Gas permeation through graphene membranes has received considerable attention for water purification and molecular sieving applications. However, characterization of the permeation has been limited to long timescales of minutes. This thesis shows a method for measuring gas permeation through porous graphene membranes at the microsecond timescale. Suspended porous graphene membranes, with an average pore size of 14 nm and a single 400 nm pore, are brought into sinusoidal motion by optothermal actuation. By monitoring the frequency dependent phase delay between actuation signal and mechanical motion, the gas dependent permeation time of the porous membrane is determined. The permeation time constant is demonstrated to be proportional to the square root of the molecular mass, indicating an effusion dominated permeation mechanism. The determination of permeation at timescales below 1 ms using a femtoliter gas cavity opens up opportunities for novel nanoscale porous graphene based gas sensors, with very fast response times.

Nanomechanical resonators made from graphene are widely researched for their potential applications due to their high sensitivity. Their atomic scale thickness makes it that these resonators exhibit amplitude-dependent damping at relatively small driving forces. To further increase the performance of these devices, it is essential to understand the dissipation process. Although many physical mechanisms that lead to linear damping have been investigated, the origin of nonlinear damping remains largely unknown. Nonlinear damping in nanomechanical resonators is typically studied using phenomenological models. In this thesis, a multilayer graphene resonator is studied that is electrostatically actuated. The graphene resonator is modeled as a viscoelastic membrane operating in the geometrically nonlinear regime. The amplitude-dependent damping term used in phenomenological models arises naturally in the equation of motion. The experimentally obtained nonlinear frequency responses are then fitted using a fully automated algorithm. Based on these fits, the viscoelastic properties of graphene and its loss tangent are found. When the same analysis is done for a single-layer graphene resonator coupled to an optical cavity, negative nonlinear damping is observed which turns positive with increasing laser power. The effect of the optical field on the nonlinear damping is then modeled. It is found that the change in equilibrium position of the graphene membrane due to laser illumination as well as geometric imperfections can lie at the root of the negative nonlinear damping behavior.

Ever since its inception, graphene has been the subject of research in many parts of the world. This is due to its exceptional mechanical and electrical properties, which makes it ideal for NanoElectroMechanical (NEMS) devices. The inherent nature of NEMS devices, includes low damping, large amplitudes of oscillation, resonant operating conditions, and the presence of nonlinear force fields. This sets an ideal stage for the appearance of nonlinear behavior. In this thesis, appearance of such nonlinear behavior in optothermally actuated graphene nanodrum resonators is studied. Frequency response arising from parametric excitation is explained based on, time modulated stiffness due to temperature variation in the membrane. Also, the response arising from direct excitation is discussed based on initial geometric imperfection present in the membrane. In order to explain the nonlinear response seen in graphene resonators, novel analytical models are developed and its corresponding limitations are discussed. A single differential equation is used to simulate the behavior of both directly and parametrically excited graphene nanoresonator. This equation is used to study the influence of nonlinear damping on response of the system. Then, an illustration is provided on characterization of graphene properties from the parametric response of the system. Finally, it is concluded that, alternative damping mechanism and other physical phenomena could be influencing the system dynamics. Therefore, modeling of these phenomena would lead to better matching of the experimental results.