Group items matching

in title, tags, annotations or url

MGI recognizes the importance of materials science to the well-being and advancement of society and aims to "deploy advanced materials at least twice as fast as possible today, at a fraction of the cost." DMREF integrates materials discovery, development, property optimization, and systems design and optimization, with each employing a toolset to be developed within a materials innovation infrastructure. The toolset will synergistically integrate advanced computational methods and visual analytics with data-enabled scientific discovery and innovative experimental techniques to revolutionize our approach to materials science and engineering.

The Materials Engineering and Processing (MEP) program supports fundamental research addressing the processing and mechanical performance of engineering Materials by investigating the interrelationship of Materials processing, structure, properties and/or life-cycle performance for targeted applications. Materials processing proposals should focus on manufacturing processes that convert Material into useful form as either intermediate or final composition. These include processes such as extrusion, molding, casting, deposition, sintering and printing.

Centennial Challenges is a program of prize competitions to stimulate innovation in technologies of interest and value to NASA and the nation. The 3DP Habitat Challenge is a prize competition designed to encourage development of new technologies, or application of existing technologies necessary to manufacture an off-world habitat using mission recycled materials and/or local indigenous materials. The goal of the 3D-Printed Habitat Challenge is to foster the development of new technologies necessary to additively manufacture a habitat using local indigenous materials with, or without, recyclable materials.

Centennial Challenges is a program of prize competitions to stimulate innovation in technologies of interest and value to NASA and the nation. The 3DP Habitat Challenge is a prize competition designed to encourage development of new technologies, or application of existing technologies necessary to manufacture an off-world habitat using mission recycled materials and/or local indigenous materials. The goal of the 3D-Printed Habitat Challenge is to foster the development of new technologies necessary to additively manufacture a habitat using local indigenous materials with, or without, recyclable materials.

MGI recognizes the importance of materials science to the well-being and advancement of society and aims to "deploy advanced materials at least twice as fast as possible today, at a fraction of the cost." DMREF integrates materials discovery, development, property optimization, and systems design and optimization, with each employing a toolset to be developed within a materials innovation infrastructure. The toolset will synergistically integrate advanced computational methods and visual analytics with data-enabled scientific discovery and innovative experimental techniques to revolutionize our approach to materials science and engineering.

Research supported by the Division of Materials Research (DMR) focuses on advancing fundamental understanding of Materials, Materials discovery, design, synthesis, characterization, properties, and Materials-related phenomena. DMR awards enable understanding of the electronic, atomic, and molecular structures, mechanisms, and processes that govern nanoscale to macroscale morphology and properties; manipulation and control of these properties; discovery of emerging phenomena of matter

Materials Research Science and Engineering Centers (MRSECs) provide sustained support of interdisciplinary Materials research and education of the highest quality while addressing fundamental problems in science and engineering. MRSECs address research of a scope and complexity requiring the scale, synergy, and interdisciplinarity provided by a campus-based research center. They support Materials research infrastructure in the United States, promote active collaboration between universities and other sectors, including industry and international institutions, and contribute to the development of a national network of university-based centers in Materials research, education, and facilities. A MRSEC may be located at a single institution, or may involve multiple institutions in partnership.

Materials Research Science and Engineering Centers (MRSECs) provide sustained support of interdisciplinary Materials research and education of the highest quality while addressing fundamental problems in science and engineering. MRSECs address research of a scope and complexity requiring the scale, synergy, and interdisciplinarity provided by a campus-based research center. They support Materials research infrastructure in the United States, promote active collaboration between universities and other sectors, including industry and international institutions, and contribute to the development of a national network of university-based centers in Materials research, education, and facilities. A MRSEC may be located at a single institution, or may involve multiple institutions in partnership.

The Electronic and Photonic Materials (EPM) program seeks to advance the field of electronics and photonics through basic, potentially transformative Materials science research. The scope of the program encompasses the discovery and understanding of Materials and Material integration with potential for major technological innovations. 

The Client engages in the development of technologies to enable the permeation or isolation of a target gas from the air in the plant plumbing that contain high-temperature, high-pressure steam and different gasses. The Client has to date developed high-durability polymer materials as well as ceramic and other materials with improved permeability and isolation of target gasses. As the development of relevant materials for a broad range of applications, including gas filter separators and gas barrier materials, is carried out more widely, the Client has decided to make this RFP to further accelerate the development of their research and development endeavors.

This program supports fundamental research including combined experiment and theory projects in ceramics (e.g., oxides, carbides, nitrides and borides), glass-ceramics, inorganic glasses, ceramic-based composites and inorganic carbon-based materials. The objective of the program is to increase fundamental understanding and to develop predictive capabilities for relating synthesis, processing, and microstructure of these materials to their properties and ultimate performance in various environments and applications. Research to enhance or enable the discovery or creation of new ceramic materials is welcome. Development of new experimental techniques or novel approaches to carry out projects is encouraged. Topics supported include basic processes and mechanisms associated with nucleation and growth of thin films; bulk crystal growth; phase transformations and equilibria; morphology; surface modification; corrosion, interfaces and grain boundary structure; and defects. The microstructures investigated range from crystalline, polycrystalline, and amorphous to composite and nanostructured materials. 

Ajinomoto will accept new research proposals related to its core business and research areas from across the globe. Eligible research includes: research relating to the application of Amino acids / Mechanism of food palatability / Measurement of food palatability / Psychological and ethnological approach to food choice / Technology relating to food texture and mouth feel / Nutritional needs, gustatory preference and activity of the aged / Sports science and nutrition / Improvement of malnutrition in the developing countries / Clinical OMICS and biomarkers for cancer diagnostics, personalized medicine and personalized nutrition / Biopharmaceutical manufacturing technology / Materials for regenerative medicine / Metabolic Engineering, Bioinformatics, Synthetic Biology for the Bio-based Materials / Next generation Materials for electronic industry and functional chemicals / Animal nutrition, Plant nutrition, Fish nutrition.

Ajinomoto will accept new research proposals related to its core business and research areas from across the globe. Eligible research includes: research relating to the application of Amino acids / Mechanism of food palatability / Measurement of food palatability / Psychological and ethnological approach to food choice / Technology relating to food texture and mouth feel / Nutritional needs, gustatory preference and activity of the aged / Sports science and nutrition / Improvement of malnutrition in the developing countries / Clinical OMICS and biomarkers for cancer diagnostics, personalized medicine and personalized nutrition / Biopharmaceutical manufacturing technology / Materials for regenerative medicine / Metabolic Engineering, Bioinformatics, Synthetic Biology for the Bio-based Materials / Next generation Materials for electronic industry and functional chemicals / Animal nutrition, Plant nutrition, Fish nutrition.

The Transformational Tools and Technologies (TTT) Project advances state-of-the-art computational and experimental tools and technologies that are vital to aviation applications in the six strategic thrusts. The project develops new computer-based tools, computational fluid dynamics models, and associated scientific knowledge that will provide first-of-a-kind capabilities to analyze, understand, and predict aviation concept performance. These revolutionary tools will be applied to accelerate NASA's research and the community's design and introduction of advanced concepts. The Project also explores technologies that are broadly critical to advancing ARMD strategic outcomes. Such technologies include the understanding of new types of strong and lightweight materials, innovative controls techniques, and experimental methods. The TTT materials and Structures Discipline emphasizes improved multifunctional and high temperature materials for airframe and engine application, as well as integrated multiscale modeling and simulation tool development to improve validated first-principles materials and structural modeling.

Pharmaceutical blister packages often have moisture and oxygen barrier requirements to maintain the efficacy of the drug they contain. Traditional barrier materials used today are PCTFE, EVOH, PVDC, PVC, COC, and combinations thereof. Klockner Pentaplast Films is seeking a thermoformable solution that can be made into blister packs that protects pharmaceuticals from moisture and oxygen. Although the use of glass bottles meets the technical specs of this RFP, studies have shown that compliance to medication instructions increases when patients and consumers use blister packs. The technology must: * Be a material, or a technology that enables the modification of a material, to achieve ALL of the following properties: - Can be made into a thermoformable film - Provides the moisture barrier equivalence of 0.015 g-mil/100 in²-day - Provides an oxygen barrier equivalence of 0.005 cm³-mil/100 in²-day - Be approved (or approvable) for food safety by the FDA - Contains no halogens *Other properties that are highly desired but not required for this application: - Optically clear - Can be recycled in traditional recycling streams - Contains mostly bio-based, natural, or sustainable materials

DMREF will support activities that significantly accelerate materials discovery and development by building the fundamental knowledge base needed to advance the design and development of materials with desirable properties or functionality. This will be accomplished through forming interdisciplinary teams of researchers working synergistically in a "closed loop" fashion, building a vibrant research community, leveraging data science, providing ready access to materials data, and educating the future MGI workforce. Achieving this goal could involve some combination of: strategies to advance materials design through testing methodology; theory, modeling, and simulation to predict behavior or assist in analysis of multidimensional input data; and validation through synthesis, growth, processing, characterization, and/or device demonstration.

The Hazard Mitigation and Structural Engineering (HMSE) program supports fundamental research to mitigate impacts of natural and anthropogenic hazards on civil infrastructure and to advance the reliability, resiliency, and sustainability of buildings and other structures. Hazards considered within the program include earthquake, tsunami, hurricane, tornado and other loads, as well as explosive and impact loading. Resiliency of buildings and other structures include structural and non-structural systems that, in totality, permit continued occupation or operation in case of an impact by a hazard. Research is encouraged that integrates structural and architectural engineering advances with discoveries in other science and engineering fields, such as earth and atmospheric sciences, material science, mechanics of materials, sensor technology, high performance computational modeling and simulation, dynamic system and control, and economics. The program seeks to fund transformative and cost-effective innovations for hazard mitigation of both new and rehabilitated buildings and other structures. Research in structural and architectural engineering is encouraged that extends beyond mature or current construction materials into investigations of smart and sustainable materials and technologies, and considers the structures in their entirety. In addition, the program funds research on structural health monitoring that goes beyond data acquisition to include the holistic system, integrating condition assessment and decision making tools to improve structural performance.

The Hazard Mitigation and Structural Engineering (HMSE) program supports fundamental research to mitigate impacts of natural and anthropogenic hazards on civil infrastructure and to advance the reliability, resiliency, and sustainability of buildings and other structures. Hazards considered within the program include earthquake, tsunami, hurricane, tornado and other loads, as well as explosive and impact loading. Resiliency of buildings and other structures include structural and non-structural systems that, in totality, permit continued occupation or operation in case of an impact by a hazard. Research is encouraged that integrates structural and architectural engineering advances with discoveries in other science and engineering fields, such as earth and atmospheric sciences, material science, mechanics of materials, sensor technology, high performance computational modeling and simulation, dynamic system and control, and economics. The program seeks to fund transformative and cost-effective innovations for hazard mitigation of both new and rehabilitated buildings and other structures. Research in structural and architectural engineering is encouraged that extends beyond mature or current construction materials into investigations of smart and sustainable materials and technologies, and considers the structures in their entirety. In addition, the program funds research on structural health monitoring that goes beyond data acquisition to include the holistic system, integrating condition assessment and decision making tools to improve structural performance

PD 15-1637, Structural and Architectural Engineering (SAE) program replaces Hazard Mitigation and Structural Engineering (HMSE) program. The overall goal of the Structural and Architectural Engineering (SAE) program is to evolve sustainable structures, such as buildings, that can be continuously occupied and /or operational during the structure??s useful life. The SAE program supports fundamental research for advancing knowledge and innovation in structural and architectural engineering that enables holistic approach to design, construction, operation, maintenance, retrofit, repair and end-of-life disposal of structures. For buildings, holistic approach incorporates the foundation-structure-envelope-nonstructural system, as well as the facade and roofing. Research topics of interest for sustainable structures include the following: strategies for structures that over their lifecycle are cost-effective, make efficient use of resources and energy, and incorporate sustainable structural and architectural materials; deterioration due to fatigue and corrosion; serviceability concerns due to large deflections and vibrations; and advances in physics-based computational modeling and simulation. Research is encouraged that integrates discoveries from other science and engineering fields, such as materials science, building science, mechanics of materials, dynamic systems and control, reliability, risk analysis, architecture, economics and human factors. The program also supports research in sustainable and holistic foundation-structure-envelope-nonstructural systems and materials as described in the following reports: ?? National Science and Technology Council, High Performance Buildings; Final Report: Federal R & D Agenda for Net Zero Energy, High-Performance Green Buildings. Building Technology Research and Development (BTRD) Subcommittee, OSTP, U.S. Government, September 2008. http://www.whitehouse.gov/files/documents/ostp/NSTC%20Reports/Federal%20RD%20Agenda%20for%20Net%

The Toyota Material Handling North America (TMHNA) University Research Program is a sponsored research program created to drive the next generation of technology for the Material handling industry. The industry's end-to-end approach to provide complete solutions to customers that are smarter, more efficient and more effective has fueled this program. The mission is to encourage professors and researchers to apply their knowledge of engineering and technical fields, drawing synergies and collaboration between collegiate research and Toyota Material Handling North America.

On the occasion of its 350th anniversary, Merck KGaA, Darmstadt, Germany will fund innovative projects in applied biophysical & analytical research. Projects will be based on the following challenges: · Challenge 1: Analytical technologies for antibodies and antibody-drug conjugates, as well as technologies to determine drug target engagement, or the level of protein or nucleic acid or metabolic biomarkers. · Challenge 2: Analytical technologies for display materials or semiconductors (Liquid Crystals, OLED materials, Quantum materials, Reactive Mesogens, Photoresist materials). E.g. Spectroscopic Methods, MS Hyphenation, Capillary Chromatography and Comprehensive Separation Technologies; Surface analytics for displays (non- or destructive), Sample preparation techniques for ultra-sensitive investigations · Challenge 3: Analytical technologies for the characterization of polymers, chemical imaging, bioanalytical methods or new methods in molecular biology. Technologies of interest for example are: field flow floractionation (FFF), dynamic light scattering (DLS), chemical imaging, new chromatographic techniques, spectroscopic and spectrometric methods, electron paramagnetic resonance (EPR), microwave analytics

The USAFA is seeking unclassified research white papers and proposals that do not contain proprietary information. If proprietary information is submitted it is the offerors' responsibility to mark the relevant portions of their proposal as specified in USAFA-BAA-2015. CAStLE performs a range of structural integrity research tasks in support of multiple Government, academic and commercial sponsors. Among these pursuits, CAStLE engages in a wide range of corrosion engineering and material science research efforts, with more emphasis on applied research, and that part of development not related to a specific system or hardware procurement. Current CAStLE research strengths include: high temperature materials development; advanced barrier coatings; static strength, static stability design, corrosion modeling, prevention and control; validation testing, analysis and methods development; computational structural and fracture mechanics; failure analysis, flight data acquisition system development, installation, maintenance and data analysis; structural risk analysis, and support of the USAF Aircraft Structural Integrity Program (ASIP). The interaction between corrosion and cracking damage mechanisms and their effect on the structural integrity has been a long-standing interest of CAStLE. There is Department of Defense (DoD) level interest in material degradation in structures-to include corrosion, cracking and other service-related damage mechanisms. The DoD level material degradation interest is the subject of this CALL, while also serving a dual public purpose.