Supriyo Datta

Supriyo Datta (born February 2, 1954) is an Indian–American researcher and author. A leading figure in the modeling and understanding of nano-scale electronic conduction, he has been called "one of the most original thinkers in the field of nanoscale electronics."

As an author, his books and online courses are widely used as original research and design work in the field of nanotechnology and electronic devices. He is known for the development of the spin transistor, the non-equilbrium Green's function method for quantum transport and negative capacitances.

Biography
Supriyo Datta was born in Dibrugarh, India in 1954.

Datta received his B.Tech from the Indian Institute of Technology (IIT) in Kharagpur, India in 1975. He then received both his MS and PhD from the University of Illinois Urbana–Champaign in 1977 and 1979, respectively. His PhD thesis was titled Theory of guided acoustic waves in piezoelectric solids.

In 1981, he joined Purdue University, where he is (since 1999) the Thomas Duncan Distinguished Professor in the School of Electrical Engineering. He was also director of the NASA Institute for Nanoelectronics and Computing until 2007.

Research
Before 1985, he worked in the field of surface acoustics. Since 1985 he has focused on nanoscale electronic devices and has contributed through his foundational work on quantum transport, spintronics and negative capacitance electronics. He has also worked on probabilistic p-bits.

Quantum transport
In a series of papers between 1985 and 1995 his group demonstrated how the non-equilibrium Green's function (NEGF) formalism used by many-body physicists for uniform conductors could be extended to model electronic devices which are non-uniform and have contacts. He made this work broadly accessible through his book Electronic Transport in Mesoscopic Physics.

Between 1995 and 2005 his group combined his earlier NEGF approach with an atomistic Hamiltonian, to establish a conceptual and computational framework that is used by quantum chemists in molecular electronics, and is also the basis for modern quantum transport simulation tools routinely used in the semiconductor industry.

Between 2005 and 2015 his group developed approaches for analyzing spin-based devices and circuits that incorporate them.

Spintronics
In 1990 he proposed the spin transistor, using spin-orbit coupling to control electron spin with an electric field rather than a magnetic field. This was experimentally demonstrated in 1997 and is widely used in the field of spintronics. This "proposal planted the idea that spin could be used in its own right as a means to carry and manipulate information — and gave birth to the new field of spintronics."

Negative capacitance electronics
In 2008, along with Sayeef Salahuddin he proposed the concept of negative capacitance devices, which is now considered a prime candidate for reducing dissipation and extending Moore's law.

Honours and awards
Datta received the President of India Gold Medal at graduation from IIT Kharagpur in 1975.

He received the Frederick Emmons Terman Award from the American Society of Engineering Education in 1994 for his book on surface acoustics, and the Presidential Young Investigator Award from the National Science Foundation, 1984.

He is included in Purdue's Book of Great Teachers and won the 2006 Herbert Newby McCoy Award, the 2018 Seed for Award and the 2020 Morrill Award given by Purdue University.

In 1996, he became both Fellow of the American Physical Society (APS) as well as of the Institute of Electrical and Electronics Engineers (IEEE). He has received various IEEE awards including: the 1985 IEEE Centennial Key to the Future, the 2002 IEEE Cledo Brunetti Award, and the 2008 IEEE Leon Kirchmayer Award.

In 2011 he received the William Procter Prize for Scientific Achievement.

In 2012 he was elected as a member into the National Academy of Engineering (NAE) for quantum transport modeling in nanoscale electronic devices.

Online Lectures

 * youtube A Different Perspective on NEGF
 * nanoHUB A Different Perspective on NEGF

Online Courses

 * Purdue-X course Fundamentals of Current Flow
 * Purdue-X course Introduction to Quantum Transport
 * Purdue-X course Boltzmann Law: Physics to Computing
 * nanoHUB-U course Fundamentals of Current Flow
 * nanoHUB-U course Introduction to Quantum Transport
 * nanoHUB-U course Boltzmann Law: Physics to Computing