Andrew Kerman

Massachusetts Institute of Technology

H-index: 43

North America-United States

About Andrew Kerman

Andrew Kerman, With an exceptional h-index of 43 and a recent h-index of 30 (since 2020), a distinguished researcher at Massachusetts Institute of Technology, specializes in the field of Condensed-matter, atomic, and optical physics, superconductivity and superconducting electronics, quantum information.

His recent articles reflect a diverse array of research interests and contributions to the field:

Novel charging effects in the fluxonium qubit

Quantum dynamics of superconductor-quantum dot-superconductor (super-semi) Josephson junctions

Superconducting-semiconducting voltage-tunable qubits in the third dimension

Qubit circuits with deep, in-substrate components

Implementation of a Josephson Phase Slip Qubit

A 3-tier stack for 3D integration of superconducting quantum systems-part 2: qubit design and performance

Gatemon qubits with superconductor-semiconductor-superconductor junctions: transition from high transparency to low transparency

Demonstration of tunable three-body interactions between superconducting qubits

Andrew Kerman Information

University	Massachusetts Institute of Technology
Position	MIT Lincoln Laboratory
Citations(all)	9961
Citations(since 2020)	3199
Cited By	8239
hIndex(all)	43
hIndex(since 2020)	30
i10Index(all)	67
i10Index(since 2020)	54
Email	Access Email
University Profile Page	Massachusetts Institute of Technology
Google Scholar	View Google Scholar Profile

Andrew Kerman Skills & Research Interests

Condensed-matter

atomic

and optical physics

superconductivity and superconducting electronics

quantum information

Andrew Kerman

Massachusetts Institute of Technology

About Andrew Kerman

Andrew Kerman Information

Andrew Kerman Skills & Research Interests

Top articles of Andrew Kerman

Novel charging effects in the fluxonium qubit

Kyle Serniak

Andrew Kerman

Quantum dynamics of superconductor-quantum dot-superconductor (super-semi) Josephson junctions

Utkan Güngördü

Andrew Kerman

Kyle Serniak

Silas Hoffman

Superconducting-semiconducting voltage-tunable qubits in the third dimension

Kyle Serniak

Qubit circuits with deep, in-substrate components

Implementation of a Josephson Phase Slip Qubit

Steven Weber

David Kim

Andrew Kerman

A 3-tier stack for 3D integration of superconducting quantum systems-part 2: qubit design and performance

David Kim

Ravi Rastogi

Kyle Serniak

Steven Weber

Andrew Kerman

Mollie Schwartz

Gatemon qubits with superconductor-semiconductor-superconductor junctions: transition from high transparency to low transparency

Utkan Güngördü

Andrew Kerman

Kyle Serniak

Silas Hoffman

Demonstration of tunable three-body interactions between superconducting qubits

Tim Menke

Antti Vepsäläinen

Roni Winik

Kyle Serniak

Simon Gustavsson

Distinguishing Multispin Interactions from Lower-Order Effects

Tim Menke

Demonstration of long-range correlations via susceptibility measurements in a one-dimensional superconducting Josephson spin chain

Xi Dai

Rui Yang

Evgeny Mozgunov

Adrian Lupascu

Dissipative, Photon-Assisted Quantum Annealing

Engineering multi-qubit interactions between superconducting flux qubits

Tim Menke

Steven Weber

Roni Winik

David Kim

Mollie Schwartz

Kyle Serniak

Simon Gustavsson

Andrew Kerman

Multi-spin chain gadget with exponentially small gap controlled by a single spin

Xi Dai

Rui Yang

David Kim

Steven Weber

Andrew Kerman

Sergey Novikov

Evgeny Mozgunov

Daniel Lidar

Tameem Albash

Adrian Lupascu

Coherent oscillations in diabatic quantum annealing schedules

Xi Dai

Rui Yang

David Kim

Steven Weber

Andrew Kerman

Sergey Novikov

Tameem Albash

Evgeny Mozgunov

Daniel Lidar

Adrian Lupascu

High-density I/O for next-generation quantum annealing: Part 1-Cryogenic wiring

Steven Weber