2342336
Cooperative Agreement
Overview
Grant Description
Mid-scale: Operations of the Center for High Energy X-Ray Science (CHEXS)
This award continues to support operations of the Center for High Energy X-Ray Science (CHEXS), a national facility providing access to unique, world-leading experimental capabilities for the US and international research community.
CHEXS consists of four core research efforts, each attached to specific synchrotron beamlines at the Cornell High Energy Synchrotron Source (CHESS).
These research programs align with the goals of the three NSF directorates (BIO, ENG, and MPS) which have supported CHEXS since 2019.
Research at all beamlines is fundamentally interdisciplinary, and proposals from any field of science are eligible for beamtime, subject only to external peer review based on the NSF review criteria (scientific merit and broader impacts).
CHEXS also supports efforts in X-ray technology R&D, education of the next generation of X-ray experts, and development and integration of advanced computation and data science for synchrotrons.
CHEXS has an overarching mission to broaden participation in synchrotron research, and to recruit and train a diverse and growing user community.
Located on the central campus of Cornell University, CHEXS is uniquely able to train the next generation of synchrotron scientists.
CHEXS supports post-docs and Ph.D. students, hosts hands-on scientific workshops to train new users in X-ray methods, provides summer training and mentorship programs targeting undergraduates from underrepresented groups in STEM fields, and provides high-quality informational materials to the general public.
Specific research areas targeted at the Center for High Energy X-Ray Science (CHEXS) are:
(1) Time-resolved studies of manufacturing processes of structural metals;
(2) Structural studies of biomolecules in extreme environments to elucidate the rules of life;
(3) High-throughput characterization of quantum materials to uncover intertwined quantum correlations; and
(4) Spectroscopic studies of valence electronic states in functional materials and inside operating devices.
The CHEXS takes advantage of the high beam energy and large bunch charges available from the Cornell Energy Storage Ring (CESR) to offer exciting opportunities for nanosecond-scale measurements of dynamics inside heavy materials.
CHEXS beamlines are harnessing the opportunity presented by rapidly growing data collection rates, incorporating new analysis methods, data analytics, and machine learning.
Development of frontier research at CHEXS is supported by an X-ray technology R&D program on next generation, cost-effective, high-performance undulator sources, high-heat-load crystal optics, faster X-ray detectors, and beamline automation.
The specific X-ray beamlines include:
Forming and Shaping Technology (FAST) beamline supports sub-millisecond time-resolved studies of manufacturing processes such as laser welding and rapid quenching.
Extreme Biology (XBIO) beamlines studies the building blocks of life at the molecular level, under extreme conditions such as high pressure, strict anoxic conditions, dissolved gasses, extremes of heat and cold, and harsh chemical environments.
XBIO combines both crystallography and small angle scattering to determine the atomic structure, shape, folding, and oligomeric state of molecules.
Q-Mapping for Quantum Materials (QM2) beamline provides high-throughput characterization of quantum materials in reciprocal space (also known as “Q-space”) to uncover intertwined quantum correlations of spins, charges, and orbitals, from high to low temperatures and spanning entire phase diagrams.
Photon-in, Photon-out X-ray Spectroscopy (PIPOXS) beamline enables spectroscopic studies of valence electronic states in functional materials using hard X-rays, allowing access to opaque materials or sample environments.
The beamline supports in situ and operando studies of man-made catalysts and enzymes with applications to fuel cells, batteries, and electronic excitations in quantum materials.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the foundation's intellectual merit and broader impacts review criteria.
Subawards are not planned for this award.
This award continues to support operations of the Center for High Energy X-Ray Science (CHEXS), a national facility providing access to unique, world-leading experimental capabilities for the US and international research community.
CHEXS consists of four core research efforts, each attached to specific synchrotron beamlines at the Cornell High Energy Synchrotron Source (CHESS).
These research programs align with the goals of the three NSF directorates (BIO, ENG, and MPS) which have supported CHEXS since 2019.
Research at all beamlines is fundamentally interdisciplinary, and proposals from any field of science are eligible for beamtime, subject only to external peer review based on the NSF review criteria (scientific merit and broader impacts).
CHEXS also supports efforts in X-ray technology R&D, education of the next generation of X-ray experts, and development and integration of advanced computation and data science for synchrotrons.
CHEXS has an overarching mission to broaden participation in synchrotron research, and to recruit and train a diverse and growing user community.
Located on the central campus of Cornell University, CHEXS is uniquely able to train the next generation of synchrotron scientists.
CHEXS supports post-docs and Ph.D. students, hosts hands-on scientific workshops to train new users in X-ray methods, provides summer training and mentorship programs targeting undergraduates from underrepresented groups in STEM fields, and provides high-quality informational materials to the general public.
Specific research areas targeted at the Center for High Energy X-Ray Science (CHEXS) are:
(1) Time-resolved studies of manufacturing processes of structural metals;
(2) Structural studies of biomolecules in extreme environments to elucidate the rules of life;
(3) High-throughput characterization of quantum materials to uncover intertwined quantum correlations; and
(4) Spectroscopic studies of valence electronic states in functional materials and inside operating devices.
The CHEXS takes advantage of the high beam energy and large bunch charges available from the Cornell Energy Storage Ring (CESR) to offer exciting opportunities for nanosecond-scale measurements of dynamics inside heavy materials.
CHEXS beamlines are harnessing the opportunity presented by rapidly growing data collection rates, incorporating new analysis methods, data analytics, and machine learning.
Development of frontier research at CHEXS is supported by an X-ray technology R&D program on next generation, cost-effective, high-performance undulator sources, high-heat-load crystal optics, faster X-ray detectors, and beamline automation.
The specific X-ray beamlines include:
Forming and Shaping Technology (FAST) beamline supports sub-millisecond time-resolved studies of manufacturing processes such as laser welding and rapid quenching.
Extreme Biology (XBIO) beamlines studies the building blocks of life at the molecular level, under extreme conditions such as high pressure, strict anoxic conditions, dissolved gasses, extremes of heat and cold, and harsh chemical environments.
XBIO combines both crystallography and small angle scattering to determine the atomic structure, shape, folding, and oligomeric state of molecules.
Q-Mapping for Quantum Materials (QM2) beamline provides high-throughput characterization of quantum materials in reciprocal space (also known as “Q-space”) to uncover intertwined quantum correlations of spins, charges, and orbitals, from high to low temperatures and spanning entire phase diagrams.
Photon-in, Photon-out X-ray Spectroscopy (PIPOXS) beamline enables spectroscopic studies of valence electronic states in functional materials using hard X-rays, allowing access to opaque materials or sample environments.
The beamline supports in situ and operando studies of man-made catalysts and enzymes with applications to fuel cells, batteries, and electronic excitations in quantum materials.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the foundation's intellectual merit and broader impacts review criteria.
Subawards are not planned for this award.
Awardee
Funding Goals
NOT APPLICABLE
Grant Program (CFDA)
Awarding Agency
Funding Agency
Place of Performance
Ithaca,
New York
14850-2820
United States
Geographic Scope
Single Zip Code
Related Opportunity
NOT APPLICABLE
Analysis Notes
Amendment Since initial award the total obligations have increased 1529% from $1,166,667 to $19,000,000.
Cornell University was awarded
CHEXS Operations: High Energy X-Ray Science
Cooperative Agreement 2342336
worth $19,000,000
from the Division of Molecular and Cellular Biosciences in September 2024 with work to be completed primarily in Ithaca New York United States.
The grant
has a duration of 4 years 6 months and
was awarded through assistance program 47.074 Biological Sciences.
Status
(Ongoing)
Last Modified 7/10/25
Period of Performance
9/1/24
Start Date
3/31/29
End Date
Funding Split
$19.0M
Federal Obligation
$0.0
Non-Federal Obligation
$19.0M
Total Obligated
Activity Timeline
Transaction History
Modifications to 2342336
Additional Detail
Award ID FAIN
2342336
SAI Number
None
Award ID URI
SAI EXEMPT
Awardee Classifications
Private Institution Of Higher Education
Awarding Office
490307 DIVISION OF MATERIALS RESEARCH
Funding Office
490807 DIVISION OF MOLECULAR AND
Awardee UEI
G56PUALJ3KT5
Awardee CAGE
4B578
Performance District
NY-19
Senators
Kirsten Gillibrand
Charles Schumer
Charles Schumer
Modified: 7/10/25