2423343
Project Grant
Overview
Grant Description
Sbir Phase I: A Fusion-Fast-Fission Reactor -The broader impact/commercial potential of this Phase I Small Business Innovation Research (SBIR) project is a safer, less expensive, proliferation-resistant hybrid nuclear technology. Previous experiments fissioned natural uranium without enrichment, thereby removing nuclear proliferation as one of the roadblocks to the use of nuclear power. The hybrid sub-critical reactor has no chain reaction and can't run away.
The hybrid is cooled with helium gas which can't become radioactive. Without cooling water, a large pressure dome isn't required reducing plant cost and site size. The hybrid produces fusion neutrons without large lasers or enormous magnets while keeping its fuel at a billion times the fuel density of tokamaks.
The fast fusion neutrons will fission thorium and spent reactor fuel. A good business case comes from being paid twice to fission existing nuclear waste while generating electricity. Hybrid fuel rods can be installed in existing reactors to burn nuclear waste on-site while reducing the time between refueling cycles.
The hybrid reactor makes the best use of fusion's fast neutrons and fission's high energy density without the complications of either. A new, safer, cleaner nuclear technology can reduce carbon emissions and present environmental advantages. This SBIR Phase I project proposes to characterize the lattice confinement fusion-fast fission of depleted uranium through time-resolved neutron spectroscopy.
Lattice confinement fusion holds deuterium fuel in a metal lattice as an electron-screened, cold plasma at a billion times the plasma density of a tokamak. Extended electrodynamics may provide insight into the fusion driver. Earlier experiments measured the fast fission of deuterium-loaded natural uranium and thorium by high-resolution gamma (HPGe) spectroscopy, alpha/beta scintillator spectroscopy, and solid-state nuclear track detectors.
Neutron energies were calculated to average 6.4 MeV. Phase I will use these diagnostics and measure the fast neutron spectrum with multiple neutron scintillator spectrometers with 500 MHz sampling rates and 200 keV energy resolution from 300 keV to 20 MeV. We expect to observe the 2.45 MeV deuterium deuterium (DD), 14.1 MeV deuterium tritium (DT) fusion neutrons and conventional neutron fission spectra peaking at 1 MeV, averaging 2 MeV with a Maxwellian tail past 10 MeV.
Phase I control, and active experiments will be shielded against cosmogenic neutrons. Four sets of ten-day runs are planned with four simultaneous micro-reactors per run. The neutron flux, drive currents, and voltages will determine the scaling efficacy of a fusion-fast-fission sub-critical hybrid reactor technology. 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 planned for this award.
The hybrid is cooled with helium gas which can't become radioactive. Without cooling water, a large pressure dome isn't required reducing plant cost and site size. The hybrid produces fusion neutrons without large lasers or enormous magnets while keeping its fuel at a billion times the fuel density of tokamaks.
The fast fusion neutrons will fission thorium and spent reactor fuel. A good business case comes from being paid twice to fission existing nuclear waste while generating electricity. Hybrid fuel rods can be installed in existing reactors to burn nuclear waste on-site while reducing the time between refueling cycles.
The hybrid reactor makes the best use of fusion's fast neutrons and fission's high energy density without the complications of either. A new, safer, cleaner nuclear technology can reduce carbon emissions and present environmental advantages. This SBIR Phase I project proposes to characterize the lattice confinement fusion-fast fission of depleted uranium through time-resolved neutron spectroscopy.
Lattice confinement fusion holds deuterium fuel in a metal lattice as an electron-screened, cold plasma at a billion times the plasma density of a tokamak. Extended electrodynamics may provide insight into the fusion driver. Earlier experiments measured the fast fission of deuterium-loaded natural uranium and thorium by high-resolution gamma (HPGe) spectroscopy, alpha/beta scintillator spectroscopy, and solid-state nuclear track detectors.
Neutron energies were calculated to average 6.4 MeV. Phase I will use these diagnostics and measure the fast neutron spectrum with multiple neutron scintillator spectrometers with 500 MHz sampling rates and 200 keV energy resolution from 300 keV to 20 MeV. We expect to observe the 2.45 MeV deuterium deuterium (DD), 14.1 MeV deuterium tritium (DT) fusion neutrons and conventional neutron fission spectra peaking at 1 MeV, averaging 2 MeV with a Maxwellian tail past 10 MeV.
Phase I control, and active experiments will be shielded against cosmogenic neutrons. Four sets of ten-day runs are planned with four simultaneous micro-reactors per run. The neutron flux, drive currents, and voltages will determine the scaling efficacy of a fusion-fast-fission sub-critical hybrid reactor technology. 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 planned for this award.
Awardee
Funding Goals
THE GOAL OF THIS FUNDING OPPORTUNITY, "NSF SMALL BUSINESS INNOVATION RESEARCH (SBIR)/ SMALL BUSINESS TECHNOLOGY TRANSFER (STTR) PROGRAMS PHASE I", IS IDENTIFIED IN THE LINK: HTTPS://WWW.NSF.GOV/PUBLICATIONS/PUB_SUMM.JSP?ODS_KEY=NSF23515
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Cleveland,
Ohio
44135-3191
United States
Geographic Scope
Single Zip Code
Related Opportunity
Analysis Notes
Amendment Since initial award the End Date has been extended from 01/31/25 to 06/30/25 and the total obligations have increased 7% from $274,936 to $294,936.
Global Energy Corporation was awarded
Project Grant 2423343
worth $294,936
from National Science Foundation in May 2024 with work to be completed primarily in Cleveland Ohio United States.
The grant
has a duration of 1 year 1 months and
was awarded through assistance program 47.084 NSF Technology, Innovation, and Partnerships.
The Project Grant was awarded through grant opportunity NSF Small Business Innovation Research / Small Business Technology Transfer Phase I Programs.
SBIR Details
Research Type
SBIR Phase I
Title
SBIR Phase I: A Fusion-Fast-Fission Reactor
Abstract
The broader impact/commercial potential of this Phase I Small Business Innovation Research (SBIR) project is a safer, less expensive, proliferation-resistant hybrid nuclear technology. Previous experiments fissioned natural uranium without enrichment, thereby removing nuclear proliferation as one of the roadblocks to the use of nuclear power. The hybrid sub-critical reactor has no chain reaction and can't run away. The hybrid is cooled with helium gas which can't become radioactive. Without cooling water, a large pressure dome isn't required reducing plant cost and site size. The hybrid produces fusion neutrons without large lasers or enormous magnets while keeping its fuel at a billion times the fuel density of tokamaks. The fast fusion neutrons will fission thorium and spent reactor fuel. A good business case comes from being paid twice to fission existing nuclear waste while generating electricity. Hybrid fuel rods can be installed in existing reactors to burn nuclear waste on-site while reducing the time between refueling cycles. The hybrid reactor makes the best use of fusion's fast neutrons and fission's high energy density without the complications of either. A new, safer, cleaner nuclear technology can reduce carbon emissions and present environmental advantages.
This SBIR Phase I project proposes to characterize the Lattice Confinement Fusion-Fast Fission of depleted uranium through time-resolved neutron spectroscopy. Lattice Confinement Fusion holds deuterium fuel in a metal lattice as an electron-screened, cold plasma at a billion times the plasma density of a tokamak. Extended Electrodynamics may provide insight into the fusion driver. Earlier experiments measured the fast fission of deuterium-loaded natural uranium and thorium by high-resolution gamma (HPGe) spectroscopy, alpha/beta scintillator spectroscopy, and solid-state nuclear track detectors. Neutron energies were calculated to average 6.4 MeV. Phase I will use these diagnostics and measure the fast neutron spectrum with multiple neutron scintillator spectrometers with 500 MHz sampling rates and 200 keV energy resolution from 300 keV to 20 MeV. We expect to observe the 2.45 MeV Deuterium Deuterium (DD), 14.1 MeV Deuterium Tritium (DT) fusion neutrons and conventional neutron fission spectra peaking at 1 MeV, averaging 2 MeV with a Maxwellian tail past 10 MeV. Phase I control, and active experiments will be shielded against cosmogenic neutrons. Four sets of ten-day runs are planned with four simultaneous micro-reactors per run. The neutron flux, drive currents, and voltages will determine the scaling efficacy of a fusion-fast-fission sub-critical hybrid reactor technology.
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.
Topic Code
EN
Solicitation Number
NSF 23-515
Status
(Complete)
Last Modified 4/4/25
Period of Performance
5/1/24
Start Date
6/30/25
End Date
Funding Split
$294.9K
Federal Obligation
$0.0
Non-Federal Obligation
$294.9K
Total Obligated
Activity Timeline
Transaction History
Modifications to 2423343
Additional Detail
Award ID FAIN
2423343
SAI Number
None
Award ID URI
SAI EXEMPT
Awardee Classifications
Small Business
Awarding Office
491503 TRANSLATIONAL IMPACTS
Funding Office
491503 TRANSLATIONAL IMPACTS
Awardee UEI
MC3LTJXCMFA8
Awardee CAGE
5H5W0
Performance District
OH-11
Senators
Sherrod Brown
J.D. (James) Vance
J.D. (James) Vance
Modified: 4/4/25