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

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.”
  • 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.
  • 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.
  • 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.
  • 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.”

Research


  • Effective manipulation of fluids at the micro/nanometer scale is of great interest in fluid dynamics, biological processes, and material synthesis. Microfluidics together with nanofabrication provides a fine control of fluid transport and interfacial dynamics, and therefore offers a wealth of ways to harness the processes of multiphase flow at the microscale. Our group takes microfluidics and nanofabrication as the main technical...

  • The research and fabrication of nanomaterials promises to revolutionize a number of industries and scientific fields, particularly biomedical devices and stem cell engineering. A major barrier to significant adoption and incorporation of novel nanomaterials is the need to produce these materials in high volume and at low-cost. We research the fabrication of ultrathin nanomembranes and the methods to produce these materials more simply, while...

  • The group’s research activities focus on enhancing the performance of energy conversion, transmission, and storage devices through the use of nanomaterials.  Current interests include the development of high capacity anode and cathode active materials for lithium ion batteries as well as engineering novel device architectures using carbon nanotubes (CNTs).  A second research area focuses on fabricating and improving the electrical...

  • 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...

  • The group’s research is centered around fluorescence spectroscopy of 21st century materials. These materials include conjugated polymers and carbon nanotubes for use in polymer photovoltaics, as well as biological probes. Using fluorescence, we can characterize new materials, study energy transfer and measure excited state kinetics. Through collaborations with RIT's nanopower Research Laboratory we also have access to nanoimaging techniques...