overview of suny research enterprise and quantum research ... · $1.6 bn. annual r&d...

Overview of SUNY Research Enterprise and Quantum Research Capacity

Grace WangSenior Vice Chancellor for Research and Economic Development

SUNY

64 Campuses

424 K Degree Seeking Students

$13 BnAnnual Operating Budget

SUNY Research Enterprise

7,100 Projects

2,700 Principal Investigators

$1.6 Bn Annual R&D Expenditure (FY 2017)

SUNY Innovation Activities

1,522 Issued Patents

717 Active License Agreements

18 Incubators

110 Active Startups

Ranks #30 among worldwide universities for U.S. granted utility patents in 2018

SUNY Economic Impact

30,600Students

$401 MAnnual R&D(FY 2017)

26,000Students

$238 MAnnual R&D(FY 2017)

17,700Students

$156 MAnnual R&D(FY 2017)

17,300Students

$98 MAnnual R&D(FY 2017)

3,000Students

$309 MAnnual R&D(FY 2017)

SUNY Medical Schools and Hospitals

3 Hospitals

$2.8 Bn Annual Revenue

4 Medical Schools

9 M Unique Patient Records

Quantum Materials, Devices

and Packaging

Quantum Information

Science

SUNY Quantum Research and Education Capacity

Quantum Enabled

Research Frontiers

ACC

ELER

ATIN

G 6

.1 to

6.3

+

Quantum Sensing Quantum Communication Quantum Computing

Quantum-Smart Workforce

Quantum Materials, Devices and Packaging

Superconducting Materials

Growth, characterization applications (e.g. Josephson Junctions) of superconducting films (such as YBa2Cu3O7, NbN, MoN, and TiC).

Refs: Appl. Phys. Lett. 66, 3674 (1995).Appl. Phys. Lett. 72, 3068 (1998).Chem. Commun. 45, 6022 (2008).J. Am. Chem. Soc. 132, 2516 (2010)

J. Am. Chem. Soc. 133, 20735 (2011).

Quanxi Jia et.al. (Currently at University at Buffalo)

Quantum Qubit Fabrication & Measurement

Wafer-scale, high-quality qubit fabrication in SUNY Poly 300mm facility

Collaboration with AFRL and NIST

300mm wafer with patterns for superconducting qubitsfabricated at SUNY Poly

Qubit transmon measurement from devices fabricated on 300mm wafers

using 193 nm lithography

Cavity resonant freq.

Freq. shift due to qubit-cavity

interaction

Papa Rao et.al., SUNY Polytechnic Institute

Heterogeneous Integration Research in Packaging Center (CHIRP)

Thermal ManagementHolistic Scaleout Designs Within Heterogeneous Packages Power Delivery and Power Management Systems Minimizing Thermal Interfacial ResistanceAlternative Fine Pitch Interconnect Technologies

Center for Heterogeneous Integration Research in Packaging (CHIRP)

Bahgat Sammakia (Center co-Director), Binghamton UniversityIn collaboration with Purdue University

Computational and Experimental Tools for Next-gen NanoelectronicsPackaging

Electromigration and Thermomigration Reliability

All Graphene Nano Ribbon TFET Switch

Molecular Dynamics

Nonlinear FEA

Cemal Basaran (Center Director), University at Buffalo

Orlov et. al., Stony Brook University

Quantum Information Science

Carlo Cafaro, SUNY Polytechnic Institute

Paul Alsing, Air Force Research Laboratory (AFRL)

Quantum InformationTechnology Laboratory

SUNY Quantum Information Science Center Long IslandD. Averin T. C. Wei

V. KorepinD. Schneble

D. KharzeevE. Figueroa

Xu Du

In collaboration with BNL, ORNL, Stockholm, and Padova.

NYC-SBU-BNL Distrubuted Quantum Computing Network

Possible NY partners: AIM Photonics, AFRL.

Quantum Computing Enabled New Research Frontiers

Informatics Driven Discovery of Quantum Materials

References: MRS Bulletin 43; (Sept.2018): Data centric science for materials innovation; I Tanaka, K.Rajan & C. Wolverton ; Molecular Systems Design & Eng. (Sept. 2018): Correlative analysis of MOF structures through manifold learning of Hirshfeld surfaces: X.Shen et.al

Krishna Rajan et.al., University at Buffalo

Hafnium nitride (HfN10) structure. Credit: MIPT

Artem R. Oganov et. al., Stony Brook University

Predicting New High-Energy Compounds

Faulty Genomic Pathway Linked to Schizophrenia

“… could lead to treatments for pregnant mothers at risk for bearing children with the disease.”-- NSF

Michal K. Stachowiak, et. al., University at Buffalo

Quantum Materials, Devices

and Packaging

Quantum Information

Science

SUNY Quantum Research and Education Capacity

Quantum Enabled

Research Frontiers

ACC

ELER

ATIN

G 6

.1 to

6.3

+

Quantum Sensing Quantum Communication Quantum Computing

Quantum-Smart Workforce

Source: Continuing Innovation in Information Technology (2012), National Academies Press

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