2215976
Project Grant
Overview
Grant Description
MRI: Acquisition of a Monochromated, Magnetic-Field-Free, Atomic-Resolution Scanning Transmission Electron Microscope Enabling Multidisciplinary Research and Education - Non-Technical Description:
Nanometer scale materials represent a class of substances with at least one dimension that approaches the size of individual atoms. These materials exhibit properties that are dramatically different from substances at larger length scales and are essential to advance a wide array of technologies, ranging from magnetic data-storage systems to superconducting quantum computers to biomaterials applications.
To study and improve upon these materials, tools are required to examine them at the atomic level while minimizing any disturbance to their structure. Electron microscopy, which uses electrons to see atoms, is one of the fundamental means by which the structures of such nanoscale materials can be studied. Current designs of high-resolution transmission electron microscopes require a lens to focus the electron beam on the sample surface. A side effect of this design is that the sample material is inadvertently exposed to a high magnetic field. Yet, turning the lens off to eliminate the magnetic field when studying magnetic or superconducting materials makes atomic-resolution analysis impossible.
The instrument acquired through this Major Research Instrumentation grant has a new lens design, providing a magnetic-field-free sample region and, when combined with a nearly mono-energetic electron source, allows for atomic-resolution imaging as well as chemical analysis of these critical materials. In addition, atomic resolution, magnetic-field-free analysis can now also be achieved during heating or cooling experiments or when a controlled magnetic field is applied.
To reach a broader user community and for communicating the capabilities of the instrument, the principal investigators hold annual workshops, organize sessions at national and international conferences, and engage with local microscopy societies. The instrument, moreover, provides the diverse undergraduate and graduate student body at University of Illinois - Chicago (UIC), a Research-1 Hispanic-Serving Institution with opportunities for hands-on research and learning experiences in cutting-edge quantum, superconducting or biomaterials science. New in-class course modules and online teaching resources are developed and freely distributed online using data from the field-free transmission electron microscope.
Technical Description:
While the development of aberration-correctors, monochromated electron sources, and advanced detectors has fueled the current revolution in resolution, nearly all high-resolution transmission electron microscopy (TEM) experiments are still performed with the sample being exposed to a high magnetic field, since the objective lens (OL) pole-pieces require a magnetic field of about 3 Tesla. Such a magnetic field limits the samples that can be studied, preventing magnetic, magneto-optical, magneto-electric, superconductive or topological materials from being characterized under relevant conditions.
Traditional magnetic imaging methods, where the OL is turned off, limit the spatial resolution to nanometer length-scales and do not allow for atomic-resolution chemical analysis. This instrument has a novel lens design that allows for better than 100 pm spatial resolution at 200 KV with a residual magnetic field of less than 0.3 MT and 40 MEV energy resolution with a probe size of 110 nm. Atomic-resolution chemical analysis, as well as novel image modes, such as 4D-STEM and differential phase contrast imaging, can be combined with in-situ heating or cooling experiments to study magnetic, superconducting or other electronic phase transitions.
Research projects at UIC enabled by the new instrument include the study of novel magnetic phases in Ni-based perovskite oxides, excitons in 2-dimensional materials, conventional and near-room temperature superconductors, nanoparticles/quantum dots as topological insulators, and anti-cavity biofilms and the mechanical manipulation of cells.
External users, ranging from universities, national laboratories, and companies across the United States to international partner institutions, can take advantage of the capabilities provided by the instrument to study novel quantum materials, new magnetic structures, photovoltaic materials, energy-storage devices, and biological systems under controlled magnetic-field conditions and with atomic resolution.
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.
Nanometer scale materials represent a class of substances with at least one dimension that approaches the size of individual atoms. These materials exhibit properties that are dramatically different from substances at larger length scales and are essential to advance a wide array of technologies, ranging from magnetic data-storage systems to superconducting quantum computers to biomaterials applications.
To study and improve upon these materials, tools are required to examine them at the atomic level while minimizing any disturbance to their structure. Electron microscopy, which uses electrons to see atoms, is one of the fundamental means by which the structures of such nanoscale materials can be studied. Current designs of high-resolution transmission electron microscopes require a lens to focus the electron beam on the sample surface. A side effect of this design is that the sample material is inadvertently exposed to a high magnetic field. Yet, turning the lens off to eliminate the magnetic field when studying magnetic or superconducting materials makes atomic-resolution analysis impossible.
The instrument acquired through this Major Research Instrumentation grant has a new lens design, providing a magnetic-field-free sample region and, when combined with a nearly mono-energetic electron source, allows for atomic-resolution imaging as well as chemical analysis of these critical materials. In addition, atomic resolution, magnetic-field-free analysis can now also be achieved during heating or cooling experiments or when a controlled magnetic field is applied.
To reach a broader user community and for communicating the capabilities of the instrument, the principal investigators hold annual workshops, organize sessions at national and international conferences, and engage with local microscopy societies. The instrument, moreover, provides the diverse undergraduate and graduate student body at University of Illinois - Chicago (UIC), a Research-1 Hispanic-Serving Institution with opportunities for hands-on research and learning experiences in cutting-edge quantum, superconducting or biomaterials science. New in-class course modules and online teaching resources are developed and freely distributed online using data from the field-free transmission electron microscope.
Technical Description:
While the development of aberration-correctors, monochromated electron sources, and advanced detectors has fueled the current revolution in resolution, nearly all high-resolution transmission electron microscopy (TEM) experiments are still performed with the sample being exposed to a high magnetic field, since the objective lens (OL) pole-pieces require a magnetic field of about 3 Tesla. Such a magnetic field limits the samples that can be studied, preventing magnetic, magneto-optical, magneto-electric, superconductive or topological materials from being characterized under relevant conditions.
Traditional magnetic imaging methods, where the OL is turned off, limit the spatial resolution to nanometer length-scales and do not allow for atomic-resolution chemical analysis. This instrument has a novel lens design that allows for better than 100 pm spatial resolution at 200 KV with a residual magnetic field of less than 0.3 MT and 40 MEV energy resolution with a probe size of 110 nm. Atomic-resolution chemical analysis, as well as novel image modes, such as 4D-STEM and differential phase contrast imaging, can be combined with in-situ heating or cooling experiments to study magnetic, superconducting or other electronic phase transitions.
Research projects at UIC enabled by the new instrument include the study of novel magnetic phases in Ni-based perovskite oxides, excitons in 2-dimensional materials, conventional and near-room temperature superconductors, nanoparticles/quantum dots as topological insulators, and anti-cavity biofilms and the mechanical manipulation of cells.
External users, ranging from universities, national laboratories, and companies across the United States to international partner institutions, can take advantage of the capabilities provided by the instrument to study novel quantum materials, new magnetic structures, photovoltaic materials, energy-storage devices, and biological systems under controlled magnetic-field conditions and with atomic resolution.
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.
Awardee
Grant Program (CFDA)
Awarding Agency
Place of Performance
Chicago,
Illinois
60607-4306
United States
Geographic Scope
Single Zip Code
Related Opportunity
None
Analysis Notes
Amendment Since initial award the total obligations have increased 38% from $2,890,000 to $3,990,000.
University Of Illinois was awarded
Atomic-Resolution STEM for Multidisciplinary Research
Project Grant 2215976
worth $3,990,000
from Directorate for Mathematical and Physical Sciences in September 2022 with work to be completed primarily in Chicago Illinois United States.
The grant
has a duration of 3 years and
was awarded through assistance program 47.049 Mathematical and Physical Sciences.
Status
(Ongoing)
Last Modified 9/20/22
Period of Performance
9/1/22
Start Date
8/31/25
End Date
Funding Split
$4.0M
Federal Obligation
$0.0
Non-Federal Obligation
$4.0M
Total Obligated
Activity Timeline
Transaction History
Modifications to 2215976
Additional Detail
Award ID FAIN
2215976
SAI Number
None
Award ID URI
SAI EXEMPT
Awardee Classifications
Public/State Controlled Institution Of Higher Education
Awarding Office
490307 DIVISION OF MATERIALS RESEARCH
Funding Office
490306 MPS MULTIDISCIPLINARY ACTIVITIES
Awardee UEI
W8XEAJDKMXH3
Awardee CAGE
1YGW1
Performance District
07
Senators
Richard Durbin
Tammy Duckworth
Tammy Duckworth
Representative
Danny Davis
Budget Funding
| Federal Account | Budget Subfunction | Object Class | Total | Percentage |
|---|---|---|---|---|
| Research and Related Activities, National Science Foundation (049-0100) | General science and basic research | Grants, subsidies, and contributions (41.0) | $3,990,000 | 100% |
Modified: 9/20/22