Integration of electro-chemical FET-based sensors in silicon- and polymer-based organs-on-chip

Currently, preclinical drug testing and disease modelling are based on static cell cultures and animal models that often fail at predicting the human pathophysiology. Alternatively, Organ-on-Chips (OoCs), dynamic microphysiological platforms, can be employed to recapitulate organ functions and mimic the cell's microphysiological environment....

Dual-Gate Fet-Based Charge Sensor Enhanced by In-Situ Electrode Decoration in a MEMS Organs-On-Chip Platform

Continuous monitoring of tissue microphysiology is a key enabling feature of the organ-on-chip (OoC) approach for drug screening and disease modeling. Sensing charged species in OoC tissue microenvironments is thereby essential. However, the inherently small (i.e., cm) size of OoC devices poses the challenging requirement to integrate...

Single electron-ics with carbon nanotubes

We experimentally investigate Quantum Dots, formed in Carbon Nanotubes. The first part of this thesis deals with charge sensing on such quantum dots. The charge sensor is a metallic Single-electron-transistor, sensitive to the charge of a single electron on the quantum dot. We use this technique for real-time charge readout and precise tuning of...

Electron spins in few-electron lateral quantum dots

This thesis describes a series of experiments aimed at understanding and controlling single electron spins confined in semiconductor lateral quantum dots, with the long-term goal of creating of a small-scale quantum computer. The confinement of these electrons results in a quantized energy spectrum, and therefore, the quantum dots can be...