Abstract: The current era of computing is driven by mostly general-purpose computing architectures with some specialization. With the increasing use of artificial intelligence/machine learning (ML) applications in manufacturing, natural language processing, scientific applications with increasing requirements such as weather prediction and protein folding, and even in Level 3 & 4 driverless cars, our reliance on computing for enabling these applications is also rapidly increasing. In this presentation, based on examining several trends in computing including energy, complexity of applications, algorithms, and manufacturing, we observe that the current trends are unsustainable. We will try to address the following questions: What can be done to address this increasing appetite for computing which needs increasing amounts of resources to operate? How do we reconcile the much-touted advent of Artificial General Intelligence (AGI) with these current trends? We will conclude the talk with a proposal of a modified form of Turing’s test that points to a new conceptualization of computing for existing and new applications. 

Bio: Sadasivan (Sadas) Shankar is Research Technology Manager at SLAC National Laboratory, adjunct Professor in Stanford Materials Science and Engineering, and Lecturer in the Stanford Graduate School of Business. He was an Associate in the Department of Physics at Harvard University, and was the first Margaret and Will Hearst Visiting Lecturer in Harvard and the first Distinguished Scientist in Residence at the Harvard Institute of Applied Computational Sciences. He has co-instructed classes related to design of materials, computing, sustainability in materials, and has received Excellence in Teaching award from Harvard University. He is co-instructing a class at Stanford University on Translation for Innovations. He is a co-founder of and the Chief Scientist at Material Alchemy, a “last mile” translational and independent venture that has been recently founded to accelerate the path from materials discovery to adoption, with environmental sustainability as a key goal. In addition to research on fundamentals of Materials Design, his current research is on new architectures for specialized AI methods is exploring ways of bringing machine intelligence to system-level challenges in inorganic/biochemistry, materials, and physics and new frameworks for computing inspired by lessons from nature. Dr. Shankar’s current research and analysis on Sustainable Computing is helping provide directions for the US Department of Energy’s EES2 scaling initiatives (energy reduction in computing every generation for 1000X reduction in 2 decades) as part of the White House Plan to Revitalize American Manufacturing and Secure Critical Supply Chains in 2022 for investment in research, development, demonstration, and commercial application (RDD&CA) in conventional semiconductors. In addition, his analysis is helping identify pathways for energy efficiency across all layers. While in the industry, Dr. Shankar and his team have enabled several critical technology decisions in the semiconductor industrial applications of chemistry, materials, processing, packaging, manufacturing, and design rules for over nine generations of Moore’s law including first advanced process control application in 300 mm wafer technology; introduction of flip-chip packaging using electrodeposition, 100% Pb-elimination in microprocessors, design of new materials, devices including nano warp-around devices for the advanced semiconductor technology manufacturing, processing methods, reactors, etc. Dr. Shankar managed his team members distributed across multiple sites in the US, with collaborations in Europe. The teams won several awards from the Executive Management and technology organizations. He is a co-inventor in over twenty patent filings covering areas in new chemical reactor designs, semiconductor processes, bulk and nano materials for the sub 10 nanometer generation of transistors, device structures, algorithms and biomarkers for ME/CFS and Long Covid. He is also a co-author in over hundred publications and presentations in measurements, multi-scale and multi-physics methods spanning from quantum scale to macroscopic scales, in the areas of chemical synthesis, plasma chemistry and processing, non-equilibrium electronic, ionic, and atomic transport, energy efficiency of information processing, and machine learning methods for bridging across scales, and estimating complex materials properties and in advanced process control.

Speaker Bio: Sadasivan (Sadas) Shankar's Profile | Stanford Profiles