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Professor John A. Rogers obtained BA and BS degrees in chemistry and in physics from the University of Texas, Austin, in 1989. From MIT, he received SM degrees in physics and in chemistry in 1992 and the PhD degree in physical chemistry in 1995.
Bio-Integrated Electronics, Optoelectronics, Microfluidics and MEMS. In this project, we are developing collections of ideas in materials science and device design to create biocompatible classes of microsystems technologies, with uses in biological research and clinical medicine.
Rogers Group. Our group consists of a diverse mix of students and postdocs, including people from chemistry, physics, electrical engineering, mechanical engineering, materials science and chemical engineering.
J.R. Walter, S. Xu, J. Stringer and J.A. Rogers, "The Future of Remote Monitoring for Pregnancy," The Bridge 52(1), 16-25 (2022). Y. Yin and J.A. Rogers, "Introduction: Smart Materials," Chemical Reviews 122, 4885-4886 (2022).
Y. Park, T. Chung and J.A. Rogers, "Three Dimensional Bioelectronic Interfaces to Small-Scale Biological Systems," Current Opinion in Biotechnology 72, 1-7 (2021). J.A. Rogers, "Integrated Nanoelectronic-Photonic Devices and Bioresorbable Materials," Nano Research 14(9), 2885-2887 (2021).
John A. Rogers Northwestern University and Querrey/Simpson Institute for Bioelectronics McCormick School of Engineering, Weinberg College of Arts and Sciences and Feinberg School of Medicine 2145 Sheridan Road, Evanston, IL 60208; 847-467-2997 jrogers@northwestern.edu Education: Harvard University
Z. Liu, J.-T. Kim, J.A. Rogers, R.L. Klatzky and J.E. Colgate, “Realism of Tactile Texture Playback: A Combination of Stretch and Vibration,” IEEE Transactions on Haptics 17(3), 441-450 (2024).
Kim, A. Banks, Y. Huang and J.A. Rogers, “A Battery-less Wireless Implant for the Continuous Monitoring of Vascular Pressure, Flow Rate and Temperature,” Nature Biomedical Engineering 7, 1215-1228 (2023).
John A. Rogers, Thanh Nho Do, Nam-Trung Nguyen, Hangbo Zhao,* and Hoang-Phuong Phan* Wide bandgap (WBG) semiconductors have attracted significant research interest for the development of a broad range of flexible electronic appli-cations, including wearable sensors, soft logical circuits, and long-term implanted neuromodulators.
Q. Zhang, Q. Liang and J.A. Rogers, "Water-soluble Energy Harvester as a Promising Power Solution for Temporary Electronic Implants," APL Materials 8, 120701 (2020).
