TEM High Voltage Biasing Holder
ID: 9Type: BOTH
Overview

Topic

TEM High Voltage Biasing Holder

Agency

Department of CommerceNational Institute of Standards and Technology

Program

Type: SBIRPhase: BOTHYear: 2024

Topic Link

https://www.sbir.gov/node/2609733

Additional Information

https://grants.gov/search-results-detail/353574
Timeline
  1. 1
    Release Apr 16, 2024 12:00 AM
  2. 2
    Open Apr 16, 2024 12:00 AM
  3. 3
    Next Submission Due Jun 14, 2024 12:00 AM
  4. 4
    Close Jun 14, 2024 12:00 AM
Description

The Department of Commerce, specifically the National Institute of Standards and Technology, is seeking proposals for the FY2024 Small Business Innovation Research (SBIR) Program for CHIPS for America – CHIPS Metrology. The specific topic of the solicitation is the TEM High Voltage Biasing Holder.

The TEM High Voltage Biasing Holder technology has potential applications in the field of metrology for CHIPS (Creating Helpful Innovations and Productive Solutions) for America. This technology aims to improve the accuracy and precision of measurements in the field of microelectronics.

The solicitation is open for both Phase I and Phase II proposals. The project duration is not specified in the document. The funding specifics and performance goals can be found on the grants.gov website. The application due date is June 14, 2024.

For more information and to access the solicitation, visit the grants.gov website at [solicitation_agency_url].

Files
No associated files provided.
Similar Opportunities
DOD SBIR 24.4 Annual - Electronic quality ferroelectric III-Nitride epitaxy for device heterostructures
Active
Department of Defense
The Department of Defense (DOD) is seeking proposals for the topic "Electronic quality ferroelectric III-Nitride epitaxy for device heterostructures" as part of their SBIR 24.4 Annual solicitation. The objective of this topic is to develop single crystalline epitaxial thin films and heterostructures of group III-IIIb-Nitride thin films for electronic device applications. The goal is to produce films that are scalable to 4-inch diameter wafer sizes or larger. The research aims to enable the development of useful products such as high operating temperature electronic memory, high temperature electronic circuits, and integrated nonlinear optical photonic circuits for UV-visible wavelengths. In Phase I, the focus is on attaining the appropriate precursors for epitaxy and producing films lattice matched to GaN and other substrates. The goal is to assess the optical and electrical quality of the thin films and demonstrate ferroelectric behavior. Phase II continues the pursuit of single crystalline epitaxial thin films and heterostructures, with a focus on developing processes relevant to 4" or larger substrates. The goal is to fabricate devices for electronic memory applications and explore switching behavior. Optical properties and nonlinear optical functionality are also considered. In Phase III, the aim is to produce epitaxial foundry services for electronic and photonic device regimes that utilize ferroelectric III-Nitride thin films. Collaboration with other research groups is encouraged to make accurate comparisons with other epitaxial approaches. The solicitation is open until March 31, 2025. For more information, visit the [SBIR topic link](https://www.sbir.gov/node/2651313) or the [solicitation agency website](https://www.defensesbirsttr.mil/SBIR-STTR/Opportunities/).
DOD SBIR 24.4 Annual - Quantum Enhanced RF Components
Active
Department of Defense
The Department of Defense (DOD) is seeking proposals for the topic of "Quantum Enhanced RF Components" as part of their SBIR 24.4 Annual solicitation. The objective of this research is to utilize quantum phenomenology to create sensitive Radio Frequency (RF) components that can enhance the performance of current communication systems. By lowering the noise levels of these components, weaker signals can be detected, potentially enabling the radar detection of previously unseen targets. The research will focus on developing quantum-based RF components such as amplifiers, mixers, and oscillators that can be integrated with existing systems. The project will be conducted in two phases. Phase I will involve delivering a series of reports outlining the feasibility of the RF component using mathematical models for quantum phenomena. Phase II will require the delivery of a working prototype and a report documenting the prototype's capabilities and any necessary control software. The potential applications of this technology include enhancing the efficacy of security systems that rely on RF detection, minimizing disruptions and identifying the source of RF interference in police and first responder communications systems, and improving communication and navigation capabilities in maritime and aviation vehicles. The project duration is not specified, but the solicitation is open until March 31, 2025. For more information and to submit proposals, interested parties can visit the DOD SBIR website.
DOD SBIR 24.4 Annual - Quantum Enhanced RF Components
Active
Department of Defense
The Department of Defense (DOD) is seeking proposals for the topic of "Quantum Enhanced RF Components" in their SBIR 24.4 Annual solicitation. The objective of this research is to utilize quantum phenomenology to create sensitive Radio Frequency (RF) components that can enhance the performance of current communication systems. By lowering the noise levels of these components, weaker signals can be detected, potentially enabling the radar detection of previously unseen targets. The research will focus on developing quantum-based RF components such as amplifiers, mixers, and oscillators that can be integrated with existing systems. The project will be conducted in two phases. Phase I will involve delivering a series of reports outlining the feasibility of the RF component using mathematical models for quantum phenomena. Phase II will require the delivery of a working prototype and a report documenting the prototype's capabilities and any necessary control software. The potential applications of this technology include enhancing the efficacy of security systems that rely on RF detection, minimizing disruptions in police and first responder communications systems caused by RF interference, and improving communication between maritime and aviation vehicles. The project duration is not specified, but the solicitation is open until March 31, 2025. For more information and to submit proposals, interested parties can visit the DOD SBIR website.
DOD SBIR 24.4 Annual - Portable Diamond NV-Based Quantum Magnetometer for Enhanced Detection of Person-Borne Improvised Explosive Devices (PBIEDs)
Active
Department of Defense
The Department of Defense (DOD) is seeking proposals for the development of a portable Diamond Nitrogen-Vacancy (NV) Center-based Quantum Magnetometer for enhanced detection of Person-Borne Improvised Explosive Devices (PBIEDs). Quantum magnetometers utilizing Diamond NV technology offer significant advancements in sensitivity and precision for detecting minor fluctuations in magnetic fields. The magnetometers provide benefits such as exceptional sensitivity, robustness, durability, and non-invasive detection. However, challenges include manufacturing complexity, cost, false positives in metal-rich environments, and limitations in detection range and depth. The solicitation invites proposals for designing a portable Diamond NV-based Quantum Magnetometer that addresses these challenges and demonstrates a thorough understanding of operational contexts. The project will be conducted in three phases: Phase I involves foundational groundwork and design schematics, Phase II focuses on developing a working prototype, and Phase III involves refining the final deployable equipment and procedures. The development of a better magnetometer has the potential to provide significant benefits to numerous programs within the DoD. The deadline for proposal submission is March 31, 2025. For more information, visit the [solicitation link](https://www.sbir.gov/node/2651331).
DOD STTR 24.D Annual - Optical-Atomic System Integration & Calibration (OASIC)
Active
Department of Defense
The Department of Defense (DOD) is seeking proposals for the topic of "Optical-Atomic System Integration & Calibration (OASIC)" as part of the Small Business Innovation Research (SBIR) program. The objective is to create a user facility for an atom-based quantum testbed that can prototype, validate, and benchmark nanophotonic, optoelectronic, and electronic components and sub-systems. The goal is to enable the development of scalable, low-SWaP atom-based quantum sensors, clocks, computing architectures, and other integrated or chip-scale quantum technologies. The solicitation emphasizes the need for rigorous testing and evaluation procedures compatible with the performance requirements of atom-based quantum devices. The Phase I of the project will involve designing and analyzing the performance and operation of the proposed quantum testbed user facility, as well as developing an operation and business plan. The Phase II will focus on constructing and demonstrating the quantum testbed based on the Phase I design. The project duration for Phase II is 24 months. The development of integrated, low-SWaP quantum systems has applications in defense, communications, logistics, exploration, pharmaceuticals, and scientific research. The solicitation encourages the facility to be located at an academic site with a commercial entity responsible for operation and management. The Phase II milestones include reports on component acquisition and fabrication, interim progress reports, and a final report describing the construction and benchmarking of the quantum testbed. The Phase III of the project involves the dual-use applications of the developed quantum systems in both defense and commercial sectors.