Liwei Lin (Advisor)

Research Advised by Professor Liwei Lin

Lin Group:  List of Projects | List of Researchers

Jacqueline Elwood

Alumni
Mechanical Engineering
Professor Liwei Lin (Advisor)
Ph.D. 2021

Received a B.S in Nanoscale Engineering at the SUNY University at Albany in Albany, NY. Joined the Liwei Lin Lab in Aug 2016 where research has focused on creating multi-functional, multi-material 3D printed systems.

Zhichun Shao

Alumni
Mechanical Engineering
Professor Liwei Lin (Advisor)
Ph.D. 2021, M.A. 2019

Zhichun Shao received his B.S. in Engineering Mechanics from Tsinghua University, China in 2017 and M.S. in Mechanical Engineering from the University of California, Berkeley in 2019. He is currently pursuing a Ph.D. in MEMS/Nano in Mechanical Engineering at UC Berkeley under the supervision of Professor Liwei Lin.

BPN799: 3D Printed Microsensors

Jacqueline Elwood
2021

We aim to develop multi-functional, multi-material 3D printed structures for the development of 3D printed microsensors. Using these multi-functional 3D printed structures, we plan to demonstrate simple sensing platforms, such as EtOH sensing for monitoring of food quality, fermentation, or ethanol content in the body, for proof-of-concept in combining conductive materials with commercially available 3D printing materials or 3D printers. Upon further development, this combination could prove critical in resolving the foremost limitations of conventional diagnostic devices (i.e....

Ultra High Frequency Piezoelectric Resonators: Suspension and Elastic Coupling

James Porter
Albert P. Pisano
Roger T. Howe
Liwei Lin
2004

In this research project, the suspension and elastic coupling of Film Bulk AcousticResonators (FBAR) has been investigated. Individual resonators and small arrays of AlN FBARs have been designed and fabricated in a post-CMOS compatible process. Suspensions based on networks of thin beams did not perform well, but m...

Microresonators as Vacuum Gauges

Sharon Oh
Roger T. Howe
Liwei Lin
2001
Resonators are sensitive to physical inputs such as pressure and force. The parameters of interest are measured by the shift in resonance frequency. The ease of measurement and their high sensitivity make resonators an attractive means of measuring many...

Pressure Driven Microflow Through a Double-T Metering Section

Luke Hunter
Albert P. Pisano
Liwei Lin
2003

Many assay devices require metering a calibrated amount of sample foranalysis. As mobile/handheld assay devices become closer to realization, power usage becomes more critical for all system components. Current designs utilize electrokinetically driven flow and well-defined channel geome...

Integrated MEMS Technologies for Adaptive Optics

Blake Lin
Richard S. Muller
Tsu-Jae King Liu
Liwei Lin
2008

Image resolutions of modern optical systems are many times limited by wavefront aberrations due to turbulence in the optical media. Adaptive Optics (AO) is a technology that utilizes deformable mirrors (DM) to correct the wavefront distortion, thereby enhancing the image resolution. In this research, we investigate the design and fabrication of micromechanical-deformable-mirror arrays for AO applications. The mirror arrays are produced using surface micromachining techniques developed for the fabrication of Microelectromechanical Systems (MEMS).

Because many AO...

Micromachined Plastic Millimeter-wave Radar Components

Firas Sammoura
Liwei Lin
Albert P. Pisano
Andrew Neureuther
2006
This research aims to develop plastic millimeter-wave components, including waveguides, tunable filters, phase shifters and antennas, toward the low-cost, batch fabrication for integrated systems for applications such as all-weather automotive and airplane landing radars. The key micromachining processes developed in this work include micro hot embossing, electroplating, polishing and bonding and as a proof of concept demonstration, micro injection molding of...

Biomimetic, Polymeric Transistor-Based Biosensor Technology

Jim Cheng
Albert P. Pisano
Ming C. Wu
Liwei Lin
2009

The goal of this research is the creation of robust, flexible, polymer sensors and circuits fabricated partially from the low cost biopolymer, chitosan, the deacetylated form of chitin which is the second most abundant polyssacharide in nature. Chitin is found in crustaceans, insects, bacteria and fungi. The sensors will detect diatomic gases and DNA to more complex macro molecules (e.g. exotoxins) in a fluidic or dry environment. Polymer-nanoparticle (e.g. Ge) hybrid films allow for development of robust polymer thin-film transistors and, with optimization of the hybrid film,...

Chitosan as a MEMS Engineering Material

Jim Cheng
Albert P. Pisano
Liwei Lin
2006
Since the beginning of civilization, there has been a thrust to better ourselves, to enhance our performance and capabilities. With nature as a template, a variety of sensors were created. As technology improved, artificial sensors have mostly surpassed their natural counterparts in sensitivity and size except in several specific areas, one being infrared sensing. The Melanophila acuminata, also known as the jewel beetle, is one of ...