James Clarke: Intel: From a Grain of Sand to a Quantum Computer

Date and Time
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Photo of James Clarke

Zoom Details

Technical Seminar

2:00 pm - 3:00 pm

Zoom Link: For Zoom Information Please Contact: QF-admin@cnsi.ucsb.edu

Speaker

James S. Clarke

Director of Quantum Hardware

Intel Corporation

Bio

Jim Clarke is the director of the Quantum Hardware research group within Intel’s Components Research Organization. Jim launched Intel’s Quantum Computing effort in 2015, as well as a research partnership with QuTech (TU Delft and TNO). His group’s primary focus is to use Intel’s process expertise to develop scalable qubit arrays. In 2018, Jim worked with industry leaders and the Intel policy group to influence the U.S. National Quantum Initiative Act. Prior to his current role, Jim managed a group focused on interconnect research at advanced technology nodes as well as evaluating new materials and paradigms for interconnect performance. He has co-authored more than 100 papers and has over 50 patents. Prior to joining Intel in 2001, Jim completed a B.S. in chemistry at Indiana University, a Ph.D. in physical chemistry at Harvard University, and a post-doctoral fellowship in physical organic chemistry at ETH, Zürich. He is a member of IEEE.

Abstract

Today’s quantum processors are limited to 10’s of entangled quantum bits. If you believe the hype, a commercially relevant system is just around the corner that can outperform our largest supercomputers. The reality, however, is that we are still at mile 1 of a marathon. There are many unanswered fundamental questions. At Intel, our approach is to rely on the continued evolution of Moore’s Law to build qubit arrays with a high degree of process control.

Here, we present progress toward the realization of 300mm spin qubit devices in a production environment. This includes (i) isotopically purified 28Si epi substrates with a compelling substrate quality (ii) design of a custom qubit layout, (iii) integration of spin qubit devices using immersion lithography, moving from classical transistor structures to full spin qubits, and (iv) the realization of quantum dots in a nested gate design novel to a 300mm process line.

In addition, this talk will focus on two bottlenecks to moving beyond today’s few-qubit devices. The first bottleneck is in the interconnect design of the quantum circuit. Today’s qubits have personalities. Individual control of each qubit is required. A small quantum processor today has multiple RF and DC wires per qubit. This is a brute force approach to wiring and will not scale to the millions of qubits needed for large applications.

The second bottleneck relates to the speed of information turns in quantum development. Fabrication of spin qubits in a silicon substrate bare similar to conventional transistors from advanced CMOS technologies. One of the above 300mm wafers has over 10,000 individual quantum test structures. Naturally, R&D should be accelerated by the potential volume of statistical data. While automated electrical testing of a CMOS transistor wafer can be completed in less than an hour at room temperature, data collection at cryogenic temperatures is currently limited to a small number of devices with a turnaround of hours to days. Rhetorically speaking, “How can we deliver an exponentially fast compute technology with the slow and serial characterization of quantum chips?