Rakesh Agrawal is the Winthrop E. Stone Distinguished Professor in the Davidson School of Chemical Engineering at Purdue University. He received a B. Tech. from the Indian Institute of Technology, Kanpur, an M.Ch.E. from the University of Delaware and an Sc.D. in chemical engineering from MIT.
Dr. Agrawal's research includes novel processes for the fabrication of low-cost thin-film solar cells, energy systems analysis, biomass to liquid fuel conversion, synthesis of efficient multicomponent separation processes using distillation, membranes and adsorption, and basic and applied research in gas separations and liquefaction. Agrawal has published 207 technical papers and has given over 250 invited lectures. He holds 126 U.S. and more than 500 foreign patents. These patents are used in over one hundred chemical plants with total capital expenditure in multibillion dollars. He has served on technology and engineering advisory boards of a number of companies.
Agrawal has received dozens of awards and honors, including Purdue’s Shreve Award for teaching excellence and the Morrill Award for excellence in research, teaching and service. From the AIChE he has received Gerhold award in separations, the Institute Award for Excellence in Industrial Gases Technology, the Chemical Engineering Practice Award, Alpha Chi Sigma and the Founders Award. He received Award in Separations Science and Technology from the ACS. He delivered Peter V. Danckwerts Lecture at the 10th World Congress of Chemical Engineering.
He is a member of the U.S. National Academy of Engineering, a Fellow of the American Academy of Arts and Sciences, a Fellow of the US National Academy of Inventors and a Fellow of the Indian National Academy of Engineering. Agrawal received the National Medal of Technology and Innovation from President Obama in 2011.
Fossil resources have played an unprecedented role in human history. The availability of fossil energy in high volumetric density has propelled human civilization at an unprecedented rate for more than two centuries. However, in spite of recent surge in fossil resource availability, with the ever increasing rate of energy demand, it is certain that we will eventually need a sustainable source of energy. The solar energy is one such source, it is plentiful, and its use can meet our daily needs for food, chemicals, heat, electricity and transportation for any foreseeable future.
The challenge with the transition from a fossil resource based economy to a solar economy is that we have to learn to harness, transform and store solar energy at the time scale of our use pattern. This has been a problem due to dilute intensity of solar irradiation and its intermittent availability. Thus the methods to collect and transform solar energy have to be both efficient and low-cost for wide spread use. In this presentation, we will discuss these challenges and our interdisciplinary approach for finding potential solutions. We will present sustainable solutions for transportation, production of fuels and chemicals, large scale storage and around the clock power generation. We will make a case for local photons to meet local needs through photovoltaic aglectric farming to enable a ‘full earth’ scenario. Finally, we will briefly discuss our research on low-cost solution processed inorganic solar cells.
Indeed, we are living in an exciting time as we continue to debate and prepare for the eventual transition from a fossil based economy to a sustainable economy based on solar energy. The goal of this presentation is to share some of this excitement from my own experiences.