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From page 188... ... in the quantum computing space. Their collaboration seeks to improve algorithms for using near-term quantum computers within the framework of variational quantum eigensolver (VQE) Read the entire page →
From page 189... ... focus on simulating quantum chemistry on quantum computers in a seniority-zero subspace, which is a subspace of the complete active space where all configurations involve paired electrons. This is advantageous for quantum computing because the pairs of electrons can be treated bosonically, thus alleviating the requirement that fermionic antisymmetry is imposed (reducing circuit size) Read the entire page →
From page 190... ... Whether quantum computing will ever impact industrially relevant chemistry problems without quantum error correction remains speculative. However, if an error-corrected quantum computer is built, then there are some known examples of industrial problems that could be solved with a quantum advantage over classical computers. Read the entire page →
From page 191... ... Recommendation 5-3. Efforts should be made to lower the current barriers to entry that limit mem bers of the chemistry research community from entering quantum information science (QIS) Read the entire page →
From page 192... ... 2021. "Simulating Quantum Chemistry in the Seniority-Zero Space on Qubit-Based Quantum Computers." Physical Review A 103(3) Read the entire page →
From page 193... ... 2022. "Efficient Quantum Computation of Molecular Forces and Other Energy Gradients." Physical Review Research 4(4) Read the entire page →
From page 194... ... 2020. "Increasing the Representation Accu racy of Quantum Simulations of Chemistry Without Extra Quantum Resources." Physical Review X 10(1) Read the entire page →
From page 195... ... He works in spintronics and quantum information engineering, studying the quantum states of electrons, nuclei, and photons in semiconductors and molecules for quantum information processing. Awschalom received the American Physical Society Oliver Buckley Prize and Julius Edgar Lilienfeld Prize, the European Physical Society Europhysics Prize, the Materials Research Society David Turnbull Award and Outstanding Investigator Prize, the American Association for the Advancement of Science Newcomb Cleveland Prize, the International Magnetism Prize from the International Union of Pure and Applied Physics, and an IBM Outstanding Innovation Award. Read the entire page →
From page 196... ... Her primary expertise is at the interface of organic chemistry, inorganic chemistry, spin-based materials, and photochemistry/electron transfer theory, which allows her to be well situated to address current challenges in molecular quantum information science: the design of molecular qubits with long decoherence times, multiqubit arrays, and qubits/qudits that can respond to external stimuli for quantum computing and sensing. Frank currently serves on two funded Department of Energy, Energy Frontiers Research Center advisory boards in quantum science and on the American Chemical Society-Petroleum Research Fund Advisory Board, and has served on numerous National Science Foundation funding panels in quantum relevant areas. Read the entire page →
From page 197... ... Her work uses first-principles calculations and phenomenological models to describe and predict novel and enhanced phenomena in quantum materials. Applications of her work range from next-generation quantum sensors for dark matter detection and coherence enhancement in materials for quantum information science, to predicting new forms of topological and multiorder quantum matter. Read the entire page →
From page 198... ... His research has resulted in more than 730 publications and focuses on light-driven processes in molecules and materials, artificial photosynthesis, molecular electronics, quantum information science, ultrafast optical spectroscopy, and time-resolved electron paramagnetic resonance spectroscopy. His honors and awards include membership in the National Academy of Sciences and the American Academy of Arts & Sciences; the Bruker Prize in Electron Paramagnetic Spectroscopy (EPR) Read the entire page →
From page 199... ... Appendix B Agendas for Information-Gathering Meetings 1–3 Information-Gathering Meeting 1 March 11, 2022, 2:15–5:30 pm EST 2:15 Welcome and Introductions Theodore Goodson, Committee Chair The Richard Bernstein Collegiate Professor of Chemistry University of Michigan Session I History and Outlook on Scalability 2:20 Opportunities for Chemistry in Quantum Information Science David Awschalom Liew Family Professor University of Chicago QIS Group Leader, Materials Science Division Argonne National Laboratory 2:50 Q&A with Committee Moderated by Brenda Rubenstein Joukowsky Family Assistant Professor of Chemistry Brown University 3:05 Molecular Systems for Quantum Information Science Michael Wasielewski Clare Hamilton Hall Professor of Chemistry Northwestern University 199 Read the entire page →
From page 200... ... G Keyes Professor of Chemistry Massachusetts Institute of Technology 4:35 Quantum Simulations and Quantum Information: A Key Feedback Loop Giulia Galli Liew Family Professor of Electronic Structure and Simulations University of Chicago 4:50 Q&A with Committee Moderated by Ryan Babbush Head of Quantum Algorithms Staff Research Scientist Google, LLC 5:05 Closing Remarks Theodore Goodson, Committee Chair The Richard Bernstein Collegiate Professor of Chemistry University of Michigan 5:10 Adjourn Open Session Information-Gathering Meeting 2 June 10, 2022, 2:15–6:00 pm EST 2:15 Welcome and Introductions Theodore Goodson, Committee Chair The Richard Bernstein Collegiate Professor of Chemistry University of Michigan Read the entire page →
From page 201... ... Biological Applications and Computational Applications for Quantum Information Science 4:00 Introduction Theodore Goodson, Committee Chair The Richard Bernstein Collegiate Professor of Chemistry University of Michigan 4:05 Chemical Design Principles for Controlling Quantum Dynamics in Complex Environments: Quantum IN Biology and Quantum FOR Biology Greg Engel Professor of Chemistry and Molecular Engineering University of Chicago 4:20 Q&A with Committee Moderated by Eric Schelter Professor of Chemistry University of Pennsylvania 4:35 Chemical Approaches to Quantum Information Science Danna Freedman F Read the entire page →
From page 202... ... Quantum Workforce Development 2:20 Pursuing Quantum Information Science Together Charles Tahan Assistant Director for Quantum Information Science Director of National Quantum Coordination Office Office of Science and Technology and Policy 2:35 Q&A with Committee Moderated by Theodore Goodson The Richard Bernstein Collegiate Professor of Chemistry University of Michigan 2:50 QIS-Chemistry and Education: Barriers to Entry from an Academic Perspective Rigoberto Hernandez Director of the Open Chemistry Collaborative in Diversity Equity Gompf Family Professor of Chemistry Department of Chemistry John Hopkins University Read the entire page →
From page 203... ... APPENDIX B 203 3:05 Q&A with Committee Moderated by Marilu Perez Garcia Scientist II Critical Materials Institute Iowa State University Ames Laboratory 3:20 Economic Development and Barriers to Entry at the Interface of Chemistry and QIS Joseph Broz Vice President Quantum Growth and Markets IBM in Yorktown 3:35 Q&A with Committee Moderated by David Awschalom Liew Family Professor in Spintronics and Quantum Information Pritzker School of Molecular Engineering The University of Chicago 3:50 Break Session II. Economic Development in QIS & Chemistry 4:00 Introduction Theodore Goodson, Committee Chair The Richard Bernstein Collegiate Professor of Chemistry University of Michigan 4:05 Theoretical Chemistry to Enhance Quantum Information Science: Education, Funding, Research Keeper Sharkey Founder and CEO ODE 4:20 Q&A with Committee Moderated by Theodore Goodson The Richard Bernstein Collegiate Professor of Chemistry University of Michigan 4:35 Disrupting Computational Chemistry with Quantum Computing Hongbin Liu Quantum Solution Lead Microsoft Quantum 4:50 Q&A with Committee Moderated by Michael Wasielewski Clare Hamilton Hall Professor of Chemistry Northwestern University 5:05 Q for Quantum Chemistry Arman Zaribafiyan CEO & Founder Good Chemistry Read the entire page →
From page 204... ... 204 ADVANCING CHEMISTRY AND QUANTUM INFORMATION SCIENCE 5:20 Q&A with Committee Moderated by Damian Watkins Chief of Research and Innovation Aperio Global 5:35 Closing Remarks Theodore Goodson, Committee Chair The Richard Bernstein Collegiate Professor of Chemistry University of Michigan 5:40 Adjourn Open Session Read the entire page →
From page 205... ... SQMS Superconducting Quantum Fermi National Accelerator $115a sqms.fnal.gov Materials and Systems Center Laboratory National Science Q-SEnSE Quantum Systems through University of Colorado, Boulder $25a colorado.edu/ Foundation: Entangled Science and Engineering research/qsense Quantum Leap HQAN Hybrid Quantum Architectures University of Illinois -- Illinois $25a hqan.illinois.edu/ Challenge and Networks Quantum Information Science Institutes and Technology Center (IQUIST) (Authorized under NQIA) Read the entire page →
From page 206... ... Federal Full Name of Center or Agency Acronym Program Lead University Website NSF NSF Q-AMASE-i Quantum Foundry for University of California, quantumfoundry.ucsb.edu Accelerated Development of Santa Barbara Quantum Materials NSF ERC-CQN Engineering Research Center University of Arizona cqn-erc.org for Quantum Networks JILA Physics Frontiers Center at University of Colorado, jila-pfc.colorado.edu JILA Boulder JQI Joint Quantum Institute University of Maryland, jqi.umd.edu College Park IQIM Institute for Quantum California Institute of iqim.caltech.edu Information and Matter Technology CUA Center for Ultracold Atoms Massachusetts Institute of cua.mit.edu Technology CQuIC Center for Quantum University of New Mexico cquic.unm.edu/ Information and Control ITAMP Institute for Theoretical Atomic Harvard pweb.cfa.harvard.edu and Molecular Physics CIQM Center for Integrated Quantum Harvard ciqm.harvard.edu Materials EPIQC Enabling Practical Scale The University of Chicago epiqc.cs.uchicago.edu Quantum Computing STAQ Software-Tailored Architecture Duke staq.pratt.duke.edu for Quantum co-design QISE-NET Quantum Information Science The University of Chicago qisenet.uchicago.edu and Engineering Network DOE ASCR Advanced Scientific Computing N/A https://science.osti.gov/ascr Research QIS Program BER Biological and Environmental N/A https://science.osti.gov/Initiatives/ Research QIS/Program-Offices-QIS-Pages BES Basic Energy Science QIS N/A science.osti.gov/bes/Research/qis Program FES Fusion Energy Sciences N/A https://science.osti.gov/Initiatives/ QIS/Program-Offices-QIS Pages%20 HEP High Energy Physics QIS N/A science.osti.gov/hep/Research/ Program Quantum-Information-Science-QIS Read the entire page →
From page 207... ... Louis; /bulletin.wustl.edu/undergrad/engineering/electrical-and-systems/ minor-quantum-engineering/ • Colorado University; catalog.colorado.edu/undergraduate/colleges-schools/engineering-applied-science/ programs-study/electrical-computer-energy-engineering/quantum-engineering-minor/ • California Institute of Technology; iqim.caltech.edu/quantum-science-and-engineering-minor/ • Saint Anslem College; www.anselm.edu/majors-minors/quantum-information-science QISE Certificate • Washington University in St. Louis; https://www.quantumx.washington.edu/training/aqet/ • University of Texas at Austin; catalog.utexas.edu/undergraduate/natural-sciences/minor-and-certificate programs/ • Drexel University; https://drexel.edu/coas/academics/graduate-programs/physics/certificate-quantum technology/ QISE Masters • University of California, Los Angeles; https://qst.ucla.edu/program.html All Three Programs Available • Colorado School of Mines, Engineering; https://quantum.mines.edu/program/ • University of Arizona, Optical Science, Quantum Information; https://www.optics.arizona.edu/ prospective-students/graduate-programs/ms-optical-sciences-quantum-information 207 Read the entire page →
From page 209... ... Appendix E Acronyms and Glossary LIST OF ACRONYMS 2D two dimensional 2DES two-dimensional electronic spectroscopy 2DIR two-dimensional infrared 3D three dimensional 4D four dimensional AC alternating current AMO atomic molecular and optical BBO β-barium borate BI Boehringer Ingelheim CC coupled cluster theory CCI Community College Internship CCNOT controlled-controlled NOT gate CISS chirality-induced spin selectivity CNOT controlled NOT gate CQC Cambridge Quantum Computing CW continuous wave DEER double electron-electron resonance DFT density functional theory DMRG density matrix renormalization group DNP dynamic nuclear polarization DOD Department of Defense DOE Department of Energy DQ double quantum 209 Read the entire page →
From page 210... ... 210 ADVANCING CHEMISTRY AND QUANTUM INFORMATION SCIENCE EDM electric dipole moment ELDOR electron-electron double resonance EMF endohedral metallofullerene ENDOR electron-nuclear double resonance EPR electron paramagnetic resonance ES electronic spectroscopy ESEEM electron-spin-echo envelope modulation ESR electron spin resonance ET electron transfer ETPA entangled two-photon absorption FAIR Findability, Accessibility, Interoperability, and Reusability FCI full configuration interaction FeMoCo FeMo cofactor FMO Fenna–Matthews–Olson FTQC fault-tolerant quantum computing HOM Hong–Ou–Mandel HR hyper-Raman HX heavy-hole INS inelastic neutron scattering IR infrared IRSC Indian River State College KDP potassium dideuterium phosphate L3C low-profit limited liability company LX light-hole MMCC method of moments coupled cluster MOF metal–organic framework MRFM magnetic resonance force microscopy μSR muon spin relaxation NDAA National Defense Authorization Act NHMFL National High Magnetic Field Laboratory NIR near-infrared NISQ noisy intermediate-scale quantum NIST National Institute of Standards and Technology NMR nuclear magnetic resonance NP nondeterministic polynomial time NQI National Quantum Initiative NQIA National Quantum Initiative Act NSF National Science Foundation NSMM near-field scanning microwave microscopy NSOM (SNOM) near-field scanning optical microscopy NV nitrogen vacancy Read the entire page →
From page 211... ... APPENDIX E 211 OCC optical cycling center ODMR optically detected magnetic resonance OOP-ESEEM out-of-phase electron-spin-echo envelope modulation OXIDE Open Chemistry Collaborative in Diversity Equity PBS polarizing beam splitter PI principal investigator QED-C Quantum Economic Development Consortium QIS quantum information science QISE quantum information science and engineering QIST quantum information science and technology QMA-Hard Quantum Merlin Arthur-Hard QMC quantum Monte Carlo QML quantum machine learning Q-NEXT Next Generation Quantum Science and Engineering QPE quantum phase estimation QTEdu Quantum Technology Education QTM quantum tunneling of magnetization R&D research and development RF radiofrequency SBIR Small Business Innovation Research SF singlet fission SMM single-molecule magnet SNL shot noise limit SNR signal-to-noise ratio SPDC spontaneous parametric down-conversion SQP spin qubit pair STEM science, technology, engineering, and mathematics STM scanning tunneling microscope STTR Small Business Technology Transfer T1 spin-lattice relaxation time T2 transverse spin relaxation time TEM transmission electron microscopy TLS two-level system TPA two-photon absorption URPOC underrepresented people of color VQE variational quantum eigensolver ZFS zero-field splitting ZPL zero-phonon line ZQ zero quantum Read the entire page →
From page 212... ... 2016. "Enhancing Coherence in Molecular Spin Qubits via Atomic Clock Transitions." Nature 531(7594) Read the entire page →

From page 188...

... in the quantum computing space. Their collaboration seeks to improve algorithms for using near-term quantum computers within the framework of variational quantum eigensolver (VQE)