Microelectromechanical systems (MEMS)
Microelectromechanical systems (MEMS) research combine microscale mechanical components with electronics to create devices that can sense, control, and actuate on a tiny scale. This interdisciplinary field plays a critical role within mechanical engineering, enabling innovations in sensors, actuators, and biomedical devices. Researchers and students exploring MEMS benefit from insights into its diverse applications and fundamental principles. JoVE Visualize enhances understanding by pairing PubMed research articles with JoVE’s experiment videos, offering a richer perspective on experimental techniques and discoveries in MEMS research.
Established approaches in MEMS research often include microfabrication techniques such as photolithography, etching, and thin-film deposition. These methods allow precise construction of microscale mechanical parts like beams, sensors, and actuators. Characterization tools, including scanning electron microscopy and atomic force microscopy, are widely used to analyze device structures and performance. Fundamental research also frequently involves simulations of mechanical behavior and fluid interactions to optimize sensor and actuator designs. These well-established methods form the backbone of MEMS development and are crucial for replicating and advancing existing technologies.
Recent advances in MEMS focus on integrating novel materials, such as graphene and piezoelectric films, to enhance device functionality and sensitivity. Techniques combining additive manufacturing with traditional microfabrication are gaining attention for producing more complex or customized MEMS devices. Additionally, research into multi-physics modeling and in situ testing is expanding the understanding of MEMS performance under varied conditions. There is a growing interest in bio-integrated MEMS for healthcare applications, leveraging microfluidics and flexible electronics. These emerging trends reflect the dynamic evolution of MEMS research, broadening its applications and pushing technological boundaries.
Hannah Weiss, Roee Ber, Mason Blacker, Nora Kim, Cordelia Orillac, Clotilde Balucani, Paul P Huang
Toyohiro Katsumata, Yusuke Nakagawa, Ryu Yoshida, Junpei Matsuda, Tomomasa Nakamura, Kazumasa Miyatake, Hiroki Katagiri, Ryota Seki, Yasumasa Tokumoto, Rena Hagiwara, Ichiro Sekiya, Kunikazu Tsuji, Hideyuki Koga
Laura Beghini, Brunnhilde M A-S Ponsi, Kamilla Refsholt, Annelen Dogger Schmidt, Virginie Callot, S Johanna Vannesjo
Donyoung Kang, Byeongseok Ryu, Sujeong Ahn, Junhyub Kim, Myeonghun Jang, Jeong Ho Cho, Won-Gun Koh, Hyungsuk Lee
Xin Jin, Yutao Li, Kelian Gaedecke, Xiaoqi Zhang, Berend Smit
Taisuke Imamura, Koichi Tomita, Paula Marincola Smith, Maho Takayama, Anneliese Hierl, Xin Shelley Wang, Loretta A Williams, Kyle G Mitchell, Ravi Rajaram, David Rice, Wayne Hofstetter, Mara B Antonoff, Reza Mehran, Ara Vaporciyan, Garrett Walsh, Jessica E Maxwell, Rebecca A Snyder, Michael P Kim, Ching-Wei D Tzeng, Paul Mansfield, Stephen Swisher, Jeffrey E Lee, Brian D Badgwell, Matthew H G Katz, Naruhiko Ikoma
Zhen Li, Xenia Gurjanov, Alexander Lemberg, Palina Sinitsa, Alexander T Sack, Felix Duecker
Sai Chandan Reddy, S Farzad Maroufi, James Feghali, A Karim Ahmed, Nicole Page, Omar Selim, Melissa Canales, Shaan Bhandarkar, Patrick Kramer, Deepa Galaiya, Bryan Ward, Charles Della Santina, C Matthew Stewart, Francis Creighton, John Carey, Jason C Nellis, Kofi O Boahene, Michael Lim, Risheng Xu, Justin M Caplan, Chetan Bettegowda, Jon Weingart, Henry Brem, Rafael J Tamargo, Christopher M Jackson