Lectures in course MICRO-470: Scaling laws in micro & nanosystems

Finite Element Method: Basics

Covers the basics of the Finite Element Method for solving complex engineering problems through element division and algebraic equations.

Mechanical Scaling: Animals and Plants

Explores mechanical scaling in Micro and Nanosystems, focusing on animals and plants.

Finite Element Simulation of Electro-Magnetic Micro-Actuator

Explores finite element simulation of electro-magnetic micro-actuators and scaling laws in micro and nanosystems.

Electrostatics in MEMS: Scaling Laws & Applications

Explores scaling laws and applications of electrostatics in MEMS, covering topics like parallel plate capacitors, zipping actuators, and MEMS gyroscopes.

Finite Element Modeling: Introduction

Introduces finite element modeling for numerical solutions to complex problems.

Mechanical Scaling: Lumped Element Modelling

Covers Lumped Element Modelling in mechanical systems, simplifying complex systems into discrete elements that exchange energy.

Electrostatic Devices: Modeling & Simulation

Covers modeling and simulation of electrostatic devices in micro and nanosystems.

Molecular machines: Nature's nanotechnology

Explores nature's molecular machines, such as ATP synthase and DNA origami.

Mechanical Scaling: Cantilevers, Stress, and Dynamics

Explores mechanical scaling in micro and nanosystems, focusing on cantilevers, stress, dynamics, and non-linear effects.

Electro-Thermo-Mechanical Analysis: Scaling Laws & Simulations

Explores electro-thermo-mechanical systems in micro and nanosystems, covering thermal bimorphs, material properties, actuators, and multiphysics simulations.

Non-linear Effects in MEMS Cantilevers

Discusses non-linear effects in MEMS cantilevers and their importance when motion exceeds 40% of the spring thickness.

Introduction: General

Covers scaling laws and simulations in micro and nanosystems, exploring phenomena at smaller scales and the breakdown effects of down-scaling.

Thermal FEM: Steady State and Transient Analysis

Explores steady-state and transient thermal analysis of silicon beams, including convection effects and practical exercises.

Mechanical Resonances: Thin Films and Stress Analysis

Explores mechanical resonances, modal analysis, and stress analysis in thin films.

Fluidics: Fundamentals and Applications

Explores the fundamentals of fluidics, covering Reynolds number, vortices, swimming, sedimentation, pressure drop, flow profiles, lift forces, and gas flows.

Thermo-Mechanical Noise: Scaling Laws & Simulations

Explores thermo-mechanical noise in micro and nanosystems, covering spectral density, position fluctuation, accelerometers, calibration, and quality factor scaling.

Surface Forces: Electrostatic & Van der Waals Interactions

Explores electrostatic and van der Waals forces, adhesion in geckos, and methods to prevent stiction in microsystems.

Structural Mechanics Part 2: FEM & Scaling Laws

Explores Finite Element Modeling in Structural Mechanics, covering convergence, nonlinear displacement, and scaling laws in micro and nanosystems.

Introduction to LEM and Equivalent Circuits

Covers the Lumped Element Model, 'lumping' systems, equivalent circuits, and domain conversion.

Structural Mechanics FEM: A First Model

Covers Finite Element Modeling in Structural Mechanics, building a first model to analyze a Polysilicon Micro-Cantilever and understand load types.