphur vacancies are donor states at 0.0 = eV. With DLTS, these states are indeed found. For flat configurations, VCuI are the dominant acceptors with a concentration of 1.83×1017?cm?3. In contrast for nanocomposites CuInII are the dominant acceptors having a concentration of 6.7×1017?cm?3. We conclude that the concentration of antisite defects in nanocomposite CuInS2 is significantly higher than that in flat films of CuInS2.","deep level transient spectroscopy; titanium compounds; copper compounds; indium compounds; ternary semiconductors; semiconductor heterojunctions; nanocomposites; vacancies (crystal); impurity states; valence bands; conduction bands","en","journal article","American Institute of Physics","","","","","","","","Applied Sciences","DelftChemTech","","","",""
"uuid:86db11a6-279d-42af-b179-756e4836bb5c","http://resolver.tudelft.nl/uuid:86db11a6-279d-42af-b179-756e4836bb5c","Enhanced photoluminescence at poly(3-octyl-thiophene)/TiO2 interfaces","Van der Zanden, B.; Van de Krol, R.; Schoonman, J.; Goossens, A.","","2004","The photoluminescence (PL) of poly(3-octyl-thiophene) (P3OT) thin films applied on TiO2 substrates is compared to the PL of P3OT films applied on quartz. Quenching of excitons occurs at the P3OT/TiO2 interface and not at the P3OT/quartz interface. Yet, in the former case the PL intensity is stronger than in the latter. In particular, P3OT films less than 5 nm thick lumines much more when applied on TiO2, which is in striking contrast to what one expects. For films thicker than 10 nm, the increase of the PL as function of the film thickness is the same for TiO2 and for quartz, which indicates that the PL enhancement originates at the interface. The dissociation of excitons at the P3OT/TiO2 interface yields positive polarons in P3OT, which is not the case at the P3OT/quartz interface. We postulate that interaction between positive polarons and excitons explain the observed enhancement of the PL at the P3OT/TiO2 interface.","polymer films; titanium compounds; photoluminescence; radiation quenching; polarons; excitons","en","journal article","American Institute of Physics","","","","","","","","Applied Sciences","DelftChemTech","","","",""
"uuid:a85fb1d0-f8ed-49ea-8bd5-43ebceb6fb17","http://resolver.tudelft.nl/uuid:a85fb1d0-f8ed-49ea-8bd5-43ebceb6fb17","Lithium dynamics in LiMn2O4 probed directly by two-dimensional 7Li NMR","Verhoeven, V.W.J.; de Schepper, I.M.; Nachtegaal, G.; Kentgens, A.P.M.; Kelder, E.M.; Schoonman, J.; Mulder, F.M.","","2001","","","en","journal article","American Physical Society","","","","","","","","","","","","",""
"uuid:f2920d4e-e606-4718-a0be-ea363572ab02","http://resolver.tudelft.nl/uuid:f2920d4e-e606-4718-a0be-ea363572ab02","Ceramic hot plate and method for its manufacture","Noordhoek, M.J.; Van den Heuvel, R.C.; Kelder, E.M.; Schoonman, J.","","2000","The subject is a hot plate comprising at least one cooking zone of ceramic material to be located above a heat source of a cooking range. The cooking zone consists of a ceramic material exhibiting a Mott transition. The material exhibiting a Mott transition may consist of a primary ceramic material, dispersed in which is a ceramic material with a Mott transition. The area of the hot plate surrounding the cooking zone may consist of a ceramic material without Mott transition","","en","patent","European Patent Office","","","","","","","","","Applied Sciences","","","",""
"uuid:8372d4be-52b3-496e-9ceb-0a0178923f3e","http://resolver.tudelft.nl/uuid:8372d4be-52b3-496e-9ceb-0a0178923f3e","Li mobility in the battery cathode material Lix[Mn1.96Li0.04]O4 studied by muon-spin relaxation","Kaiser, C.T.; Verhoeven, V.W.J.; Gubbens, P.C.M.; Mulder, F.M.; de Schepper, I.; Yaouanc, A.; Dalmas de Reotier, P.; Cottrell, S.P.; Kelder, E.M.; Schoonman, J.","","2000","","","en","journal article","American Physical Society","","","","","","","","","","","","",""
"uuid:f20c4c31-524b-4377-8466-6f06503de278","http://resolver.tudelft.nl/uuid:f20c4c31-524b-4377-8466-6f06503de278","New generation of solar cells sees the light","Goossens, A.; Schoonman, J.","","1997","","review org solar cell development dye org solar cell review phthalocyanine dye org solar cell review","nl","journal article","","","","","","","","","","","","","",""
"uuid:5a4306b2-70bc-490f-b0c3-76ca7bcfc683","http://resolver.tudelft.nl/uuid:5a4306b2-70bc-490f-b0c3-76ca7bcfc683","Photoelectrochemical study of thin anatase TiO2 films prepared by metallorganic chemical vapor deposition","Boschloo, G.K.; Goossens, A.; Schoonman, J.","","1997","","electrolyte; Experimental study Photoelectrochemistry Optically transparent electrode Indium Oxides (ACT) Tin Oxides (ACT) Modified material Thin film Anatase Titanium IV Oxides (ACT) Chemical vapor deposition Photosensitizer Metalloporphyrin Zinc Complexes Photoelect","en","journal article","","","","","","","","","","","","","",""
"uuid:6974e1e3-2719-4189-8760-c067af2f55d4","http://resolver.tudelft.nl/uuid:6974e1e3-2719-4189-8760-c067af2f55d4","Particle-precipitation-aided chemical vapor deposition of titanium nitride","Dekker, J.P.; Van der Put, P.J.; Veringa, H.J.; Schoonman, J.","","1997","","thermophoretic deposition rapid growth tio2 films","en","journal article","","","","","","","","","","","","","",""
"uuid:764a8b15-ed8c-4c4f-b17d-44a8f7e53064","http://resolver.tudelft.nl/uuid:764a8b15-ed8c-4c4f-b17d-44a8f7e53064","Thermochemical data of boron subphosphide","Kelder, E.M.; Van der Put, P.J.; Schoonman, J.","","1997","","boron monophosphide boron phosphide boron subphosphide BP thermochemical data","en","journal article","","","","","","","","","","","","","",""
"uuid:8dc2020f-dcd6-4c7b-a0de-e8344895a614","http://resolver.tudelft.nl/uuid:8dc2020f-dcd6-4c7b-a0de-e8344895a614","Thin film solid electrolytes and electrodes for rechargeable lithium-ion batteries","Schoonman, J.; Kelder, E.M.","","1997","","chemical vapour deposition electrostatic spray deposition thin film deposition lithium-ion batteries electrostatic spray deposition; electrolyte","en","journal article","","","","","","","","","","","","","",""
"uuid:66a8cd45-aff4-4578-84cf-0500ca5ed00b","http://resolver.tudelft.nl/uuid:66a8cd45-aff4-4578-84cf-0500ca5ed00b","Mott-Schottky analysis of nanometer-scale thin-film anatase TiO2","Van de Krol, R.; Goossens, A.; Schoonman, J.","","1997","","Experimental study; Thin films; Schottky barrier; Permittivity; Titanium oxides; Etude experimentale","en","journal article","","","","","","","","","","","","","",""
"uuid:c41b59dc-3d92-4b75-beaf-5ad2170be25f","http://resolver.tudelft.nl/uuid:c41b59dc-3d92-4b75-beaf-5ad2170be25f","Panel discussion - Future prospects of lithium batteries","Owens, B.; Osaka, T.; Ohta, A.; Takeuchi, E.; Takamura, T.; Gibbard, F.; Abraham, K.M.; Megahed, S.; Kozawa, A.; Ishikawa, R.; Walk, C.R.; Blomgren, G.; Imai, T.; Kurokawa, H.; Schoonman, J.; Nakajima, K.; Atanasoski, R.; Tanaka, T.; Moy, R.; Yazami, R.; Broussely, M.; Yagasaki, E.; Yao, C.Y.; Suzuki, K.; Besenhard, J.; Peled, E.; Kuroki, M.; Levy, S.; Tatsumi, K.; Armand, M.","","1997","","","en","journal article","","","","","","","","","","","","","",""
"uuid:7619df46-8c4a-4fb6-b2c2-84caf3c0a393","http://resolver.tudelft.nl/uuid:7619df46-8c4a-4fb6-b2c2-84caf3c0a393","Spectroscopic investigation of lithium intercalation in thin films of anatase titanium dioxide","Van de Krol, R.; Goossens, A.; Schoonman, J.","","1997","","lithium intercalation anatase titanium dioxide oxide titanium lithium intercalation optical absorption","en","book chapter","","","","","","","","","","","","","",""
"uuid:3dacc0bb-494b-492d-ab66-80071ea03234","http://resolver.tudelft.nl/uuid:3dacc0bb-494b-492d-ab66-80071ea03234","Electrode and solid electrolyte thin films for secondary lithium-ion batteries","Chen, C.H.; Kelder, E.M.; Schoonman, J.","","1997","","lithium manganese oxide lithium boron phosphate electrostatic spray deposition thin film lithium batteries electrostatic spray deposition","en","journal article","","","","","","","","","","","","","",""
"uuid:d312dc9b-cb22-4aba-8397-33700503e021","http://resolver.tudelft.nl/uuid:d312dc9b-cb22-4aba-8397-33700503e021","Investigation of the potential distribution in porous nanocrystalline TiO2 electrodes by electrolyte electroreflection","Boschloo, G.K.; Goossens, A.; Schoonman, J.","","1997","","electrolyte; TiO2 electrodes porous nanocrystalline electrodes electrolyte electroreflection potential distribution titanium-dioxide semiconductor-films charge separation surface-states spectroscopy interfaces modulation hydrogen spectra light","en","journal article","","","","","","","","","","","","","",""
"uuid:4c721cd9-7b36-466e-9174-075ce4fba178","http://resolver.tudelft.nl/uuid:4c721cd9-7b36-466e-9174-075ce4fba178","Dynamic compaction of powders by an oblique detonation wave in the cylindrical configuration","Carton, E.P.; Verbeek, H.J.; Stuivinga, M.; Schoonman, J.","","1997","","shock compaction","en","journal article","","","","","","","","","","","","","",""
"uuid:18adaff4-4e1d-41c1-ab24-451ffaea10a2","http://resolver.tudelft.nl/uuid:18adaff4-4e1d-41c1-ab24-451ffaea10a2","Portable hype versnelt komst elektrische auto - De herlaadbare lithiumbatterij doet het goed in laptops en andere mobiele elektronica. Met een keramische in plaats van organische elektrolyt scoort de batterij ook hoge ogen voor gebruik in de elektrische auto","Kelder, E.; Schoonman, J.","","1997","","scheikunde","nl","journal article","","","","","","","","","","","","","",""
"uuid:0a2faa09-f5f7-4275-90ca-1ec225247f98","http://resolver.tudelft.nl/uuid:0a2faa09-f5f7-4275-90ca-1ec225247f98","Synthesis of high surface area silicon carbide by fluidized bed chemical vapour deposition","Moene, R.; Kramer, L.F.; Schoonman, J.; Makkee, M.; Moulijn, J.A.","","1997","","silicon carbide fluidized bed chemical vapor deposition vapor liquid solid mechanism high surface area particles","en","journal article","","","","","","","","","","","","","",""
"uuid:fa52798c-4a08-45a2-b70b-0186ed771e30","http://resolver.tudelft.nl/uuid:fa52798c-4a08-45a2-b70b-0186ed771e30","Effect of layer morphology on the lithium-ion diffusion in thin LixCoO2 films","Chen, C.H.; Kelder, E.M.; Schoonman, J.","","1997","","Experimental study Thin films Lithium oxides Cobalt oxides Ternary compounds Diffusion Ion exchange Morphology Fractals Porous materials Intercalation compounds Electrochemical reaction Etude experimentale Couche mince Lithium oxyde Cobalt oxyde Compose t","en","journal article","","","","","","","","","","","","","",""
"uuid:da251c0b-594c-4e8f-9cfc-6dbf6449c478","http://resolver.tudelft.nl/uuid:da251c0b-594c-4e8f-9cfc-6dbf6449c478","Formation and growth of silicon nitride particles in a laser-driven aerosol reactor investigated with photon correlation spectroscopy and electron microscopy","Tuinman, I.L.; Van Drunen, M.A.; Marijnissen, J.C.M.; Scarlett, B.; Schoonman, J.","","1997","","flame soot","en","journal article","","","","","","","","","","","","","",""
"uuid:bbac982d-0f3d-4a0a-898a-7c344ef84e95","http://resolver.tudelft.nl/uuid:bbac982d-0f3d-4a0a-898a-7c344ef84e95","Electrostatic spray deposition (ESD) of Li-ion-conducting Li3PO4 thin films","Chen, C.H.; Schoonman, J.","","1997","","electrostatic spray deposition lithium phosphate film ionic conductor lithium phosphate spray deposition","en","journal article","","","","","","","","","","","","","",""
"uuid:db25be50-18d0-475f-9117-7b18c21ca0cc","http://resolver.tudelft.nl/uuid:db25be50-18d0-475f-9117-7b18c21ca0cc","Quality control of Li1+dMn2-dO4 spinels with their impurity phases by Jaeger and Vetter titration","Kelder, E.M.; Jak, M.J.G.; Schoonman, J.; Hardgrave, M.T.; de-Andersen, S.Y.","","1997","","Secondary batteries Lithium ion Batterie accumulateur electrochimique Lithium ion Litio ion Electrical power engineering Electrical engineering Applied sciences Electroenergetique Electrotechnique Sciences appliquees Electroenergetica Electrotecnica Cienc","en","journal article","","","","","","","","","","","","","",""
"uuid:b18a4251-2bb0-4dd8-81ef-ca14568c812e","http://resolver.tudelft.nl/uuid:b18a4251-2bb0-4dd8-81ef-ca14568c812e","Functional ceramic films with reticular structures prepared by electrostatic spray deposition technique","Chen, C.H.; Kelder, E.M.; Schoonman, J.","","1997","","thin-films pyrolysis liquids","en","journal article","","","","","","","","","","","","","",""
"uuid:ad30d608-8258-41b8-8f29-15b28eda9a72","http://resolver.tudelft.nl/uuid:ad30d608-8258-41b8-8f29-15b28eda9a72","A search for suitable coating materials on separator plates for molten carbonate fuel cells","Keijzer, M.; Hemmes, K.; van der Put, P.; Dewit, J.H.W.; Schoonman, J.","","1997","","stainless steel corrosion behavior","en","journal article","","","","","","","","","","","","","",""
"uuid:b27c8ca6-9aad-4b2e-adfc-df180b676379","http://resolver.tudelft.nl/uuid:b27c8ca6-9aad-4b2e-adfc-df180b676379","Defect chemistry in solid state electrochemistry","Schoonman, J.","","1997","","review defect chem solid state electrochem crystal defect solid state electrochem review point defect solid state electrochem review conductor solid state electrochem review","en","book chapter","","","","","","","","","","","","","",""
"uuid:155b4fcc-b555-47d1-8939-2bbda267e892","http://resolver.tudelft.nl/uuid:155b4fcc-b555-47d1-8939-2bbda267e892","Unique porous LiCoO2 thin layers prepared by electrostatic spray deposition","Chen, C.H.; Kelder, E.M.; Schoonman, J.","","1996","","Experimental study Porous materials Thin films Ternary compounds Lithium oxides Cobalt oxides Crystal growth from solutions Electrodeposition Aerosols Thermal stability Pore size Etude experimentale Materiau poreux Couche mince Compose ternaire Lithium ox","en","journal article","","","","","","","","","","","","","",""
"uuid:c1f3f40a-586f-44bc-b4b4-22e8699e3960","http://resolver.tudelft.nl/uuid:c1f3f40a-586f-44bc-b4b4-22e8699e3960","Synthesis of nanometer-scale boron phosphide whiskers by vapor-liquid-solid chemical vapor deposition","Schroten, E.; Goossens, A.; Schoonman, J.","","1996","","graphite nickel","en","journal article","","","","","","","","","","","","","",""
"uuid:17dc2d69-07c1-49fd-8405-7138b3194b8d","http://resolver.tudelft.nl/uuid:17dc2d69-07c1-49fd-8405-7138b3194b8d","Electrostatic spray deposition of thin layers of cathode materials for lithium battery.","Chen, C.H.; Kelder, E.M.; Jak, M.J.G.; Schoonman, J.; Chowdari, B.V.R.","","1996","","Battery Secondary cell Lithium Electrostatic spraying Electrostatic deposition Thin film Electrode material Production process Solid electrolyte storage battery Lithium oxide Cobalt oxide Diffusion coefficient Chemical diffusion Diffraction pattern X ray","en","journal article","","","","","","","","","","","","","",""
"uuid:e533ffd5-0d3e-4c20-a28c-d67431b8cff4","http://resolver.tudelft.nl/uuid:e533ffd5-0d3e-4c20-a28c-d67431b8cff4","Vapor-phase synthesis and processing of nanoparticle materials (NANO)","Fissan, H.J.; Schoonman, J.","","1996","","","en","journal article","","","","","","","","","","","","","",""
"uuid:a8291054-f910-4f7c-a165-03f4c02c32c8","http://resolver.tudelft.nl/uuid:a8291054-f910-4f7c-a165-03f4c02c32c8","Morphology control of thin LiCoO2 films fabricated using the electrostatic spray deposition (ESD) technique","Chen, C.H.; Kelder, E.M.; van der Put, P.; Schoonman, J.","","1996","","pyrolysis","en","journal article","","","","","","","","","","","","","",""
"uuid:c6bae183-0605-4b42-872e-1afd7c9635af","http://resolver.tudelft.nl/uuid:c6bae183-0605-4b42-872e-1afd7c9635af","Dithiacrown ether substituted porphyrazines: Synthesis, single-crystal structure, and control of aggregation in solution by complexation of transition-metal ions","Van Nostrum, C.F.; Benneker, F.B.G.; Brussaard, H.; Kooijman, H.; Veldman, N.; Spek, A.L.; Schoonman, J.; Feiters, M.C.; Nolte, R.J.M.","","1996","","crown thioether chemistry electrical-properties copper phthalocyanine molecular materials network polymers derivatives water moieties ligand units","en","journal article","","","","","","","","","","","","","",""
"uuid:e770541c-17c8-4f74-ad94-1c95391283d9","http://resolver.tudelft.nl/uuid:e770541c-17c8-4f74-ad94-1c95391283d9","Dynamically compacted rechargeable ceramic lithium batteries. Solid state ionics - 95. Part II","Jak, M.J.G.; Kelder, E.M.; Stuivinga, M.; Schoonman, J.; Chowdari, B.V.R.","","1996","","Secondary cell Solid electrolyte storage battery Battery Lithium Manganese Oxides Energy density Dynamic compaction Ceramic materials Equivalent circuit Electrical impedance Frequency characteristic Temperature effect Electrical conductivity Boron Phospha","en","journal article","","","","","","","","","","","","","",""
"uuid:a38b9ba0-e1b6-4ebf-b32b-ce2ed72a5827","http://resolver.tudelft.nl/uuid:a38b9ba0-e1b6-4ebf-b32b-ce2ed72a5827","Synthesis of terbia-doped yttria-stabilized zirconia thin films by electrostatic spray deposition (ESD)","Stelzer, N.H.J.; Schoonman, J.","","1996","","terbia yttria zirconia film electrostatic spraying","en","journal article","","","","","","","","","","","","","",""
"uuid:aed7af47-8d12-4fc5-bc90-d5b940f53cf2","http://resolver.tudelft.nl/uuid:aed7af47-8d12-4fc5-bc90-d5b940f53cf2","Coating of yttria-stabilized zirconia (YSZ) thin films on gadolinia-doped ceria (GCO) by the electrostatic spray deposition (ESD) technique","Chen, C.H.; Nord-Varhaug, K.; Schoonman, J.","","1996","","yttria stabilized zirconia coated ceria electrolyte fuel cell electrolyte ceria coated","en","journal article","","","","","","","","","","","","","",""
"uuid:e88ddac7-8781-4790-841c-3775eed3aabe","http://resolver.tudelft.nl/uuid:e88ddac7-8781-4790-841c-3775eed3aabe","Thin-film components for lithium-ion batteries","Chen, C.H.; Kelder, E.M.; Van der Put, P.J.J.M.; Schoonman, J.","","1996","","electrolyte; review lithium ion thin film battery","en","conference paper","","","","","","","","","","","","","",""
"uuid:2d98e0de-522c-4a74-bd61-4c8a19cb0eb0","http://resolver.tudelft.nl/uuid:2d98e0de-522c-4a74-bd61-4c8a19cb0eb0","Reaction-bonded titanium nitride ceramics","Pivkina, A.; Van der Put, P.J.; Frolov, Y.; Schoonman, J.","","1996","","","en","journal article","","","","","","","","","","","","","",""
"uuid:f182a00c-9a9b-4edc-be70-0d8d8cc8d107","http://resolver.tudelft.nl/uuid:f182a00c-9a9b-4edc-be70-0d8d8cc8d107","The influence of surface kinetics in modelling chemical vapour deposition processes in porous preforms","Dekker, J.P.; Moene, R.; Schoonman, J.","","1996","","ceramic materials high-temperature gas-phase infiltration composites cvd diffusion silicon densification pressure","en","journal article","","","","","","","","","","","","","",""
"uuid:0158dd49-e3b6-4ae0-ba3c-031e9d9b39eb","http://resolver.tudelft.nl/uuid:0158dd49-e3b6-4ae0-ba3c-031e9d9b39eb","Combination of ac-impedance spectroscopy and short circuiting measurements applied on Yba2Cu3O7-. Solid state ionics - 95. Part II","Jak, M.J.G.; Riess, I.; Schoonman, J.; Chowdari, B.V.R.","","1996","","Electrical test Electrical impedance High frequency Short circuit Electrochemical cell Solid electrolyte Yttrium oxide Barium oxide Copper oxide Quaternary compound High temperature superconductor Stabilized zirconia Ionic conductivity Electronic conducti","en","journal article","","","","","","","","","","","","","",""
"uuid:c06ade52-29f1-4ecf-9b22-2e531d1e5704","http://resolver.tudelft.nl/uuid:c06ade52-29f1-4ecf-9b22-2e531d1e5704","Octahedral site occupation of lithium in LixMn2O4","Kelder, E.M.; Schoonman, J.; Berg, H.; Thomas, J.O.","","1996","","battery cathode lithium manganese oxide","en","conference paper","","","","","","","","","","","","","",""
"uuid:8c62aff1-83a2-4d4f-854a-25a01cc547b7","http://resolver.tudelft.nl/uuid:8c62aff1-83a2-4d4f-854a-25a01cc547b7","Structural and electrical properties of dynamically compacted all-solid-state rechargeable lithium ion battery components","Jak, M.J.G.; Kelder, E.M.; Van Zomeren, R.A.; Schoonman, J.","","1996","","anodes- boron-compounds ceramics- densification- electrical-conductivity graphite- ionic-conductivity lithium- lithium-compounds phosphorus-compounds secondary-cells solid-electrolytes electrical-properties structural-properties dynamically-compacted soli; electrolyte","en","conference paper","Electrochem. Soc, Pennington, NJ, USA","","","","","","","","","","","","",""
"uuid:d1783e38-9a69-4208-ad34-c8de7a4f1e7f","http://resolver.tudelft.nl/uuid:d1783e38-9a69-4208-ad34-c8de7a4f1e7f","Electrical and interfacial properties of a Li3Fe2(PO4)3 single crystal with silver electrodes","Ivanov, S.A.K.; Schoonman, J.","","1996","","Electric conductivity Electric impedance Solid solid interfaces Monocrystals Temperature dependence Phase transformations DSC Ionic conductivity Solid electrolytes Activation energy Electrical model Equivalent circuits Twin boundary Experimental study Lit","en","journal article","","","","","","","","","","","","","",""
"uuid:d5917ad6-059a-4bdf-8f2f-a495adb8a738","http://resolver.tudelft.nl/uuid:d5917ad6-059a-4bdf-8f2f-a495adb8a738","Raman spectroscopy as an on-line measurement technique in a laser-CVD reactor during production of Si sub 3N sub 4","Tuinman, I.L.; Veenstra, J.; Marijnissen, J.C.M.; Scarlett, B.; Schoonman, J.","","1996","","Silicon nitride Chemical vapor deposition Laser applications Raman spectroscopy Computational fluid dynamics Nucleation Mixing Powders Backscattering Computer simulation Gated detector system 804.2 (Inorganic Components) 802.2 (Chemical Reactions) 744.9 (","en","journal article","","","","","","","","","","","","","",""
"uuid:26050d3a-88e4-4159-8ea0-89c66eea96f0","http://resolver.tudelft.nl/uuid:26050d3a-88e4-4159-8ea0-89c66eea96f0","A new ceramic lithium solid electrolyte for rechargeable swing type batteries","Kelder, E.M.; Jak, M.J.G.; deLange, F.; Schoonman, J.","","1996","","electrolyte; solid electrolytes ion conductivity lithium ion batteries ion conductivity","en","journal article","","","","","","","","","","","","","",""
"uuid:cc737ebf-df81-4cd2-9492-148738cb4146","http://resolver.tudelft.nl/uuid:cc737ebf-df81-4cd2-9492-148738cb4146","Coating of activated carbon with silicon carbide by chemical vapour deposition","Moene, R.; Boon, H.T.; Schoonman, J.; Makkee, M.; Moulijn, J.A.","","1996","","activated carbon modification chemical vapour deposition silicon carbide oxidation resistance mechanical strength growth-characteristics cvd kinetics systems infiltration","en","journal article","","","","","","","","","","","","","",""
"uuid:f274152a-1a31-42b7-a131-02f5fd1d6c40","http://resolver.tudelft.nl/uuid:f274152a-1a31-42b7-a131-02f5fd1d6c40","Laser-induced chemical vapour deposition of silicon carbonitride","Besling, W.F.A.; Van der Put, P.J.J.M.; Schoonman, J.; Battiston, G.A.; Gerbasi, R.; Porchia, M.","","1995","","Experimental study Ternary compounds Silicon carbides Silicon nitrides Carbonitrides Crystal growth from vapors CVD Photosensitization Laser radiation Coatings Powders Ultrafine particle Amorphous state Characterization Operating mode Etude experimentale","en","conference paper","","","","","","","","","","","","","",""
"uuid:22d468f8-9aeb-4e2d-a207-540a61285819","http://resolver.tudelft.nl/uuid:22d468f8-9aeb-4e2d-a207-540a61285819","Shock-Wave Mechanics in Porous Ceramic Assemblies","Boogerd, P.; Verbeek, H.J.; Stuivinga, M.; Van der Steen, A.C.; Schoonman, J.","","1995","","hugoniot model","en","journal article","","","","","","","","","","","","","",""
"uuid:1d7c9d23-51c6-4572-aec4-12b182d2d30c","http://resolver.tudelft.nl/uuid:1d7c9d23-51c6-4572-aec4-12b182d2d30c","Conversion of activated carbon into porous silicon carbide by fluidized bed chemical vapor deposition","Moene, R.; Kramer, L.F.; Schoonman, J.; Makkee, M.; Moulijn, J.A.","","1995","","silicon carbide catalyst support prepn CVD nickel silicon carbide catalyst chem vapor deposition silicon carbide prepn","en","book chapter","","","","","","","","","","","","","",""
"uuid:d0b3dc6f-298b-40e5-9acd-7a2b6036480b","http://resolver.tudelft.nl/uuid:d0b3dc6f-298b-40e5-9acd-7a2b6036480b","General Shock-Wave Equation of State for Solids","Boogerd, P.; Verbeek, H.J.; Stuivinga, M.; Van der Steen, A.C.; Van der Put, P.J.; Schoonman, J.","","1995","","","en","journal article","","","","","","","","","","","","","",""
"uuid:0560d6f2-b228-4116-aa85-40243b26b76d","http://resolver.tudelft.nl/uuid:0560d6f2-b228-4116-aa85-40243b26b76d","The thermodynamic properties of BaCeO3 at temperatures from 5 to 940 K","Scholten, M.J.; Schoonman, J.; Van Miltenburg, J.C.; Cordfunke, E.H.P.","","1995","","Entropy Enthalpy Cerium Oxides Barium Oxides Ternary compound Experimental study Heat capacity Entropie Enthalpie Cerium Oxyde Baryum Oxyde Compose ternaire Etude experimentale Capacite calorifique BaCeO3 Ba Ce O Entropia Entalpia Cerio Oxido Bario Oxido","en","journal article","","","","","","","","","","","","","",""
"uuid:dc248e38-23c0-4589-a1e8-bfac9c8e341a","http://resolver.tudelft.nl/uuid:dc248e38-23c0-4589-a1e8-bfac9c8e341a","Microstructure-conductivity relationships in solid anisotropic ionically conducting materials","Butchereit, E.; Schoonman, J.; Zandbergen, H.W.; Lutz-Elsner, C.; Schreiber, M.; Wang, P.","","1995","","microstructure anisotropic ionically conducting material ionic conductor microstructure","en","conference paper","","","","","","","","","","","","","",""
"uuid:21ebb242-7b14-40f6-a1d9-8acac6187b1b","http://resolver.tudelft.nl/uuid:21ebb242-7b14-40f6-a1d9-8acac6187b1b","Electrical properties of Au-Bn-InP MIS diodes","Baehr, O.; Barrada, M.; Bath, A.; Lepley, B.; Thévenin, P.; Schoonman, J.","","1995","","natuurkunde","en","journal article","","","","","","","","","","","","","",""
"uuid:a5e8e006-9376-44d2-a027-ad9e0c1d4b48","http://resolver.tudelft.nl/uuid:a5e8e006-9376-44d2-a027-ad9e0c1d4b48","Solid oxide fuel cells operating on uniform mixtures of fuel and air","Riess, I.; Van der Put, P.J.; Schoonman, J.","","1995","","natuurkunde","en","journal article","","","","","","","","","","","","","",""
"uuid:b5e328a7-a005-41eb-98d6-7fc4435908ee","http://resolver.tudelft.nl/uuid:b5e328a7-a005-41eb-98d6-7fc4435908ee","Nickel catalyzed conversion of activated carbon into porous silicon carbide","Moene, R.; Schoonman, J.; Makkee, M.; Moulijn, J.A.","","1995","","porous silicon carbide activated carbon conversion nickel catalyzed activated carbon conversion","en","book chapter","","","","","","","","","","","","","",""
"uuid:20e829a7-c796-49aa-ad3e-a9d8f1b13c2b","http://resolver.tudelft.nl/uuid:20e829a7-c796-49aa-ad3e-a9d8f1b13c2b","Electrochemical Investigations of Silicon/Boron Phosphide Heterojunction Photoelectrodes","Goossens, A.; Schoonman, J.","","1995","","boron phosphide heterojunctions photoelectrodes boron phosphide semiconductor electrodes impedance","en","journal article","","","","","","","","","","","","","",""
"uuid:ae4b73ed-9c7c-4f48-a820-b3c3016b86d4","http://resolver.tudelft.nl/uuid:ae4b73ed-9c7c-4f48-a820-b3c3016b86d4","Diffusion enhancement in LixMn2O4","Chen, L.; Huang, X.; Kelder, E.; Schoonman, J.","","1995","","Intercalation compound Ternary compound Chemical diffusion Lithium Ions (ENT) Manganese Oxides (ENT) Spinels Battery Electrical impedance Cyclic voltammetry Electrochemical properties Compose insertion Compose ternaire Diffusion chimique Lithium Ion (ENT)","en","journal article","","","","","","","","","","","","","",""
"uuid:a869a9c9-e4db-411d-a9f9-3b600233981f","http://resolver.tudelft.nl/uuid:a869a9c9-e4db-411d-a9f9-3b600233981f","Fabrication of LiCoO2 thin film cathodes for rechargeable lithium battery by electrostatic spray pyrolysis","Chen, C.H.; Buysman, A.A.J.; Kelder, E.M.; Schoonman, J.","","1995","","Experimental study Electrode production Pyrolysis Spraying Thin layer electrode Lithium Oxides (ACT) Cobalt Oxides (ACT) Ternary compound Battery Surface structure Scanning electron microscopy Morphology Diffusion coefficient Lithium Ions Organic solvent; pyrolysis","en","journal article","","","","","","","","","","","","","",""
"uuid:c7262b2b-aec1-49df-ad9c-5ad9fa594c34","http://resolver.tudelft.nl/uuid:c7262b2b-aec1-49df-ad9c-5ad9fa594c34","Thin film fuel cells","Van Dieten, V.E.J.; Dekker, J.P.; Schoonman, J.","","1995","","","en","book chapter","MATERIALS RESEARCH SOC","","","","","","","","","","","","",""
"uuid:10a249e0-6d9d-4c8c-8396-e11057635c0a","http://resolver.tudelft.nl/uuid:10a249e0-6d9d-4c8c-8396-e11057635c0a","Electrochemical vapor deposition of doped LaCrO3","Van Dieten, V.E.J.; Schoonman, J.","","1995","","lanthanum chromite electrochem vapor deposition","en","conference paper","","","","","","","","","","","","","",""
"uuid:5b6a5a4f-76a9-4099-8465-a963127998c4","http://resolver.tudelft.nl/uuid:5b6a5a4f-76a9-4099-8465-a963127998c4","Gas-phase synthesis of nano-structured semiconductors. Advanced materials and processing","Goossens, A.; Schoonman, J.; Yoshimura, M.","","1995","","Review Semiconductor materials Nanostructure Thin film Porous material Crystal growth from vapors VLS growth Chemical vapor deposition Precipitation Laser beam Wet process Chemical etching Sol gel process Article synthese Semiconducteur Nanostructure Couc","en","journal article","","","","","","","","","","","","","",""
"uuid:3cb843ac-3505-4594-809f-a4cedf23c177","http://resolver.tudelft.nl/uuid:3cb843ac-3505-4594-809f-a4cedf23c177","The Production of Thin-Films of Limn2o4 by Electrospraying","Van Zomeren, A.A.; Kelder, E.M.; Marijnissen, J.C.M.; Schoonman, J.","","1994","","taylor cone","en","journal article","","","","","","","","","","","","","",""
"uuid:4f76b967-0cbd-42d5-9848-8df22b62de67","http://resolver.tudelft.nl/uuid:4f76b967-0cbd-42d5-9848-8df22b62de67","Vapour-phase synthesis of titanium nitride powder","Dekker, J.P.; Van der Put, P.J.; Veringa, H.J.; Schoonman, J.","","1994","","Powder Inorganic compound Titanium Nitrides Titanium Chlorides (ENT) Ammonia (ENT) Hydrogen (ENT) Particle size X ray diffraction Lattice parameters Surface area Electron microscopy Poudre Compose mineral Titane Nitrure Titane Chlorure (ENT) Ammoniac (ENT","en","journal article","","","","","","","","","","","","","",""
"uuid:96e64f32-1e64-4554-9cf3-8da4d685e0f8","http://resolver.tudelft.nl/uuid:96e64f32-1e64-4554-9cf3-8da4d685e0f8","Chemie brengt komst elektrische auto dichterbij - Mondiale belangstelling voor 'zero emission' voertuigen heeft onderzoek naar betrouwbare herlaadbare batterijen in een stroomversnelling gebracht","Schoonman, J.; Kelder, E.M.","","1994","","scheikunde","nl","journal article","","","","","","","","","","","","","",""
"uuid:3b930bdb-1ff0-4d8d-b35f-f2952f5eca80","http://resolver.tudelft.nl/uuid:3b930bdb-1ff0-4d8d-b35f-f2952f5eca80","Mechanism of a 'Schottky-barrier-limited' Bi2Sr2CaCu2O8+x based sensor for CO and NO","Huang, X.J.; Schoonman, J.; Chen, L.Q.","","1994","","Measurement sensor Gas detector Carbon monoxide (ANA) Nitrogen monoxide (ANA) Semiconductor materials Porous material Polycrystal Thick film Chemisorption Reaction mechanism Schottky barrier Electrical conductance Temperature effect Partial pressure Gas m","en","journal article","","","","","","","","","","","","","",""
"uuid:2682a1dc-227a-4922-937e-3d6441b24c09","http://resolver.tudelft.nl/uuid:2682a1dc-227a-4922-937e-3d6441b24c09","NOx sensing characteristics of Bi2Sr2CaCu2O8+x and Bi2Sr2CuO6+x films","Huang, X.J.; Schoonman, J.; Boukamp, B.A.; Bouwmeester, H.J.M.; Van der Put, P.J.; Royal, N.C.S.T.; International, S.","","1994","","Gas detector Superconducting materials Bismuth Oxides Strontium Oxides Calcium Oxides Copper Oxides Nitrogen Oxides (ANA) Inorganic compound Electric resistivity Multi element compound Detecteur de gaz Supraconducteur Bismuth Oxyde Strontium Oxyde Calcium","en","journal article","","","","","","","","","","","","","",""
"uuid:64a4e21a-9bb6-46e6-9e5b-27a295587cd3","http://resolver.tudelft.nl/uuid:64a4e21a-9bb6-46e6-9e5b-27a295587cd3","Homogeneous Nucleation of Silicon","Kruis, F.E.; Schoonman, J.; Scarlett, B.","","1994","","chlorinated silanes aerosol vapor nitride system growth","en","journal article","","","","","","","","","","","","","",""
"uuid:61374d07-d660-44e3-8745-a87a8d6ca643","http://resolver.tudelft.nl/uuid:61374d07-d660-44e3-8745-a87a8d6ca643","Vapor phase manufacture of porous TiN deposits on/in porous supports. Vapor phase manufacture of materials","Dekker, J.P.; Schoonman, J.; Pratsinis, S.; Kodas, T.T.","","1994","","Experimental study Crystal growth methods Crystal growth from vapors CVD Precipitation Aerosol deposition Binary compounds Titanium nitrides Porous materials Temperature gradients Porosity Substrates Etude experimentale Methode croissance cristalline Croi","en","journal article","","","","","","","","","","","","","",""
"uuid:94779773-d182-4cd1-9e18-1e4153ac0749","http://resolver.tudelft.nl/uuid:94779773-d182-4cd1-9e18-1e4153ac0749","Amorphous MnO2 thin film cathode for rechargeable lithium batteries","Chen, L.; Van Zomeren, A.; Schoonman, J.","","1994","","Secondary cell; Battery; Lithium; Electrode material; Manganese; Oxides; Thin film; Energetic capacity; Electrochemical characteristic; Accumulateur electrochimique","en","journal article","","","","","","","","","","","","","",""
"uuid:b834473c-331f-44dc-8b14-3668ebcf36a3","http://resolver.tudelft.nl/uuid:b834473c-331f-44dc-8b14-3668ebcf36a3","A kinetic study of titanium nitride chemical vapor deposition using nitrogen, hydrogen, and titanium tetrachloride","Dekker, J.P.; Van der Put, P.J.; Veringa, H.J.; Schoonman, J.","","1994","","titanium nitride chem vapor deposition kinetics chloride titanium reaction hydrogen nitrogen","en","journal article","","","","","","","","","","","","","",""
"uuid:d78dc13d-426d-465c-9135-0976dc218107","http://resolver.tudelft.nl/uuid:d78dc13d-426d-465c-9135-0976dc218107","Evaluation of Isothermal Chemical-Vapor Infiltration with Langmuir-Hinshelwood Type Kinetics","Moene, R.; Dekker, J.P.; Makkee, M.; Schoonman, J.; Moulijn, J.A.","","1994","","deposition diffusion","en","journal article","","","","","","","","","","","","","",""
"uuid:cee1c7ea-2611-4ee7-8582-b2c0823b2e2a","http://resolver.tudelft.nl/uuid:cee1c7ea-2611-4ee7-8582-b2c0823b2e2a","Low-temperature synthesis of thin films of YSZ and BaCeO3 using electrostatic spray pyrolysis (ESP)","Kelder, E.M.; Nijs, O.C.J.; Schoonman, J.","","1994","","electrolyte; Experimental study Crystal growth methods Crystal growth from solutions Electrospray Aerosols Pyrolysis Solid electrolytes Thin films Ceramics Zirconium oxides Yttrium oxides Ternary compounds Barium oxides Cerium oxides Solid fuels Fuel cells Etude exper","en","journal article","","","","","","","","","","","","","",""
"uuid:2d7a1651-5f8a-45a0-9303-8e052884a179","http://resolver.tudelft.nl/uuid:2d7a1651-5f8a-45a0-9303-8e052884a179","High-Tc superconductors as NO sensor materials: A general investigation","Huang, X.J.; Schoonman, J.; Chen, L.Q.","","1994","","Measurement sensor Gas detector Nitrogen monoxide (ANA) Preparation High temperature superconductor Ceramic materials Yttrium oxide Barium oxide Copper oxide Lanthanum oxide Strontium oxide Bismuth oxide Neodymium Oxides Lithium addition Sensitivity Respo","en","journal article","","","","","","","","","","","","","",""
"uuid:2ebdc6b5-ba7f-4a7a-9ebf-5cac9f744a17","http://resolver.tudelft.nl/uuid:2ebdc6b5-ba7f-4a7a-9ebf-5cac9f744a17","Chemical vapour infiltration of TiB2 and TiN in porous Al2O3","Dekker, J.P.; Van der Put, P.J.; Veringa, H.J.; Schoonman, J.","","1994","","Oxide ceramics Alumina Aluminium oxide Porous material Chemical vapor deposition Infiltration Titanium boride Titanium nitride Physical properties Permeability Mechanical properties Porous membrane Experimental study Ceramique oxyde Alumine Aluminium oxyd","en","journal article","","","","","","","","","","","","","",""
"uuid:6644fc6e-6d68-46c6-9851-8944d8630da5","http://resolver.tudelft.nl/uuid:6644fc6e-6d68-46c6-9851-8944d8630da5","A gas sensor with porous films of Bi2Sr2CaCu2O8+x: An analysis of the response","Huang, X.J.; Schoonman, J.; Chen, L.Q.","","1994","","Measurement sensor Gas detector Semiconductor detector Thick film Bismuth oxide Strontium oxide Calcium oxide Copper oxide Porous material Electric resistivity Response function Time dependence Temperature effect Partial pressure Schottky barrier Nitrogen","en","journal article","","","","","","","","","","","","","",""
"uuid:8342222d-c48b-4a1a-9f33-806ceb5449f1","http://resolver.tudelft.nl/uuid:8342222d-c48b-4a1a-9f33-806ceb5449f1","CVD-grown boron phosphides: A thermodynamical adsorption model to understand the growth of different kinds of boron phosphides","Kelder, E.M.; van der Put, P.; Schoonman, J.","","1994","","boron phosphide CVD thermodn adsorption model","en","book chapter","","","","","","","","","","","","","",""
"uuid:a6c95d2e-c7b7-41c3-b608-c10c1ede80bb","http://resolver.tudelft.nl/uuid:a6c95d2e-c7b7-41c3-b608-c10c1ede80bb","Observations on the Na-Beta''-Alumina Metal Interface by Impedance Spectroscopy and Scanning Electron-Microscopy","Butchereit, E.; Schreiber, M.; Schoonman, J.","","1994","","sodium beta-aluminas ac impedance conductivity water","en","journal article","","","","","","","","","","","","","",""
"uuid:13883cff-57f3-4c4f-8dd4-7c71077ee472","http://resolver.tudelft.nl/uuid:13883cff-57f3-4c4f-8dd4-7c71077ee472","Plasma-Enhanced Chemical-Vapor-Deposition of Boron-Nitride onto Inp","Bath, A.; Baehr, O.; Barrada, M.; Lepley, B.; Van der Put, P.J.; Schoonman, J.","","1994","","gate insulators thin-films","en","journal article","","","","","","","","","","","","","",""
"uuid:0cc556e1-73d9-4fe7-a9d9-8cd0f0a5f29e","http://resolver.tudelft.nl/uuid:0cc556e1-73d9-4fe7-a9d9-8cd0f0a5f29e","Hydrogen measuring probe for coal gasification processes. Discussion","Jacobs, A.; Vangrunderbeek, J.; Beckers, H.; De Schutter, F.; Luyten, J.; Van Landschoot, R.; Schoonman, J.; Kapteijn, F.; Moulijn, J.; Nater, K.; Prins, W.","","1993","","Coal Gasification Hydrogen Measurement sensor Gas analysis Solid electrolyte Design Charbon Gazeification Hydrogene Capteur mesure Analyse gaz Electrolyte solide Conception Carbon Gasificacion Hidrogeno Captador medida Analisis gas Electrolito solido Dise; electrolyte","en","journal article","","","","","","","","","","","","","",""
"uuid:cb8add52-35d7-4441-addc-2c15aa41c2a2","http://resolver.tudelft.nl/uuid:cb8add52-35d7-4441-addc-2c15aa41c2a2","Polycrystalline, glassy and thin films of LiMn2O4","Chen, L.; Schoonman, J.","","1993","","Electric conductivity Electric impedance Thin films Vitreous state XRD Sintering Lattice parameters Polycrystals Self diffusion Experimental study DTA Manganites Lithium compounds Manganese oxides Ternary compounds Conductivite electrique Impedance electr","en","journal article","","","","","","","","","","","","","",""
"uuid:d53fc73d-5b01-4d29-b604-dc277caab945","http://resolver.tudelft.nl/uuid:d53fc73d-5b01-4d29-b604-dc277caab945","Ag+-Beta''-Alumina Solid-Electrolyte So(X) Sensor with Metal Silver as a Solid Reference Electrode","Rao, N.; Sorensen, O.T.; Van den Bleek, C.M.; Schoonman, J.","","1993","","","en","journal article","","","","","","","","","","","","","",""
"uuid:403656a9-9b4c-4929-b2a2-094900515f05","http://resolver.tudelft.nl/uuid:403656a9-9b4c-4929-b2a2-094900515f05","Chemical vapor deposition techniques for thin films of solid electrolytes and electrodes","Van Dieten, V.E.J.; Dekker, J.P.; Van Zomeren, A.A.; Schoonman, J.","","1993","","electrochem vapor deposition yttria stabilized zirconia CVD electrochem titanium silicide lithium battery","en","book chapter","","","","","","","","","","","","","",""
"uuid:1289bc1c-8427-4366-9ad2-5f04f5d92808","http://resolver.tudelft.nl/uuid:1289bc1c-8427-4366-9ad2-5f04f5d92808","Synthesis of Strontium and Barium Cerate and Their Reaction with Carbon-Dioxide","Scholten, M.J.; Schoonman, J.; Van Miltenburg, J.C.; Oonk, H.A.J.","","1993","","bulk protonic conduction yb-doped srceo3 solid electrolyte ion conduction baceo3","en","journal article","","","","","","","","","","","","","",""
"uuid:f1410e96-05eb-48d9-9f33-f115a64fd4ed","http://resolver.tudelft.nl/uuid:f1410e96-05eb-48d9-9f33-f115a64fd4ed","Chemical vapor deposition of titanium diboride using boron tribromide, titanium tetrachloride, and hydrogen","Dekker, J.P.; Van der Put, P.J.; Schoonman, J.; Veringa, H.J.","","1993","","titanium boride CVD reaction kinetics titanium tetrachloride CVD titanium boride boron bromide CVD titanium boride","en","journal article","","","","","","","","","","","","","",""
"uuid:6742381d-409c-4065-9dbd-5fca2178ed83","http://resolver.tudelft.nl/uuid:6742381d-409c-4065-9dbd-5fca2178ed83","Kinetics of tungsten low-pressure chemical-vapor deposition using WF6 and SiH4 studied by in situ growth-rate measurements","Ammerlaan, J.A.M.; Van der Put, P.J.; Schoonman, J.","","1993","","Thin film; Crystal growth; Experimental study; Tungsten; Chemical vapor deposition; Low pressure; Kinetics; In situ; Process control","en","journal article","","","","","","","","","","","","","",""
"uuid:41be0b93-9eb2-40ec-a3a0-737d1c399a78","http://resolver.tudelft.nl/uuid:41be0b93-9eb2-40ec-a3a0-737d1c399a78","Gas-to-particle conversion in the particle precipitation-aided chemical vapor deposition process. II: Synthesis of the perovskite oxide yttrium chromite. The role of aerosols in materials processing","Van Dieten, V.E.J.; Dekker, J.P.; Hurkmans, E.J.; Schoonman, J.","","1993","","Experimental study Aerosol deposition Particle precipitation Chemical vapor deposition Powder Ternary compound Yttrium Oxides (FIN) Chromium Oxides Perovskite type compound Gas mixture Steam (ENT) Oxygen Molecules (ENT) Binary compound Yttrium Chlorides (","en","journal article","","","","","","","","","","","","","",""
"uuid:c40fd6db-b050-4e71-aab1-8b71c5b6bb66","http://resolver.tudelft.nl/uuid:c40fd6db-b050-4e71-aab1-8b71c5b6bb66","Sensors for SOx based on a solid electrolyte of Ag+-b''-alumina with metallic silver as a solid reference electrode","Rao, N.; Srensen, O.T.; Van den Bleek, C.M.; Schoonman, J.","","1993","","electrolyte; solid electrolyte potentiometric sensor sulfur oxide silver ion exchanged beta alumina electrolyte","ru","journal article","","","","","","","","","","","","","",""
"uuid:86ac0c2c-93d9-41d9-a628-acb7e73f35f8","http://resolver.tudelft.nl/uuid:86ac0c2c-93d9-41d9-a628-acb7e73f35f8","Taguchi-type NOx gas sensors based on semiconducting mixed oxides","Rao, N.; Van den Bleek, C.M.; Schoonman, J.","","1993","","Gas detector Nitrogen Oxides Aluminium Oxides Zinc Oxides Vanadium Oxides Sensitivity Medium effect Temperature Detecteur de gaz Azote Oxyde Aluminium Oxyde Zinc Oxyde Vanadium Oxyde Sensibilite Effet milieu Temperature Detector de gas Nitrogeno Oxido Alu","en","journal article","","","","","","","","","","","","","",""
"uuid:dac65709-95d6-412e-8886-4b62b85e080f","http://resolver.tudelft.nl/uuid:dac65709-95d6-412e-8886-4b62b85e080f","Manganese oxide (MnO) thin film cathode for rechargeable microbatteries","Chen, L.; Schoonman, J.","","1993","","battery manganese oxide cathode film manganese oxide cathode film formation characterization","en","journal article","","","","","","","","","","","","","",""
"uuid:ccf95c64-7e20-42b2-a682-f814b9330088","http://resolver.tudelft.nl/uuid:ccf95c64-7e20-42b2-a682-f814b9330088","Electrical properties of SrCe095Yb005O3 in hydrogen containing atmospheres","Kosacki, I.; Becht, J.G.M.; Van Landschoot, R.; Schoonman, J.","","1993","","Experimental study Electrical conductivity Ionic conductivity Proton conductivity Controlled atmosphere Raman scattering Inorganic compound Cerium Strontium Ytterbium Oxides Mixed Etude experimentale Conductivite electrique Conductivite ionique Conductivi","en","journal article","","","","","","","","","","","","","",""
"uuid:8336d617-8cc5-4525-a919-8dde7533dcaf","http://resolver.tudelft.nl/uuid:8336d617-8cc5-4525-a919-8dde7533dcaf","Synthesis of strontium cerium oxide (SrCeO3), barium cerium oxide (BaCeO3), strontium zirconium oxide (SrZrO3), and barium zirconium oxide (BaZrO3) and their reaction with carbon dioxide","Scholten, M.J.; Schoonman, J.; Van Miltenburg, J.C.; Oonk, H.A.J.","","1993","","ceramic oxide synthesis reaction carbon dioxide barium cerium oxide reaction carbon dioxide strontium cerium oxide reaction carbon dioxide strontium zirconium oxide reaction carbon dioxide barium zirconium oxide reaction carbon dioxide","en","conference paper","","","","","","","","","","","","","",""
"uuid:4362a350-cc2e-42d6-bf1c-3db362f4812b","http://resolver.tudelft.nl/uuid:4362a350-cc2e-42d6-bf1c-3db362f4812b","Kinetics and mechanism of tungsten LPCVD using tungsten hexafluoride and silane studied by in-situ growth rate measurements","Ammerlaan, J.A.M.; Van der Put, P.J.; Schoonman, J.","","1993","","vapor deposition tungsten redn tungsten fluoride integrated circuit tungsten CVD","en","conference paper","","","","","","","","","","","","","",""
"uuid:bc0fdd38-dafd-4ba2-b6f2-f664719cf7dc","http://resolver.tudelft.nl/uuid:bc0fdd38-dafd-4ba2-b6f2-f664719cf7dc","All-Solid-State Lithium Microbatteries","Huang, X.J.; Chen, L.Q.; Schoonman, J.","","1993","","","en","journal article","","","","","","","","","","","","","",""
"uuid:29755a1e-4b7a-47cb-a4b8-c7cbbc585e8f","http://resolver.tudelft.nl/uuid:29755a1e-4b7a-47cb-a4b8-c7cbbc585e8f","Chemical vapor deposition (CVD) provides special materials with exceptional properties","Schoonman, J.; van der Put, P.","","1993","","review chem vapor deposition material","nl","journal article","","","","","","","","","","","","","",""
"uuid:1655afd3-552c-495b-b3f6-43452c0a3418","http://resolver.tudelft.nl/uuid:1655afd3-552c-495b-b3f6-43452c0a3418","Gas-to-particle conversion in the particle precipitation-aided chemical vapor deposition process. I: Synthesis of the binary compound titanium nitride. The role of aerosols in materials processing","Dekker, J.P.; Van der Put, P.J.; Veringa, H.J.; Schoonman, J.; Pratsinis, S.E.","","1993","","Experimental study Aerosol deposition Particle precipitation Chemical vapor deposition Powder Binary compound Titanium Nitrides (FIN) Gas mixture Titanium Chlorides (ENT) Ammonia (ENT) Nitrogen Molecules (ENT) Hydrogen Molecules (ENT) Instrumentation Hete","en","journal article","","","","","","","","","","","","","",""
"uuid:ebcf8519-235a-43ea-9761-42f6c332b9af","http://resolver.tudelft.nl/uuid:ebcf8519-235a-43ea-9761-42f6c332b9af","Raman scattering and ionic transport in SrCe1-xYbxO3","Kosacki, I.; Schoonman, J.; Balkanski, M.","","1992","","Experimental study Ionic conductivity Raman scattering Dielectric loss Vibrational mode Spectral line width Intensity Temperature High temperature Thermal annealing Controlled atmosphere Solid solution Chemical composition Vacancy Inorganic compound Ceriu","en","journal article","","","","","","","","","","","","","",""
"uuid:d9c7aec4-6a9f-407c-88ce-aecfdbcd9124","http://resolver.tudelft.nl/uuid:d9c7aec4-6a9f-407c-88ce-aecfdbcd9124","Chemical vapor deposition of thin films of mixed conductors","Van Zomeren, A.A.; Koegler, J.H.; Van der Put, P.J.; Schoonman, J.","","1992","","crystn CVD film mixed conductor titanium sulfide vapor deposition molybdenum sulfide vapor deposition","en","journal article","","","","","","","","","","","","","",""
"uuid:9dfac568-90bd-4e74-b90c-2bf90c878cac","http://resolver.tudelft.nl/uuid:9dfac568-90bd-4e74-b90c-2bf90c878cac","Thermodynamic Calculations on the Chemical Vapor-Deposition of Silicon-Nitride and Silicon from Silane and Chlorinated Silanes","Kruis, F.E.; Scarlett, B.; Bauer, R.A.; Schoonman, J.","","1992","","si-h-cl dissociation-energy heats sicl4 thermochemistry systems equilibria si3n4","en","journal article","","","","","","","","","","","","","",""
"uuid:0750b24a-471b-48af-ba9b-9b76e054f4c7","http://resolver.tudelft.nl/uuid:0750b24a-471b-48af-ba9b-9b76e054f4c7","Thin film techniques for solid oxide fuel cells","Van Dieten, V.E.J.; Schoonman, J.","","1992","","natuurkunde","en","journal article","","","","","","","","","","","","","",""
"uuid:12c4f02b-24ce-4460-a188-aca7e66d771f","http://resolver.tudelft.nl/uuid:12c4f02b-24ce-4460-a188-aca7e66d771f","Electrochemical insertion of lithium into YBa2Cu307y","Chen, L.; Van Zomeren, A.; Schoonman, J.","","1992","","Electrochemical reaction Insertion Lithium Ions High temperature superconductor Barium Copper Yttrium Oxides Mixed Voltammetry Electromotive force Experimental study Reaction electrochimique Insertion Lithium Ion Supraconducteur haute temperature Baryum C","en","journal article","","","","","","","","","","","","","",""
"uuid:e33fe132-9229-433e-ac85-08cbee394535","http://resolver.tudelft.nl/uuid:e33fe132-9229-433e-ac85-08cbee394535","The growth of electrochemical vapor deposited YSZ films","Dekker, J.P.; Van Dieten, V.E.J.; Schoonman, J.","","1992","","yttria zirconia film electrochem vapor deposition","en","journal article","","","","","","","","","","","","","",""
"uuid:5708bd3d-2ef1-40a0-a86c-1931f0c74bc4","http://resolver.tudelft.nl/uuid:5708bd3d-2ef1-40a0-a86c-1931f0c74bc4","Na2SO4-based solid electrolytes for SOx sensors","Rao, N.; Schoonman, J.; Sorensen, O.T.","","1992","","Air pollution Sulfur Oxides Solid electrolyte Sodium Sulfates Measurement sensor Yttrium Sulfates Lanthanum Sulfates Sodium Tungstates Electrical conductivity Pollution air Soufre Oxyde Electrolyte solide Sodium Sulfate Capteur mesure Yttrium Sulfate Lant; electrolyte","en","journal article","","","","","","","","","","","","","",""
"uuid:32322aa0-2b6e-43e8-af52-86fc97baf677","http://resolver.tudelft.nl/uuid:32322aa0-2b6e-43e8-af52-86fc97baf677","Potentiometric NOx (x=1,2) sensors with Ag+,''-alumina as solid electrolyte and Ag metal as solid reference","Rao, N.; Van den Bleek, C.M.; Schoonman, J.","","1992","","Electrochemical detector Nitrogen Oxides Solid electrolyte Alumina Modified material Potentiometry Detecteur electrochimique Azote Oxyde Electrolyte solide Alumine Materiau modifie Potentiometrie Detector electroquimico Nitrogeno Oxido Electrolito solido; electrolyte","en","journal article","","","","","","","","","","","","","",""
"uuid:dce38b43-2fcd-49b2-a510-fb0d417b9fad","http://resolver.tudelft.nl/uuid:dce38b43-2fcd-49b2-a510-fb0d417b9fad","High Tc superconductors as NOx and COx sensor materials","Huang, X.J.; Chen, L.Q.; Schoonman, J.","","1992","","Air pollution Nitrogen Oxides Carbon Oxides Measurement sensor High temperature superconductor Barium Copper Yttrium Oxides Mixed Chemisorption Catalyst Cerium Copper Neodymium Oxides Mixed Bismuth Copper Strontium Oxides Mixed Bismuth Calcium Copper Stro","en","journal article","","","","","","","","","","","","","",""
"uuid:bd84b405-7dae-4b25-8107-4908c891a6a1","http://resolver.tudelft.nl/uuid:bd84b405-7dae-4b25-8107-4908c891a6a1","A novel temperature-gradient Na+-b\""-alumina solid electrolyte based sulfur oxide (SOx) gas sensor without gaseous reference electrode","Rao, N.; Van den Bleek, C.M.; Schoonman, J.","","1992","","electrolyte; temp gradient sulfur oxide gas sensor sodium beta alumina solid electrolyte sensor nonisothermal solid electrolyte gas sensor potentiometry","en","journal article","","","","","","","","","","","","","",""
"uuid:d894e64c-5fa8-46ca-a872-e5cd42001330","http://resolver.tudelft.nl/uuid:d894e64c-5fa8-46ca-a872-e5cd42001330","Sodium sulfate-based solid electrolytes for sulfur oxide (SOx) sensors","Rao, N.; Schoonman, J.; Soerensen, O.T.","","1992","","electrolyte; sodium sulfate sensor sulfur oxide tungsten sulfate chem sensor sulfur oxide lithium sulfate chem sensor sulfur oxide solid electrolyte sodium sulfate chem sensor","en","journal article","","","","","","","","","","","","","",""
"uuid:5acadd7d-83d8-4c29-9264-6c7529adbc14","http://resolver.tudelft.nl/uuid:5acadd7d-83d8-4c29-9264-6c7529adbc14","An Impedance Study of Boron Phosphide Semiconductor Electrodes","Goossens, A.; Schoonman, J.","","1992","","electrolyte; systems","en","journal article","","","","","","","","","","","","","",""
"uuid:3a2998be-276a-4d7d-8e7e-97ea2bacf640","http://resolver.tudelft.nl/uuid:3a2998be-276a-4d7d-8e7e-97ea2bacf640","AN INORGANIC COMPOSITE MEMBRANE COMPRISING MOLECULAR SIEVE CRYSTALS","Geus, E.R.; Jansen, J.C.; Jaspers, B.C.; Schoonman, J.; Van Bekkum, H.","","1992","Abstract of WO 9213631 (A1) Inorganic composite membrane containing molecular sieve crystals, comprising a macroporous support to which molecular sieve crystals and modifications thereof have been applied substantially as a monolayer, said crystals and modifications thereof having been oriented so that, to a substantial extent, the pores of the sieve crystals form a significant included angle with the support surface, there being present between the crystals a gastight matrix, at least gastight to a degree sufficient under practical conditions.","","en","patent","European Patent Office","","","","","","","","","","","","",""
"uuid:1c7ac9f6-8326-4824-bf50-d4f7d9057f0b","http://resolver.tudelft.nl/uuid:1c7ac9f6-8326-4824-bf50-d4f7d9057f0b","Proton conductivity in strontium cerates for hydrogen gas sensors in coal gasification systems","Schutter, F.D.; Vangrunderbeek, J.; Luyten, J.; Kosacki, I.; Landschoot, R.V.; Schram, J.; Schoonman, J.","","1992","","natuurkunde; systems","en","journal article","","","","","","","","","","","","","",""
"uuid:0f0651d4-2719-4534-bfdf-643629efb5c6","http://resolver.tudelft.nl/uuid:0f0651d4-2719-4534-bfdf-643629efb5c6","Charge transport phenomena in thin-film cathodes","Van Zomeren, A.A.; Koegler, J.H.; Schoonman, J.; Van der Put, P.J.","","1992","","charge transport lithium titanium sulfide diffusion lithium sulfide surface structure elec impedance lithium titanium sulfide cell","en","journal article","","","","","","","","","","","","","",""
"uuid:71f24028-787c-415f-949e-7a64c142a574","http://resolver.tudelft.nl/uuid:71f24028-787c-415f-949e-7a64c142a574","Oxygen Diffusion in the Sofc Interconnection Material Lacr(1-X)Mgxo3","Van Dieten, V.E.J.; Dekker, J.P.; Schoonman, J.","","1992","","electrolyte","en","journal article","","","","","","","","","","","","","",""
"uuid:4157b716-fd23-4b79-978e-494f125b91b2","http://resolver.tudelft.nl/uuid:4157b716-fd23-4b79-978e-494f125b91b2","Permeability studies on a silicalite single crystal membrane model","Geus, E.R.; Jansen, A.E.; Jansen, J.C.; Schoonman, J.; Van Bekkum, H.","","1991","","gas permeability silicalite single crystal membrane epoxy embedded zeolite membrane gas permeation","en","book chapter","","","","","","","","","","","","","",""
"uuid:a6bf18a7-5390-4d44-8e47-f03866bff3f9","http://resolver.tudelft.nl/uuid:a6bf18a7-5390-4d44-8e47-f03866bff3f9","Chemical Vapor Precipitation of Submicron Titanium Nitride Powder","Dekker, J.P.; Van der Put, P.J.; Nieuwenhuis, R.R.; Veringa, H.J.; Schoonman, J.","","1991","","","en","journal article","","","","","","","","","","","","","",""
"uuid:85059b73-5645-47f5-a724-8780377edae1","http://resolver.tudelft.nl/uuid:85059b73-5645-47f5-a724-8780377edae1","Electrochemical vapor deposition of stabilized zirconia and interconnection materials for solid oxide fuel cells","Schoonman, J.; Dekker, J.P.; Broers, J.W.; Kiwiet, N.J.","","1991","","review electrochem vapor deposition stabilized zirconia electrolyte solid fuel cell review yttria stabilized zirconia electrolyte review interconnect lanthanum chromite fuel cell review","en","journal article","","","","","","","","","","","","","",""
"uuid:9e57af77-7e02-4ef7-a030-a4074e5e4ffd","http://resolver.tudelft.nl/uuid:9e57af77-7e02-4ef7-a030-a4074e5e4ffd","Structural, Optical, and Electronic-Properties of Silicon Boron Phosphide Heterojunction Photoelectrodes","Goossens, A.; Kelder, E.M.; Beeren, R.J.M.; Bartels, C.J.G.; Schoonman, J.","","1991","","electrical properties impedance spectroscopy materials properties photoelectrochemistry semiconductors photo-electrochemical cells n-si semiconductor electrodes methanol interfaces oxide behavior water photoanodes anodes","en","journal article","","","","","","","","","","","","","",""
"uuid:7e93d271-9dd1-46df-9b31-3542208515e6","http://resolver.tudelft.nl/uuid:7e93d271-9dd1-46df-9b31-3542208515e6","Solid state ionics in solid oxide fuel cells","Schoonman, J.; Dekker, J.P.; Broers, J.W.; Kiwiet, N.J.","","1991","","electrolyte; review fuel cell solid state ionics yttria zirconia fuel cell review lanthanum chromium oxide conductor review","en","book chapter","","","","","","","","","","","","","",""
"uuid:564dfecd-11d3-4b0b-992c-e8770a8277e8","http://resolver.tudelft.nl/uuid:564dfecd-11d3-4b0b-992c-e8770a8277e8","Laser Synthesis of Low-Agglomerated Submicrometer Silicon-Nitride Powders from Chlorinated Silanes","Bauer, R.A.; Becht, J.G.M.; Kruis, F.E.; Scarlett, B.; Schoonman, J.","","1991","","sinterable ceramic powders driven reactions coagulation particles","en","journal article","","","","","","","","","","","","","",""
"uuid:4ae26abf-d446-4cbe-a326-e385c9a5eb56","http://resolver.tudelft.nl/uuid:4ae26abf-d446-4cbe-a326-e385c9a5eb56","Chemical vapour deposition of tungsten by H2 reduction of WCl6. Fourth European workshop on refractory metals and silicides: Selected papers, Saltsjobaden, Sweden, March 24-27, 1991","Ammerlaan, J.A.M.; Boogaard, D.R.M.; Van der Put, P.J.; Schoonman, J.","","1991","","Surfaces Interfaces Condensed matter physics Materials science Physics Surfaces Interfaces Physique de l'etat condense Science des materiaux Physique Superficies Interfases Fisica del estado condensado, Ciencia de los materiales Fisica","en","journal article","","","","","","","","","","","","","",""
"uuid:488d7f87-b9d2-42f4-bece-8ad00e75c059","http://resolver.tudelft.nl/uuid:488d7f87-b9d2-42f4-bece-8ad00e75c059","Electrochemical SO sub x and NO sub x sensors with Ag super plus -beta double prime -alumina as solid electrolyte and Ag as solid reference electrode","Rao, N.; Sorensen, O.T.; Schoonman, J.; Van den Bleek, C.M.","","1991","","Alumina SENSORS Electrochemical ELECTROLYTES, SOLID NITROGEN OXIDES Sensors SULFUR DIOXIDE Sensors ELECTRODES Silver Beta alumina 812 (Ceramics, Refractories and Glass) 701 (Electricity and Magnetism) 801 (Chemistry) 804 (Chemicals Generally) 451 (Air Pol","en","journal article","","","","","","","","","","","","","",""
"uuid:1f19cea4-bc4c-4181-8a80-a7eab4aeea35","http://resolver.tudelft.nl/uuid:1f19cea4-bc4c-4181-8a80-a7eab4aeea35","Chemical vapor deposition of titanium diboride for titanium nitride-titanium diboride laminar composites","Becht, J.G.M.; Van Dieten, V.E.J.; Schoonman, J.","","1991","","titanium diboride; chem vapor deposition; nitride titanium","en","conference paper","","","","","","","","","","","","","",""
"uuid:7afd215c-5bab-4fff-9f45-2fcd80e8a1bb","http://resolver.tudelft.nl/uuid:7afd215c-5bab-4fff-9f45-2fcd80e8a1bb","Deposition of cubic boron monophosphide from tribromoborane and tribromophosphine: A reaction mechanism","Kelder, E.M.; Van der Put, P.J.; Becht, J.G.M.; Schoonman, J.","","1991","","CVD boron phosphide reaction mechanism kinetics boron phosphide CVD adsorption phosphide CVD","en","book chapter","","","","","","","","","","","","","",""
"uuid:04dde6d0-84df-43e5-9027-5f49deff7d85","http://resolver.tudelft.nl/uuid:04dde6d0-84df-43e5-9027-5f49deff7d85","Optical and Dielectric-Properties of Mixed Lead Halides Pbcl2xbr2(1-X)","Lumbreras, M.; Certier, M.; Erguig, H.; Schoonman, J.","","1991","","","en","journal article","","","","","","","","","","","","","",""
"uuid:33e5327f-eab4-4566-b8a2-dfbac495280d","http://resolver.tudelft.nl/uuid:33e5327f-eab4-4566-b8a2-dfbac495280d","Modelling and design of a new laminar mixing-type aerosol reactor using laser-heating","Kruis, F.E.; Scarlett, B.; Schoonman, J.","","1991","","Ceramic materials SILICON AND ALLOYS Powders THERMODYNAMICS CHEMICAL REACTORS LASERS, CARBON DIOXIDE Applications Image analysis package aerosol reactor cvd phase diagrams mach zehnder interferometer software package solgasmix pv 812 (Ceramics, Refractori","en","journal article","","","","","","","","","","","","","",""
"uuid:782ca610-93cb-4a4e-a243-78d9dad2e142","http://resolver.tudelft.nl/uuid:782ca610-93cb-4a4e-a243-78d9dad2e142","Chemical and Electrical-Properties of Yb-Doped Strontium Cerates in Coal Combustion Atmospheres","Luyten, J.; Deschutter, F.; Schram, J.; Schoonman, J.","","1991","","","en","journal article","","","","","","","","","","","","","",""
"uuid:7b09892c-8f82-4cf2-b622-e00d29a43307","http://resolver.tudelft.nl/uuid:7b09892c-8f82-4cf2-b622-e00d29a43307","Plasma Enhanced Chemical Vapor-Deposition and Characterization of Boron-Nitride Gate Insulators on Inp","Bath, A.; Van der Put, P.J.; Becht, J.G.M.; Schoonman, J.; Lepley, B.","","1991","","optical-properties films bn interface technology silicon misfet","en","journal article","","","","","","","","","","","","","",""
"uuid:a2e85402-8964-472b-a93e-daa5e8b77279","http://resolver.tudelft.nl/uuid:a2e85402-8964-472b-a93e-daa5e8b77279","Synthesis of a ceramic zeolite membrane by means of a dip-coating technique","Geus, E.R.; Van Veen, H.M.; Veringa, H.J.; Schoonman, J.; Van Bekkum, H.","","1991","","zeolite ceramic membrane dip coating","en","conference paper","","","","","","","","","","","","","",""
"uuid:eafa6deb-329b-4c07-a8c6-1f3ad3f1f40c","http://resolver.tudelft.nl/uuid:eafa6deb-329b-4c07-a8c6-1f3ad3f1f40c","STM image of silicalite 1 pore structure","Jansen, J.C.; Schoonman, J.; Van Bekkum, H.; Pinet, V.","","1991","","pore structure silicalite 1 zeolite scanning tunneling microscopy silicalite 1 zeolite","en","journal article","","","","","","","","","","","","","",""
"uuid:2cbbdd7a-fe8b-452c-888b-62a0799d3ea5","http://resolver.tudelft.nl/uuid:2cbbdd7a-fe8b-452c-888b-62a0799d3ea5","Deposition of boron nitride by plasma enhanced CVD using borane amine","Becht, J.G.M.; Bath, A.; Hengst, E.; Van der Put, P.J.; Schoonman, J.","","1991","","boron nitride layer deposition borane methylamine","en","conference paper","","","","","","","","","","","","","",""
"uuid:ae06436e-ca66-42d2-92d2-63d9c20fb0bc","http://resolver.tudelft.nl/uuid:ae06436e-ca66-42d2-92d2-63d9c20fb0bc","Design of a ceramic zeolite membrane","Geus, E.R.; Mulder, A.; Vischjager, D.J.; Schoonman, J.; Van Bekkum, H.","","1991","","membrane zeolite design","en","conference paper","","","","","","","","","","","","","",""
"uuid:0c71a446-656c-44bb-b408-06f7ba8b4560","http://resolver.tudelft.nl/uuid:0c71a446-656c-44bb-b408-06f7ba8b4560","Iodine-Doped Crowned Phthalocyanines","Sielcken, O.E.; Nolte, R.J.M.; Schoonman, J.","","1990","","","en","journal article","","","","","","","","","","","","","",""
"uuid:085a8362-8eab-4f3d-918b-14269d7b5a2d","http://resolver.tudelft.nl/uuid:085a8362-8eab-4f3d-918b-14269d7b5a2d","Determination of particle aggregation in ultrafine silicon nitride powders","Van der Put, P.J.; Bauer, R.A.; Van den Assem, A.; Kruis, F.E.; Scarlett, B.; Schoonman, J.","","1990","","silicon nitride laser chem vapor pptn field flow fractionation silicon nitride quasielastic light scattering silicon nitride cluster silicon nitride fractal dimension aggregation ultrafine silicon nitride powder","en","book chapter","","","","","","","","","","","","","",""
"uuid:ca5397d8-3855-4f0c-8f26-ab4d1dd71854","http://resolver.tudelft.nl/uuid:ca5397d8-3855-4f0c-8f26-ab4d1dd71854","Electrochemical vapor deposition: Theory and experiment","Kiwiet, N.J.; Schoonman, J.","","1990","","yttrium zirconium oxide film deposition lanthanum chromium oxide film deposition electrochem vapor deposition oxide film fuel cell oxide electrochem vapor deposition","en","journal article","","","","","","","","","","","","","",""
"uuid:a2b5595e-46e9-4bbe-9930-2d215bbe20a4","http://resolver.tudelft.nl/uuid:a2b5595e-46e9-4bbe-9930-2d215bbe20a4","Microstructure of laser-deposited silicon nitride powders","Bauer, R.A.; Van den Assem, A.; Van der Put, P.J.; Scarlett, B.; Schoonman, J.","","1990","","Ceramic materials SILICON NITRIDE Microstructure CERAMIC MATERIALS Laser Applications SILICON NITRIDE Vapor Deposition POWDERS Laser deposited silicon nitride powders chemical vapour deposition sedimentation field flow fractionation quasi elastic light sc","en","conference paper","","","","","","","","","","","","","",""
"uuid:25c15d46-eb08-420e-a749-90d5fd0aa21b","http://resolver.tudelft.nl/uuid:25c15d46-eb08-420e-a749-90d5fd0aa21b","Kinetic studies of thin film polycrystalline cubic boron monophosphide grown by CVD","Kelder, E.M.; Goossens, A.; Van der Put, P.J.; Schoonman, J.","","1990","","crystn kinetics boron phosphide film","en","conference paper","","","","","","","","","","","","","",""
"uuid:723920af-55ba-4174-b550-1ddb5a2b60a5","http://resolver.tudelft.nl/uuid:723920af-55ba-4174-b550-1ddb5a2b60a5","Oxygen ion conductivity in dynamically compacted yttrium barium copper oxide (YBa2Cu3O7-x)","Kiwiet, N.J.; Schoonman, J.; Van der Steen, A.C.; Kodde, H.H.; Schrader, M.A.","","1990","","ionic cond barium copper yttrium oxide oxygen cond barium copper yttrium oxide","en","conference paper","","","","","","","","","","","","","",""
"uuid:e1f7ac39-6bb9-4753-aa89-1ec0354ec5b6","http://resolver.tudelft.nl/uuid:e1f7ac39-6bb9-4753-aa89-1ec0354ec5b6","The stabilization of silicon photoelectrodes by a boron phosphide (BP) protective optical window","Goossens, A.; Kelder, E.M.; Schoonman, J.","","1990","","silicon photoelectrode boron phosphide window","en","conference paper","","","","","","","","","","","","","",""
"uuid:f3ab6d09-9570-48fc-9b8c-576f6c65833e","http://resolver.tudelft.nl/uuid:f3ab6d09-9570-48fc-9b8c-576f6c65833e","Ionic conductivity of ceramic superconductors","Vischjager, D.J.; Van Zomeren, A.A.; Schoonman, J.; Kontoulis, I.; Steele, B.C.H.","","1990","","ionic cond cuprate superconductor","en","journal article","","","","","","","","","","","","","",""
"uuid:de450c65-7332-45b4-8118-aaeef84c3c5c","http://resolver.tudelft.nl/uuid:de450c65-7332-45b4-8118-aaeef84c3c5c","Chemical vapor precipitation of silicon nitride powders with a tunable carbon dioxide laser","Bauer, R.A.; Van Weeren, R.; Van der Put, P.J.; Kruis, F.E.; Scarlett, B.; Schoonman, J.","","1990","","silicon nitride chem vapor deposition laser excitation dichlorosilane ammonia reaction","en","book chapter","","","","","","","","","","","","","",""
"uuid:be14b1ec-f548-4dfd-92c0-4b9f254dfda2","http://resolver.tudelft.nl/uuid:be14b1ec-f548-4dfd-92c0-4b9f254dfda2","The impedance of surface recombination at illuminated semiconductor electrodes. A non-equilibrium approach","Goossens, A.; Schoonman, J.","","1990","","electrolyte; semiconductor electrolyte interface surface recombination electron hole recombination semiconductor electrode elec impedance energy bond structure interface","en","journal article","","","","","","","","","","","","","",""
"uuid:411d06ba-c125-472d-abb9-ca26efb281e5","http://resolver.tudelft.nl/uuid:411d06ba-c125-472d-abb9-ca26efb281e5","Laser Chemical Vapor Precipitation of Submicrometer Silicon and Silicon-Nitride Powders from Chlorinated Silanes","Bauer, R.A.; Smulders, R.; Becht, J.G.M.; Van der Put, P.J.; Schoonman, J.","","1989","","","en","journal article","","","","","","","","","","","","","",""
"uuid:7267d048-adac-49c8-910d-0b8580fc2b77","http://resolver.tudelft.nl/uuid:7267d048-adac-49c8-910d-0b8580fc2b77","Laser Cvp of Ultrafine Ceramic Powders of Si and Si3n4 - a Study of the Flow Pattern of the Laser Flame","Bauer, R.A.; Kruis, F.E.; Becht, J.G.M.; Scarlett, B.; Schoonman, J.","","1989","","","en","journal article","","","","","","","","","","","","","",""
"uuid:e6869d75-50d5-4a4a-98de-b088b2e26d4f","http://resolver.tudelft.nl/uuid:e6869d75-50d5-4a4a-98de-b088b2e26d4f","Chemical vapor deposition in the system titanium-nitrogen-boron: Titanium mononitride as a diffusion barrier for boron","Becht, J.G.M.; Van der Put, P.J.; Schoonman, J.","","1989","","deposition titanium nitride boron diffusion barrier","en","journal article","","","","","","","","","","","","","",""
"uuid:87fd14d3-e71b-4543-9397-217046abf3ea","http://resolver.tudelft.nl/uuid:87fd14d3-e71b-4543-9397-217046abf3ea","Nh4y and Hy Zeolites as Electrolytes in Hydrogen Sensors","Dekker, M.; Tzand, I.; Schram, J.; Schoonman, J.","","1989","","electrolyte","en","journal article","","","","","","","","","","","","","",""
"uuid:467066f7-7af6-4a27-bd37-7a6e40f7c559","http://resolver.tudelft.nl/uuid:467066f7-7af6-4a27-bd37-7a6e40f7c559","Cvd of Laminar Composites in the System Tin-Tib2","Becht, J.G.M.; Van der Put, P.J.; Schoonman, J.","","1989","","","en","journal article","","","","","","","","","","","","","",""
"uuid:caf6becb-c4de-4738-8b45-9bed5d3c613f","http://resolver.tudelft.nl/uuid:caf6becb-c4de-4738-8b45-9bed5d3c613f","Vapor-phase deposition of ceramic coatings","Van der Put, P.J.; Becht, J.G.M.; Schoonman, J.","","1989","","review vapor phase deposition ceramic coating ceramic vapor phase review phys vapor deposition review chem vapor deposition review","nl","journal article","","","","","","","","","","","","","",""
"uuid:18fd8fc1-f805-4a44-a7ec-4f69f0282913","http://resolver.tudelft.nl/uuid:18fd8fc1-f805-4a44-a7ec-4f69f0282913","Hydrothermal Processing of Ceramic Powders for Alumina-Magnesia Spinels","Krijgsman, P.; Becht, J.G.M.; Schoonman, J.","","1989","","","en","journal article","","","","","","","","","","","","","",""
"uuid:9d56be36-bb82-4714-b193-5414ef4f7c1a","http://resolver.tudelft.nl/uuid:9d56be36-bb82-4714-b193-5414ef4f7c1a","Alkali-Metal Picrate Complexes of Crowned Phthalocyanines - Solid-State Structures and Electrical-Properties","Sielcken, O.E.; Vanlindert, H.C.A.; Drenth, W.; Schoonman, J.; Schram, J.; Nolte, R.J.M.","","1989","","","en","journal article","","","","","","","","","","","","","",""
"uuid:801e4bf9-4635-438d-ad71-83ac7b5c6e5c","http://resolver.tudelft.nl/uuid:801e4bf9-4635-438d-ad71-83ac7b5c6e5c","Polycrystalline Boron Phosphide Semiconductor Electrodes","Goossens, A.; Kelder, E.M.; Schoonman, J.","","1989","","","en","journal article","","","","","","","","","","","","","",""
"uuid:e7aef844-eb87-408b-b372-efa169ebd01b","http://resolver.tudelft.nl/uuid:e7aef844-eb87-408b-b372-efa169ebd01b","Laser excited synthesis of sub-micron powders","Becht, J.G.M.; Bauer, B.A.; Van der Put, P.J.; Schoonman, J.; Scarlett, B.","","1989","","silicon nitride laser synthesis fine powder","en","conference paper","","","","","","","","","","","","","",""
"uuid:20ad6a1e-c505-4bea-b1e0-f77afb742f60","http://resolver.tudelft.nl/uuid:20ad6a1e-c505-4bea-b1e0-f77afb742f60","Study of Boron-Nitride Gate Insulators Grown by Low-Temperature Plasma Enhanced Chemical Vapor-Deposition on Inp","Bath, A.; Van der Put, P.J.; Schoonman, J.; Lepley, B.","","1989","","","en","journal article","","","","","","","","","","","","","",""
"uuid:c456afc0-8a72-4d5f-9a1c-02e89a5d109c","http://resolver.tudelft.nl/uuid:c456afc0-8a72-4d5f-9a1c-02e89a5d109c","Electrochemical vapor deposition of SOFC [solid oxide fuel cell] components","Dekker, J.P.; Kiwiet, N.J.; Schoonman, J.","","1989","","zirconia yttria electrochem vapor deposition kinetics oxidn zirconia electrolyte model fuel cell zirconia electrolyte deposition","en","conference paper","","","","","","","","","","","","","",""
"uuid:181be43c-d42a-4fe4-837c-2840a856a768","http://resolver.tudelft.nl/uuid:181be43c-d42a-4fe4-837c-2840a856a768","Mixed ionic-electronic conduction in HTcS","Vischjager, D.J.; Schram, J.; Mackor, A.; Schoonman, J.","","1989","","electrolyte; ionic electronic cond superconductors cuprate barium yttrium cuprate ionic conduction europium barium cuprate ionic conduction lanthanum strontium cuprate ionic conduction","en","conference paper","","","","","","","","","","","","","",""
"uuid:2576c267-5265-4765-8194-d7d59ac399be","http://resolver.tudelft.nl/uuid:2576c267-5265-4765-8194-d7d59ac399be","Laser vapor-phase synthesis of submicron silicon and silicon nitride powders from chlorinated silanes","Bauer, R.A.; Van der Put, P.J.; Becht, J.G.M.; Schoonman, J.","","1988","","silicon nitride laser vapor synthesis silane reaction ammonia","nl","journal article","","","","","","","","","","","","","",""
"uuid:e5b9f4f6-2183-446c-aac4-886fead6b5e1","http://resolver.tudelft.nl/uuid:e5b9f4f6-2183-446c-aac4-886fead6b5e1","Vapor phase synthesis of ultrafine silicon nitride powders","Jacquemijns, E.J.; Van der Put, P.J.; Schoonman, J.","","1988","","silicon nitride ultrafine prepn ammonia reaction silicon chloride vapor","en","journal article","","","","","","","","","","","","","",""
"uuid:d5376553-b8b6-4bc9-b631-554eb02e0100","http://resolver.tudelft.nl/uuid:d5376553-b8b6-4bc9-b631-554eb02e0100","Oxygen diffusion in YBa2Cu3O7-x; an impedance spectroscopy study","Vischjager, D.J.; Van der Put, P.J.; Schram, J.; Schoonman, J.","","1988","","Experimental study Ionic conductivity Electrical conductivity Superconducting transition Activation energy Vacancy Oxygen Stoichiometry Self diffusion Low temperature High temperature Temperature High temperature superconductor Oxide ceramics Inorganic co","en","journal article","","","","","","","","","","","","","",""
"uuid:0258581a-cdca-48dd-b400-01abc5d894e4","http://resolver.tudelft.nl/uuid:0258581a-cdca-48dd-b400-01abc5d894e4","Chemical-vapor deposition (CVD) of laminated titanium nitride-titanium boride (TiN-TiB2)-system composites","Becht, J.G.M.; Van der Put, P.J.; Schoonman, J.","","1988","","titanium nitride boride composite coating","nl","journal article","","","","","","","","","","","","","",""
"uuid:c8597006-dd97-42b4-bd6f-a78274ea0d90","http://resolver.tudelft.nl/uuid:c8597006-dd97-42b4-bd6f-a78274ea0d90","Electrical-Conductivity of Mixed Lead Halides Pbcl2xbr2(1-X)","Lumbreras, M.; Schram, J.; Schoonman, J.; Schouler, E.J.L.","","1988","","","en","journal article","","","","","","","","","","","","","",""
"uuid:dc9aa7e2-2e1e-4129-85c4-5d4461dcd9ce","http://resolver.tudelft.nl/uuid:dc9aa7e2-2e1e-4129-85c4-5d4461dcd9ce","Impedance Spectroscopy of Sulfate Solid Electrolytes","Dekker, M.; Kalwij, R.A.; Schram, J.; Schoonman, J.","","1988","","electrolyte","en","journal article","","","","","","","","","","","","","",""
"uuid:a213fab2-512c-43e0-a470-8ced4d59a56b","http://resolver.tudelft.nl/uuid:a213fab2-512c-43e0-a470-8ced4d59a56b","Electrical-Conductivity in Complexes of Crowned-Phthalocyanines with Metal-Salts","Sielcken, O.E.; Schram, J.; Nolte, R.J.M.; Schoonman, J.; Drenth, W.","","1988","","","en","journal article","","","","","","","","","","","","","",""
"uuid:6ff61b6f-22ee-4f92-96d9-7bc71502de1c","http://resolver.tudelft.nl/uuid:6ff61b6f-22ee-4f92-96d9-7bc71502de1c","Laser vapor phase synthesis of submicron silicon and silicon nitride powders from halogenated silanes","Bauer, R.A.; Smulders, R.; Geus, E.R.; Van der Put, P.J.; Becht, J.G.M.; Schoonman, J.","","1988","","laser synthesis silicon nitride powder chlorosilane reaction ammonia ceramic powder","en","conference paper","","","","","","","","","","","","","",""
"uuid:b927653b-3947-4469-a281-65db33166752","http://resolver.tudelft.nl/uuid:b927653b-3947-4469-a281-65db33166752","Doped lithium iron oxide (LiFeO2) as MCFC cathode material","Van den Noort, M.A.; Van der Put, P.J.J.M.; Schoonman, J.","","1988","","lithium magnesium iron oxide cond cathode lithium magnesium iron oxide molten carbonate fuel cell cathode","en","journal article","","","","","","","","","","","","","",""
"uuid:e879c900-696f-421f-ae58-0d4f22164cda","http://resolver.tudelft.nl/uuid:e879c900-696f-421f-ae58-0d4f22164cda","Particle-Size Analysis by Sedimentation Field Flow Fractionation","Scarlett, B.; Merkus, H.G.; Mori, Y.; Schoonman, J.","","1988","","","en","journal article","","","","","","","","","","","","","",""
"uuid:4e927af2-239f-4d72-aa23-2ddf0aeb96c7","http://resolver.tudelft.nl/uuid:4e927af2-239f-4d72-aa23-2ddf0aeb96c7","Cvd of Laminar Ceramic Composites","Becht, J.G.M.; Van der Put, P.J.; Schoonman, J.","","1988","","","en","journal article","","","","","","","","","","","","","",""
"uuid:f37c758a-3694-4114-a0f4-6b746195f979","http://resolver.tudelft.nl/uuid:f37c758a-3694-4114-a0f4-6b746195f979","The Analysis of the Small-Signal Ac-Response of Bovine Enamel Membranes","Scholberg, H.P.F.; Borggreven, J.; Driessens, F.C.M.; Schoonman, J.","","1987","","","en","journal article","","","","","","","","","","","","","",""
"uuid:cc646d7a-376e-4212-afa4-d4b301dcf902","http://resolver.tudelft.nl/uuid:cc646d7a-376e-4212-afa4-d4b301dcf902","Crowned Phthalocyanines","Sielcken, O.E.; Drenth, W.; Schoonman, J.; Schram, J.; Nolte, R.J.M.","","1987","","","en","journal article","","","","","","","","","","","","","",""
"uuid:af18ed87-1fc2-44d6-92ac-955a183de077","http://resolver.tudelft.nl/uuid:af18ed87-1fc2-44d6-92ac-955a183de077","Electrical-Properties of Mixed Lead Halides Pbcl2xbr2(1-X)","Lumbreras, M.; Schoonman, J.; Schouler, E.J.L.","","1987","","","en","journal article","","","","","","","","","","","","","",""
"uuid:09599c0b-b127-43ea-b365-9f620a4aaeb7","http://resolver.tudelft.nl/uuid:09599c0b-b127-43ea-b365-9f620a4aaeb7","Thermally Stimulated Depolarization Current Measurements on Ba1-Xlaxf2+X and Ba1-Xuxf2+2x Solid-Solutions","Ouwerkerk, M.; Veldkamp, F.J.; Schoonman, J.","","1987","","","en","journal article","","","","","","","","","","","","","",""
"uuid:8ba58d6d-f268-42fb-a108-23243521e2ff","http://resolver.tudelft.nl/uuid:8ba58d6d-f268-42fb-a108-23243521e2ff","Fluorine Solid Electrolytes - Fundamentals and Applications","Schoonman, J.","","1987","","electrolyte","en","journal article","","","","","","","","","","","","","",""
"uuid:9d7dfdd6-f61a-44d7-b972-dba6c9c9f45a","http://resolver.tudelft.nl/uuid:9d7dfdd6-f61a-44d7-b972-dba6c9c9f45a","Thermal Depolarization Phenomena in Fluoride Solid Electrolytes","Schoonman, J.","","1986","","electrolyte","fr","journal article","","","","","","","","","","","","","",""
"uuid:74f2ad0f-375e-420e-9066-693fc72e145d","http://resolver.tudelft.nl/uuid:74f2ad0f-375e-420e-9066-693fc72e145d","Structure and Ionic-Conductivity of Mixed Lead Halides Pbcl2xbr2(1-X).2","Lumbreras, M.; Protas, J.; Jebbari, S.; Dirksen, G.J.; Schoonman, J.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:e7825270-fdc9-4635-bf14-15b4a05b2d9f","http://resolver.tudelft.nl/uuid:e7825270-fdc9-4635-bf14-15b4a05b2d9f","Neutron-Diffraction and Tsdc on Ba1-Xuxf2+2x Solid Electrolytes","Ouwerkerk, M.; Andersen, N.H.; Veldkamp, F.F.; Schoonman, J.","","1986","","electrolyte","en","journal article","","","","","","","","","","","","","",""
"uuid:cdfa064d-0aed-47d1-8357-931159d19ad8","http://resolver.tudelft.nl/uuid:cdfa064d-0aed-47d1-8357-931159d19ad8","Photoelectrochemical Properties of Polycrystalline Mg-Doped Para-Type Iron(Iii) Oxide","Tinnemans, A.H.A.; Koster, T.P.M.; Thewissen, D.; Mackor, A.; Schoonman, J.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:407c0963-e1d2-42ac-8b9a-6e32d3c8e694","http://resolver.tudelft.nl/uuid:407c0963-e1d2-42ac-8b9a-6e32d3c8e694","A Study of the Disorder in Heavily Doped Ba1-Xlaxf2+X by Neutron-Scattering, Ionic-Conductivity and Specific-Heat Measurements","Andersen, N.H.; Clausen, K.N.; Kjems, J.K.; Schoonman, J.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:0a0202b2-111f-4cfe-9768-81b36669936e","http://resolver.tudelft.nl/uuid:0a0202b2-111f-4cfe-9768-81b36669936e","Structure and Ionic-Conductivity of Mixed Lead Halides Pbcl2xbr2(1-X).1","Lumbreras, M.; Protas, J.; Jebbari, S.; Dirksen, G.J.; Schoonman, J.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:b09c418f-af71-4a35-9026-a43d1f478c9a","http://resolver.tudelft.nl/uuid:b09c418f-af71-4a35-9026-a43d1f478c9a","Interfacial Phenomena of Polycrystalline Mg-Doped Para-Type Iron(Iii) Oxide Photoelectrodes","Tinnemans, A.H.A.; Koster, T.P.M.; Mackor, A.; Schoonman, J.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:8ccd667f-89f0-470d-b717-32da087283d1","http://resolver.tudelft.nl/uuid:8ccd667f-89f0-470d-b717-32da087283d1","Anorganische materialen: De synthese van eigenschappen","Schoonman, J.","","1985","","Intreerede / redevoering JDA / Anorganische chemie: algemeen / Inorganic chemistry: general","nl","public lecture","","","","","","","","","","","","","",""
"uuid:2d979d93-5770-4f6b-a538-dfe20bd12666","http://resolver.tudelft.nl/uuid:2d979d93-5770-4f6b-a538-dfe20bd12666","Tsdc and Neutron-Scattering Measurements on Ba1-Xlaxf2+X and Ba1-Xuxf2+2x Solid-Solutions","Ouwerkerk, M.; Veldkamp, F.F.; Andersen, N.H.; Schoonman, J.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:1ca311c5-d824-4487-bc7c-22a369302eec","http://resolver.tudelft.nl/uuid:1ca311c5-d824-4487-bc7c-22a369302eec","Dislocation Polarization and Space-Charge Relaxation in Solid-Solutions Ba1-Xlaxf2+X","Laredo, E.; Suarez, N.; Bello, A.; Puma, M.; Figueroa, D.; Schoonman, J.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:0ff7ee9d-8258-400a-b2e4-13549cc1a782","http://resolver.tudelft.nl/uuid:0ff7ee9d-8258-400a-b2e4-13549cc1a782","Taludbekleding van gezette steen. Fase 2: Verslag onderzoek","Visser, P.J. .; Taat, H.; Schoonman, H.B.","Kenter, C.J. (contributor); Rijkswaterstaat","1984","In de tweede helft van 1981 is door de Deltadienst van Rijkswaterstaat aan het Waterloopkundig Laboratorium en het Laboratorium voor Grondmechanica opdracht verleend voor een onderzoek naar de stabiliteit onder golfaanval van de teenkonstruktie en taludbekleding van de Oesterdam, damvak Marollegat. In het kader van deze opdracht is onder meer een grootschalige modelproef uitgevoerd in de Deltagoot. Dit model is konform de werkelijkheid opgebouwd uit de materialen die voor dit doel door de opdrachtgever ter beschikking worden gesteld. Naast de grootschalige proeven (Deltagoot) zijn ook kleinschalige proeven uitgevoerd (Scheldegoot). Uit beide modellen zijn voor de aanvang van de proeven representatieve materiaalmonsters getrokken waarvan de eigenschappen zijn bepaald, die voor de evaluatie van het modelonderzoek van belang zijn. Deze evaluatie en daarmee ook dit materiaalonderzoek valt onder fase 2 van het Fundamenteel Onderzoek ""Stabiliteit steenzettingen"". Kort na het onderzoek ten behoeve van de Oesterdam zijn in de Deltagoot nog een viertal grootschalige onderzoeken met taludbekledingen uitgevoerd.","talud; bekleding","nl","report","Deltares (WL/GD)","","","","","","","","","","","","Steenzettingen - TAW/ENW",""