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  • Micro-Device Research
    Implantable Micro-Device Research Could Lead To New Therapies To Treat Hearing Loss
  • Advancing Tissue Engineering
    Research by RIT Professor Points to Improvements in Tissue Engineering
  • Microscale Heat Transfer
    Satish Kandlikar: Reduced in Heat in Electronic Devices
  • Truly Unique
    RIT's Semiconductor and Microsystems Fabrication Laboratory
  • Nanocomputing
    Brain Power
  • Truly Unique
    Micro-Device Research
  • Plasmonic Electronics
    Exploring a Plasmonic Alternative
  • Micro-Device Research
    Photonics Light The Way of Microprocessors
  • Stellar Students
    Advancing Lithium Ion Battery Technology
  • Cutting Edge Research
    MOVPE Equipment Changes Everything in Semiconductor Processing
  • Renewable Energy
    Impacts on Climate Change

Microsystems Engineering builds on the fundamentals of traditional engineering and science and tackles technical challenges of small-scale nano-systems. Microsystems Engineers manipulate electrical, photonic, optical, mechanical, chemical, and biological systems on a nano-scale.

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Testimonials

  • Burak Baylav - PhD Graduate
    I had access to the latest technology, tools and data. It was a dream come true and I was able to use this relationship for my Ph.D. research.”
  • Anand Gopalan - PhD Graduate
    “While working toward my PhD in Microsystems at RIT, I was exposed to cutting edge technology with the opportunity to be part of industry supported research.”
  • Peng Xie - PhD Graduate
    I found my Microsystems experience prepared me well for the challenges of industry. During my Ph.D. program, I had taken a 1-year internship at IMEC as well as a 4 months internship at GlobalFoundries. These experiences helped me to better understand the workspace, expand my professional network and get a pulse of where the industry is heading. With my solid preparation at RIT, I am confident that I am ready to take on any challenges in the future.
  • Monica Kempsell Sears - PhD Graduate
    I’ve always wanted to be one of the people who figures out how to push this field further and further—and now I am.
  • Cory Cress - PhD Graduate
    During my time at RIT, I performed research in the NanoPower Research Labs. It was here that I learned how to create nanomaterials and devices. I learned how to understand them, and test their performance. Now, I use these skills at the US Naval Research Lab in Washington, DC. My work here has a massive impact on how electronics are created.

Research

  • Terahertz light is light in-between the microwave and mid-infrared region of the electromagnetic spectrum. Only over the last decade did terahertz technology mature to the point where we can know think about deploying this part of the electromagnetic spectrum for measurement and control purposes in industry. The Terahertz Materials Characterization Laboratory at RIT develops terahertz based material characterization techniques relevant to the...

  • Recently the Rochester Institute of Technology has demonstrated the co-integration of CMOS devices and resonant interband tunnel diodes (RITDs).  Our strategy has been to integrate the tunnel diodes following all high temperature steps, but prior to the contact metallization of the CMOS devices.  A recent paper in the Sept. 2003 issue of IEEE Transactions on Electron Devices co-written by our sister group at the Ohio State University found...

  • Our research group works on cryptographic engineering. In short, the research group is involved in the design, implementation, and optimization of crypto-systems in embedded hardware and software. In addition, the group actively works on emerging topics in side-channel analysis attacks and countermeasures. The research conducted in this group includes a number of abstraction levels, including hardware micro architecture and platform specific...

  • The conversion of light from the sun into electrical energy is playing a very important role in our current challenge for alternative energy technologies, to reduce our dependence on fossil fuels as well as reduce greenhouse gas emissions. The vision of Dr. Hubbard’s research group is to accelerate scientific breakthroughs in the discovery of materials and structures that will advance the frontier of the conversion of light to electricity....

  • In Biomedical Signal and Image Analysis (BSIA) Lab at Rochester Institute of Technology, our mission is understanding human physiology from an engineering perspective, developing algorithms that can benefit global health care, and training the next generation of scientists and engineers to develop and apply engineering principals in biomedicine. The research of interest includes application of non-stationary signal analysis and classification...