Nanotechnology Now – Press Release: Diamond cut precision: University of Illinois to develop diamond sensors for neutron experiment and quantum information science

Home > Press > Diamond cut precision: University of Illinois to develop diamond sensors for neutron experiment and quantum information science

Artist’s rendering illustrates the nitrogen-vacancy diamond sensor the Beck group will develop. The internal grid lines represent the path of laser light within the diamond—the incoming beam (thicker red line) is repeatedly reflected within the diamond sensor until it encounters the cut corner where it emerges (the thinner red line). Image by Yasmine Steele for Illinois Physics CREDIT The Grainger College of Engineering at the University of Illinois Urbana-Champaign

Abstract:
The nuclear physics group at the University of Illinois Urbana-Champaign is looking for evidence of new physics in neutrons, electrically neutral particles that hold atomic nuclei together with an interaction called the strong force. Faculty and researchers are participating in the nEDM experiment at Oak Ridge National Laboratory which will measure the neutron’s electric dipole moment, a property that allows neutrons to interact with electric fields despite their neutrality. A precise measurement will constrain theories extending the current standard model of particle physics. To achieve this, the researchers must accurately measure subtle changes in very strong electric fields.

Diamond cut precision: University of Illinois to develop diamond sensors for neutron experiment and quantum information science

Urbana, IL | Posted on April 14th, 2023

Professor of Physics Douglas Beck has been awarded a grant from the Department of Energy to develop sensors based on nitrogen vacancy diamond, a material whose quantum properties at low temperatures make it unusually sensitive to electric fields. His research group has shown that the material can measure strong electric fields, and the award will allow the researchers to construct sensors ready to use in the nEDM experiment. In addition, the material’s quantum properties make it a promising candidate for quantum information science. The researchers will also explore these potential applications.

Beck explained that chemically added nitrogen vacancy, or NV, impurities give diamond unusual electric field sensitivity. “These impurities are regions with an extra nitrogen atom and a hole [or vacancy] where carbon atoms normally would be,” he said. “When the material is cooled to less than 20 degrees above absolute zero, the impurities form a quantum system that responds to electric fields. This is quite an unusual characteristic because not many systems respond to electric fields, and that makes NV diamond special.”

The NV system can be made even more sensitive when it is prepared in a particular quantum state. Instead of letting the system stay in its lowest energy state after they cool it, the researchers form a quantum superposition of the lowest and next-lowest energy states called a dark state, so named because it does not interact with light. “In a sense, the name is meant to suggest that it’s immune to interactions with the environment,” Beck said. “Because it is long lived, it has a very sharply defined energy that very accurately tells us how big the electric field is.”

Beck’s group has demonstrated that this phenomenon enables NV diamond to measure strong electric fields, and the award will allow the researchers to develop reliable, robust sensors based on it. This will involve packaging sensors into units that readily connect with the lasers used to control them and minimize the effects of background noise. They are also investigating a quantum technique called dynamical decoupling that would allow them to effectively reverse the effects of experimental imperfections, according to Beck. This would make the already-precise electric field measurements even more accurate.

Another goal of the research is to explore proposals for using NV diamond in quantum information science. The dark state’s long lifetime and resilience against environmental noise make it a promising platform for quantum sensing and quantum memory. Many such applications depend on placing quantum systems in squeezed states that possess the minimum uncertainty allowed by the Heisenberg principle. There have been several proposals for creating squeezed states in NV diamond, and Beck’s group will survey their feasibilities.

This work will be supported with $650,000 over three years awarded by the Quantum Horizons initiative in the Department of Energy’s Nuclear Physics program.

####

For more information, please click here

Contacts:
Cassandra Smith
University of Illinois Grainger College of Engineering

Copyright © University of Illinois Grainger College of Engineering

If you have a comment, please Contact us.

Issuers of news releases, not 7th Wave, Inc. or Nanotechnology Now, are solely responsible for the accuracy of the content.

Bookmark:

News and information

New family of wheel-like metallic clusters exhibit unique properties April 14th, 2023

Efficient heat dissipation perovskite lasers using a high-thermal-conductivity diamond substrate April 14th, 2023

Nanobiotechnology: How Nanomaterials Can Solve Biological and Medical Problems April 14th, 2023

New Developments in Biosensor Technology: From Nanomaterials to Cancer Detection April 14th, 2023

Physics

IOP Publishing celebrates World Quantum Day with the announcement of a special quantum collection and the winners of two prestigious quantum awards April 14th, 2023

Quantum Physics

IOP Publishing celebrates World Quantum Day with the announcement of a special quantum collection and the winners of two prestigious quantum awards April 14th, 2023

New experiment translates quantum information between technologies in an important step for the quantum internet March 24th, 2023

Semiconductor lattice marries electrons and magnetic moments March 24th, 2023

Destroying the superconductivity in a kagome metal: Electronic control of quantum transitions in candidate material for future low-energy electronics March 3rd, 2023

Possible Futures

New family of wheel-like metallic clusters exhibit unique properties April 14th, 2023

Channeling mechanical energy in a preferred direction April 14th, 2023

Implantable device shrinks pancreatic tumors: Taming pancreatic cancer with intratumoral immunotherapy April 14th, 2023

Manchester graphene spin-out signs $1billion game-changing deal to help tackle global sustainability challenges: Landmark deal for the commercialisation of graphene April 14th, 2023

Sensors

New family of wheel-like metallic clusters exhibit unique properties April 14th, 2023

Nanobiotechnology: How Nanomaterials Can Solve Biological and Medical Problems April 14th, 2023

Scientists push the boundaries of manipulating light at the submicroscopic level March 3rd, 2023

TUS researchers propose a simple, inexpensive approach to fabricating carbon nanotube wiring on plastic films: The proposed method produces wiring suitable for developing all-carbon devices, including flexible sensors and energy conversion and storage devices March 3rd, 2023

Discoveries

Efficient heat dissipation perovskite lasers using a high-thermal-conductivity diamond substrate April 14th, 2023

Data can now be processed at the speed of light! April 14th, 2023

Channeling mechanical energy in a preferred direction April 14th, 2023

Implantable device shrinks pancreatic tumors: Taming pancreatic cancer with intratumoral immunotherapy April 14th, 2023

Materials/Metamaterials

Nanobiotechnology: How Nanomaterials Can Solve Biological and Medical Problems April 14th, 2023

New Developments in Biosensor Technology: From Nanomaterials to Cancer Detection April 14th, 2023

Bilayer PET/PVDF substrate-reinforced solid polymer electrolyte improves solid-state lithium metal battery performance March 24th, 2023

Understanding the mechanism of non-uniform formation of diamond film on tools: Paving the way to a dry process with less environmental impact March 24th, 2023

Announcements

Nanobiotechnology: How Nanomaterials Can Solve Biological and Medical Problems April 14th, 2023

New Developments in Biosensor Technology: From Nanomaterials to Cancer Detection April 14th, 2023

IOP Publishing celebrates World Quantum Day with the announcement of a special quantum collection and the winners of two prestigious quantum awards April 14th, 2023

Data can now be processed at the speed of light! April 14th, 2023

Interviews/Book Reviews/Essays/Reports/Podcasts/Journals/White papers/Posters

New family of wheel-like metallic clusters exhibit unique properties April 14th, 2023

Efficient heat dissipation perovskite lasers using a high-thermal-conductivity diamond substrate April 14th, 2023

Channeling mechanical energy in a preferred direction April 14th, 2023

Implantable device shrinks pancreatic tumors: Taming pancreatic cancer with intratumoral immunotherapy April 14th, 2023

Quantum nanoscience

IOP Publishing celebrates World Quantum Day with the announcement of a special quantum collection and the winners of two prestigious quantum awards April 14th, 2023

Semiconductor lattice marries electrons and magnetic moments March 24th, 2023

Destroying the superconductivity in a kagome metal: Electronic control of quantum transitions in candidate material for future low-energy electronics March 3rd, 2023

Scientists boost quantum signals while reducing noise: “Squeezing” noise over a broad frequency bandwidth in a quantum system could lead to faster and more accurate quantum measurements February 10th, 2023