Note: This list is non-exhaustive.

Athena Lab

Georgia Institute of Technology

The ATHENA group at Georgia Tech explores the advancing and development of novel technologies for electromagnetic, wireless, RF, mm-wave and sub-THz applications. Their research includes areas such as telecom, defense, space, automotive, health, smart skin, weather/climate and sensing areas and combines inkjet-printing, flexible paper/organic substrates, nanotechnology-based structures and green energy scavenging.

Website

Electromagnetics Research Group (Subgroup: TErahertz Systems Laboratory)

Michigan State University

Our research is motivated by the need for efficient and economical high-frequency (millimeter wave and terahertz) components, devices, sensors, and systems. The underlining
theme is the use of electromagnetics theory coupled with micro/nanofabrication to design and demonstrate high frequency circuits and sub-systems at the wafer level.

Website

3D Systems Packaging Research Center (PRC)

Georgia Institute of Technology

The Georgia Tech 3D Systems Packaging Research Center focuses on Smart, wearable, IOT, automotive, bio-electronics, and high-performance systems research. Leading-edge electronic systems research, cross-disciplinary education, and industry collaborations with 50+ global companies, make the PRC a leader in System-on-Package research.

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Electronic Packaging Laboratory

University of Buffalo
The Electronic Packaging Laboratory is an interdisciplinary research center of the University at Buffalo, The State University of New York. The purpose of this laboratory is to develop the computational and experimental tools needed to develop the next generation of nanoelectronics and nanophotonics devices. Conducting research for the next generation of nanoelectronics/ nanophotonics requires interdisciplinary collaboration between experts in solid mechanics, structural analysis, materials, electronics, circuits, photonics, heat transfer, fluid mechanics, manufacturing, and design. The EPL strives to educate competitive and self-motivated students and professionals with state-of-the-art knowledge in interdisciplinary research in a unique interdisciplinary environment.

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Microelectronics Laboratory

Lincoln Lab, MIT
The Microelectronics Laboratory is a state-of-the-art semiconductor research and fabrication facility that supports the design, fabrication, and packaging of novel devices.
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HYBRIDMEMS

Purdue University
Developments in MEMS fabrication technology over the past two decades have yielded new opportunities to design high quality factor (Q) micromechanical structures for ultra-low-power frequency-domain signal processing, sensing, and timing applications. Our goal is to harness the benefits of new and high-impact micromechanical devices and circuits for low-power, compact wireless communication, physical and chemical sensors, and timing applications. In the HybridMEMS Lab we invent new mechanical designs and efficient transducers to make MEMS resonators with high resonance frequency, low motional impedance, strong transducer coupling coefficient, low bias drift and wide programmable range. We further investigate coupling mechanisms between resonators to demonstrate channel-select filters and synchronized oscillator dynamics, and explore inter-domain coupling to design merged MEMS-CMOS and MEMS-HEMT devices. Our lab has also focused on the extension of these devices and systems into unreleased structures, eradicating the need for costly packaging, improving yield and robustness in harsh environments, and making MEMS resonators more accessible for a wide range of applications.

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Center for Electronic Manufacturing and Assembly (CEMA)

Rochester Institute of Technology
Through training, research and testing, CEMA prepares professionals to become successful within a global society. CEMA leverages this:

1.To be a Center of Excellence in understanding and supporting the needs of the electronics packaging industry.

2. To provide relevant services to our industry partners, engaged in semiconductor chip packaging, printed circuit board assemblies and electronics/optoelectronics systems.

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Packaging Research in Electronic Energy Systems(PREES)

NC State University
PREES brings together commercial, industrial and military interests in exploring newer approaches to physical definition, development and fabrication of electrical energy processing systems. Any physical realization of a power electronic system can be addressed in “Energy Systems Packaging.

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Bioelectronic and Electronic Laboratory

Florida International University
The objective is to develop next-generation bioelectronic packaging of wearable or implantable systems for health monitoring or restoring lost or damaged organ functions. This interdisciplinary research combines the advances in electronic system integration technologies with the improved understanding of neuromuscular and neurological disorders, and emerging surgical or therapeutic interventions to address them.
The primary research focus is to integrate electronic system functions into ultra-thin, flexible but reliable and biocompatible  implants. The functions range from power conversion, signal multiplexing, and target power delivery with spatial and temporal resolution, while also providing remateability with high-density electrode arrays. His research will address the fundamental challenges in realizing the seamless heterogeneous integration of electronic systems components with neural and tissue interfaces, by developing a new generation of 3D bioelectronic packaging technologies.
Website
Terahertz Electronics Laboratory

UCLA
This lab works on the development of novel high-performance terahertz sources, detectors, spectrometers, reconfigurable meta-films, imaging and spectroscopy systems that leverage photonic, plasmonic, and MEMS concepts, and  employs the developed terahertz device technologies for terahertz applications in material characterization, stand-off chemical detection, atmospheric studies, biological analysis and medical imaging.

Website

Applied Electromagnetics Group

University of California, San Diego
Research is focused on novel structures for controlling the interaction between electromagnetic waves and matter ranging from radio to optical frequencies. Periodic structures such as metasurfaces provide a medium for incorporating nonlinear or active circuit elements for applications such as antenna isolation, scattering control, improved absorption, and bandwidth enhancement for microwave structures. They can also enable extreme electric field enhancement for photoemission based microelectronic and plasmonic devices. Specific techniques include mathematics for arbitrary anisotropic impedance surface patterning, nonlinear or non-Foster based active materials, and nano-scale periodic structures for new optical effects. They also develop small broadband antennas, and new devices for biological applications of electromagnetics.

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The Nano Micro Electronics Laboratory

Kansas State University
The Nano Micro Electronics Laboratory is dedicated to advancing the state of the art of microfabrication and nanotechnology, with emphasis on new approaches to fabricate devices with characteristic lengths in the micro- to nanoscale from both silicon and non-silicon materials; and demonstrating these devices in multiple application spaces ranging from nano/micro power-electronics to energy storage, conversion, harvesting, RF-microwave and biomedical devices.

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HELIOS

Ohio State university
The Hyperspectral Engine Lab for Integrated Optical Systems (HELIOS) Laboratory is solely focused on exploring the uncharted THz spectrum by acquiring equipment and engaging several companies and government agencies in collaborative projects.
Website

Bioelectronic and Electronic Laboratory

Florida International University
The objective is to develop next-generation bioelectronic packaging  of wearable or implantable systems for health monitoring or restoring lost or damaged organ functions. This interdisciplinary research combines the advances in electronic system integration technologies with the improved understanding of neuromuscular and neurological disorders, and emerging surgical or therapeutic interventions to address them.
The primary research focus is to integrate electronic system functions into ultra-thin, flexible but reliable and biocompatible  implants. The functions range from power conversion, signal multiplexing, and target power delivery with spatial and temporal resolution, while also providing remateability with high-density electrode arrays. His research will address the fundamental challenges in realizing the seamless heterogeneous integration of electronic systems components with neural and tissue interfaces, by developing a new generation of 3D bioelectronic packaging technologies.
Website

Terahertz Electronics Laboratory

University of California, Los Angeles

This lab works on the development of novel high-performance terahertz sources, detectors, spectrometers, reconfigurable meta-films, imaging and spectroscopy systems that leverage photonic, plasmonic, and MEMS concepts, and employs the developed terahertz device technologies for terahertz applications in material characterization, stand-off chemical detection, atmospheric studies, biological analysis, and medical imaging.
Website

The Radio Frequency (RF) Photonics Lab

University of Massachusetts, Dartmouth)

The Radio Frequency (RF) Photonics Group conducts pioneering research to advance technologies covering electromagnetic spectrum from radio to optical frequencies. Our focus is on integrated microwave / photonic microsystems for high performance radar and electronic sensing.
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Photonics and Terahertz Group

Georgia Institute of Technology
The research group, led by Dr. Alexandre Locquet and Prof. David. S. Citrin, is part of the lab “Unité Mixte Internationale (UMI) 2958 Georgia Tech-CNRS”, an international collaboration between the Centre National de la Recherche Scientifique and the Georgia Institute of Technology. The lab is located at Georgia Tech Lorraine, Metz, France, which is the European campus of the Georgia Institute of Technology. The research activities encompass photonic information processing (from fundamentals of laser nonlinear dynamics to applications) as well as, terahertz imaging and spectroscopy for non-destructive evaluation.
Website

INSYST Integrated Nanosystems Research Lab

Florida International University
This Lab focuses on Terahertz (THz) Devices and Applications,Nanoscale Materials and Devices for Sensing and Detection,Free Space Optical (FSO) and Visible Light Communication (VLC),Plasmonic Structures for Bio/chemical Sensing and Communication,Novel Materials for Sensing and Communication.

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Computational Electromagnetics and Antennas Research Lab(Penn state university)
The lab is engaged in exciting and innovative research in the areas of computational electromagnetics and optics, antenna theory and design, phased array antenna systems (including ultra-wideband arrays and reconfigurable beam-scanning metamaterial lenses), microwave devices, wireless and personal communication systems (including body area networks and associated on-body/off-body propagation modes), wearable and e-textile antennas, RFID tag antennas, conformal antennas, tunable and reconfigurable antennas, frequency selective surfaces, electromagnetic wave interactions with complex media, metamaterials and metasurfaces (including novel RF/optical coatings, near-perfect super-octave absorbers, electromagnetic band gap structures, negative-, zero-, low- and high-index materials), transformation optics, nanoscale electromagnetics (including nanoantennas, quasicrystals, and a variety of other photonic and plasmonic devices), and bio-inspired electromagnetic/optical design. They are also actively involved in fundamental investigations at the cutting-edge between mathematics and electromagnetics in such areas as Fibonacci numbers, fractal geometry, knot theory, and aperiodic tiling theory. The lab is internationally recognized for its pioneering work in the development and application of nature-inspired optimization techniques (e.g. genetic algorithms, clonal selection algorithms, particle swarm, wind driven optimization, and various other evolutionary programming schemes) to solve complex electromagnetic/optical design problems.
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Antenna Research Group

University of Colorado Boulder
ARG’s research specializes in antenna theory and design with emphasis on applications of electrically small antennas (ESAs), simultaneous transmit and receive (STAR), wideband microwave and millimeter wave communication and electronic warfare front-ends.
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RF Power and Analog Laboratory

University of Colorado Boulder
The RFPAL investigates challenges in RF and microwave active circuit design, including making RF front-ends and related components more energy efficient through RF and analog circuit design
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INTEGRATED ELECTROMAGNETICS CIRCUITS AND SYSTEMS LAB (IECS)

University of Virginia
Current research interests include design of energy-efficient integrated circuits for IoT, RF photonics, holistic integration of high-frequency analog circuits, advanced digital circuits, and novel electromagnetic structures to enable the next generation of microwave and mm-wave applications, including adaptive mm-wave circuits as well as mm-wave power generation and radiation.
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