Birck Nanotechnology Center is home to 300 resident students, faculty and staff who have access to all shared labs. The 186,000 sq ft. facility includes a 25,000 sq. ft. ISO Class 3-4-5-6 (Class 1-10-100-1000) nanofabrication cleanroom – the Scifres Nanofabrication Laboratory – that includes a 2,500 sq. ft. ISO Class 6 (Class 1000) pharmaceutical-grade biomolecular cleanroom. Researchers from six academic colleges are at the forefront of nano electronics, photonics, energy, micro electromechanical systems, nanobio technology and nanomanufacturing and are helping to develop a local high tech ecosystem in collaboration with Discovery Park District and Wabash Heartland Innovation Network (WHIN) community internet of things (IoT) testbeds. 

2-Dimensional Hexagonal Boron Nitride on Silicon

by Oksana Makarova

DNA-like material could bring even smaller transistors

February 11, 2020

WEST LAFAYETTE, Ind. — Computer chips use billions of tiny switches, called transistors, to process information. The...

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PQSEI Seminar: Gerardo Ortiz

February 17, 2020

Physics and Computation (with Nuclear Spins)

Bio: After receiving his Ph.D. in Theoretical Physics at the Swiss Federal Institute of Technology, Gerardo Ortiz continued his career in the US, first, as a postdoctoral fellow at the University of Illinois at Urbana-Champaign, and then as an Oppenheimer fellow at the Los Alamos National Laboratory where he stayed as a permanent staff member until 2006. He is currently working in the Department of Physics at Indiana University, Bloomington. His scientific career has spanned a large variety of topics in condensed matter physics and quantum information science, including electron fluids and solids, topological quantum matter, high-temperature superconductivity, quantum critical phenomena, cold atom physics, and entangled-quantum probes of matter, among others.

Abstract: There is a deep connection between Physics and Computation. Indeed, any computation can be represented as a physical process. In 1981 Richard Feynman raised some provocative questions in connection to the simulation of physical phenomena using a special device called a "Quantum Computer". Such a device was intended to mimic physical processes exactly the same as Nature, and thus shared those "spooky" features of quantum physics. Remarks coming from such an influential figure generated widespread interest in these ideas, and today, more than three decades after, there are still open questions. What kind of physical phenomena can be efficiently mimicked?, How?, and What are its limitations? I will address these questions in the broader context of what is currently known as quantum information science. I will show quantum simulations in a liquid NMR quantum computer of Fano-Anderson resonant impurity scattering and Aharonov- Bohm effect with anyons.

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