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NineSigma, representing a Global Leader in medical devices, invites proposals for technologies that can create micron scale structures on metal surfaces. The challenge is to obtain a robust micropatterned surface with a high aspect ratio that can maintain the surface characteristics in a high pressure, high temperature environment.  The approach must be applicable to curved (non planar) metal surfaces. Microstructures on the surfaces of medical devices have many advantages for the various medical application. Surface patterning imparts critical functional features to the device, such as anti-fouling, hydrophobicity, adhesion, etc. The RFP sponsor is seeking innovations that allow creating precise microstructured patterns on non-planar metal surfaces.

Imaging systems are commonly used for conducting pavement evaluations. AASHTO Standard Practice for Collecting Images of Pavement Surfaces for Distress Detection (AASHTO Designation: PP 68) addresses the collection of images. However, there are no widely accepted methods for measuring the characteristics of pavement surface images (such as 2-dimensional optical images and 3-dimensional surface elevation images). There are also no widely accepted AASHTO standard practices for the calibration, certification, and verification of such images. Research is needed to identify the characteristics of surface images that are essential for pavement evaluation and develop methods for measuring these characteristics, and also to develop recommended standard practices for implementing these methods. This information will help highway agencies better evaluate image data collection systems and improve the process of pavement condition evaluation. The objectives of this research are to (1) identify and develop methods for measuring the characteristics of surface images used for pavement evaluation and analysis; and (2) develop recommended standard practices for the calibration, certification, and verification of such images, for consideration and adoption by AASHT

The Geobiology and Low-Temperature Geochemistry Program focuses on geochemical processes in terrestrial Earth's surface environmental systems, as well as the interaction of geochemical and biological processes. The program supports field, laboratory, theoretical, and modeling studies of these processes and related mechanisms at all spatial and temporal scales. Studies may address: 1) inorganic and/or organic geochemical processes occurring at or near the Earth's surface now and in the past, and across the broad spectrum of interfaces ranging in scale from planetary and regional to mineral-surface and supramolecular; 2) the role of life in the transformation and evolution of Earth's geochemical cycles; 3) surficial chemical and biogeochemical systems and cycles, including their modification through environmental change and human activities; 4) low-temperature aqueous geochemical processes; 5) mineralogy and chemistry of earth materials; 6) geomicrobiology and biomineralization processes; and 7) medical mineralogy and geochemistry. The Program encourages research that focuses on geochemical processes as they are coupled with physical and biological processes in the critical zone. The Program also supports work on the development of tools, methods, and models for the advancement of low-temperature geochemistry and geobiology. The Geobiology and Low-Temperature Geochemistry Program is interested in supporting transformational and cutting-edge research. The Program is highly interdisciplinary and interfaces with other programs within the Earth Surface Section and with programs in biology, chemistry and engineering.

The Macromolecular, Supramolecular and Nanochemistry (MSN) Program focuses on basic research that addresses fundamental questions regarding the chemistry of macromolecular, supramolecular and nanoscopic species and other organized structures and that advances chemistry knowledge in these areas.  Research of interest to this program will explore novel chemistry concepts in the following topics: (1) The development of novel synthetic approaches to clusters, nanoparticles, polymers, and supramolecular architectures; innovative surface functionalization methodologies; surface monolayer chemistry; and template-directed synthesis.  (2) The study of molecular-scale interactions that give rise to macromolecular, supramolecular or nanoparticulate self-assembly into discrete structures; and the study of chemical forces and dynamics that are responsible for spatial organization in discrete organic, inorganic, or hybrid systems (excluding extended solids).  (3) Investigations that utilize advanced experimental or computational methods to understand or to predict the chemical structure, unique chemical and physicochemical properties, and chemical reactivities that result from the organized or nanoscopic structures.  Research in which theory advances experiment and experiment advances theory synergistically is of special interest.

The Macromolecular, Supramolecular and Nanochemistry (MSN) Program focuses on basic research that addresses fundamental questions regarding the chemistry of macromolecular, supramolecular and nanoscopic species and other organized structures and that advances chemistry knowledge in these areas.  Research of interest to this program will explore novel chemistry concepts in the following topics: (1) The development of novel synthetic approaches to clusters, nanoparticles, polymers, and supramolecular architectures; innovative surface functionalization methodologies; surface monolayer chemistry; and template-directed synthesis.  (2) The study of molecular-scale interactions that give rise to macromolecular, supramolecular or nanoparticulate self-assembly into discrete structures; and the study of chemical forces and dynamics that are responsible for spatial organization in discrete organic, inorganic, or hybrid systems (excluding extended solids).  (3) Investigations that utilize advanced experimental or computational methods to understand or to predict the chemical structure, unique chemical and physicochemical properties, and chemical reactivities that result from the organized or nanoscopic structures.  Research in which theory advances experiment and experiment advances theory synergistically is of special interest.

Effective September 1, 2013, the Materials Engineering and Processing Program (MEP) (PD 13-8092) will be accepting proposals that address engineering principles as they relate to material processing and performance. This program replaces the Materials Processing and Manufacturing (MPM), Materials and Surface Engineering (MSE), and Structural Mechanics and Materials (SMM) programs. This new MEP program is effectively a merger and evolutionary advance of these three programs. The MPM, MSE and SMM programs will no longer be accepting new proposals1. The Division of Civil, Mechanical, and Manufacturing Innovation (CMM) in Directorate for Engineering (ENG) of the National Science Foundation (NSF) created the Materials Engineering and Processing (MEP) program to support fundamental research addressing the interrelationship of materials processing, structure, properties and/or life-cycle performance for targeted applications. Processing and performance of all material systems are of interest. These include polymers, metals, ceramics, semiconductors, composites, and hybrids thereof. Research driven by scientific hypotheses are encouraged when suitable, and materials in bulk form or focus on special zones such as surfaces or interfaces that are to be used in structural and/or functional applications are appropriate for this program. Analytical, experimental, and numerical studies are supported and collaborative proposals with industry (i.e. Grant Opportunities for Academic Liaison with Industry (GOALI)) are encouraged.

The objective of the Aircraft Drag Reduction Program will be to mature and transition technologies to reduce the fuel burn of legacy and future fleet aircraft by employing engineered surfaces, materials, and coatings (ESMC). Aircraft drag reduction by means of ESMC may address any element of aircraft drag. This Research and Development (R&D) may include, aircraft drag reduction technologies, especially turbulent boundary layer skin friction drag reduction; evaluating the performance (drag reduction) of the technologies - tests ranging from laboratory testing of ESMC coupons, to wind tunnel testing (small- to large-scale), to flight testing of ESMC technologies; and maturing and transitioning technologies to aircraft, to include qualification testing of new coatings, materials, or surfaces.

A thin, formable, and tunable light source that can be formed under a decorative surface material to illuminate the printed graphic image on the decorative surface

Yanfeng Automotive seeks interiors that have the ability to resist dirt/dust/oil accumulation. The Interior surface must always appear to be clean and must appear to be easy to clean.

The objective of this Funding Opportunity Announcement is to solicit and competitively seek applications for the development of tools and methods needed to improve the measurement and reduce the uncertainty in the measurement of in-situ maximum principal stress in the deep surface and understand and predict the geomechanical impact of pressure migration due to injection on the storage complex including the underburden and basement formations. The Areas of Interest of this Announcement are Tools and Methods for Determining Maximum Principal Stress in the Deep Surface and Methods for Understanding Impact of Vertical Pressure Migration due to Injection on State of Subsurface Stress.

NineSigma, representing a Global Manufacturer, invites proposals for materials, coatings, chemicals or additives that will clearly identify where a surface has been in contact with or otherwise disrupted by external sources.

NineSigma, representing a global metal engineering company invites responses from experts, SMEs or organisations for technologies or materials to provide an Open 3D Surface Structure for a (coated) Copper Mold.

The Materials Engineering and Processing (MEP) program supports fundamental research addressing the interrelationship of materials processing, structure, properties and/or life-cycle performance for targeted applications. Research proposals should be driven by the performance or output of the material system relative to the targeted application(s). Research plans driven by scientific hypotheses are encouraged when suitable. Materials in bulk form or focus on special zones such as surfaces or interfaces that are to be used in structural and/or functional applications are appropriate. All material systems are of interest including polymers, metals, ceramics, semiconductors, composites and hybrids thereof. Analytical, experimental, and numerical studies are supported and collaborative proposals with industry (GOALI) are encouraged.

The objective of this effort will be to produce a package of "Marinized" materials upgrades to be used in United States Navy surface ship gas turbines for propulsion or auxiliary power systems that will enable longer hot section lives at current operating temperatures and/or  higher temperature operations with sustained engine life in marine service.

The USDOT seeks to develop, evaluate, and test vehicle-to-infrastructure (V2I) applications for the light vehicle fleet that are intended to transform surface transportation safety, mobility, and environmental performance through a connected vehicle environment. These efforts are outlined in RITA's ITS Strategic Research Plan, 2010-2014. The FHWA has a lead role in the selection, development, and testing of the applications. V2I applications are those applications wherein vehicle-based sensors and vehicle-to-vehicle (V2V) communications are not considered adequate for development of information, alerts, or warnings for drivers. Rather, additional information is required from the infrastructure in order to enable the applications. These applications, however, are vehicle-based, in that they are programs resident in the on-board equipment of the vehicle. The on-board systems use information from vehicle-based sensors, V2V communications, and V2I communications to determine if information, alerts, or warnings should be provided to the driver. Automobile manufacturers (OEMs) are critical partners in development of vehicle-based applications and processes. The Crash Avoidance Metrics Partnership (CAMP) partnership was formed between Ford Motor Company and General Motors to accelerate development and implementation of crash avoidance countermeasures in light vehicles to improve traffic safety. The CAMP partnership forms a consortium of all OEMs that desire to cooperatively work together and with the USDOT on specific research areas, such as V2I applications. This cooperative agreement is with CAMP and is intended to facilitate the selection, development, and evaluation of V2I safety, mobility and environmental applications, and to conduct other Connected Vehicle program work that involves communications between vehicles, infrastructure, and pedestrians and bicyclists.

This ROSES NRA (NNH16ZDA001N) solicits basic and applied research in support of NASA's Science Mission Directorate (SMD). This NRA covers all aspects of basic and applied supporting research and technology in space and Earth sciences, including, but not limited to: theory, modeling, and analysis of SMD science data; aircraft, scientific balloon, sounding rocket, International Space Station, CubeSat and suborbital reusable launch vehicle investigations; development of experiment techniques suitable for future SMD space missions; development of concepts for future SMD space missions; development of advanced technologies relevant to SMD missions; development of techniques for and the laboratory analysis of both extraterrestrial samples returned by spacecraft, as well as terrestrial samples that support or otherwise help verify observations from SMD Earth system science missions; determination of atomic and composition parameters needed to analyze space data, as well as returned samples from the Earth or space; Earth surface observations and field campaigns that support SMD science missions; development of integrated Earth system models; development of systems for applying Earth science research data to societal needs; and development of applied information systems applicable to SMD objectives and data

This program supports fundamental scientific research in ceramics (e.g., oxides, carbides, nitrides and borides), glass-ceramics, inorganic glasses, ceramic-based composites and inorganic carbon-based materials. Projects should be centered on experiments; inclusion of computational and theory components are encouraged. 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. Additional Information Eligibility rules apply for submissions; please see the Program Description section of the CER solicitation for details. PIs are encouraged to include all anticipated broader impact activities in their initial proposals, rather than planning on supplemental requests. Most projects include: (1) the anticipated significance on science, engineering and/or technology including possible benefits to society, (2) plans for the dissemination, and (3) broadening participation of underrepresented groups and/or excellence in training, mentoring, and/or teaching. Many successful proposals include one additional broader impact activity.

The Geophysics Program supports basic research in the physics of the solid earth to explore its composition, structure, and processes from the Earth's surface to its' deepest interior. Laboratory, field, theoretical, and computational studies are supported. Topics include (but are not limited to) seismicity, seismic wave propagation, and the nature and occurrence of geophysical hazards; the Earth's magnetic, gravity, and electrical fields; the Earth's thermal structure; and geodynamics. Supported research also includes geophysical studies of active deformation, including geodesy, and theoretical and experimental studies of the properties and behavior of Earth materials.

This ROSES NRA (NNH17ZDA001N) solicits basic and applied research in support of NASA's Science Mission Directorate (SMD). The NRA covers all aspects of basic and applied supporting research and technology in space and Earth sciences, including, but not limited to: theory, modeling, and analysis of SMD science data; aircraft, scientific balloon, sounding rocket, International Space Station, CubeSat and suborbital reusable launch vehicle investigations; development of experiment techniques suitable for future SMD space missions; development of concepts for future SMD space missions; development of advanced technologies relevant to SMD missions; development of techniques for and the laboratory analysis of both extraterrestrial samples returned by spacecraft, as well as terrestrial samples that support or otherwise help verify observations from SMD Earth system science missions; determination of atomic and composition parameters needed to analyze space data, as well as returned samples from the Earth or space; Earth surface observations and field campaigns that support SMD science missions; development of integrated Earth system models; development of systems for applying Earth science research data to societal needs; and development of applied information systems applicable to SMD objectives and data.

The Process and Reaction Engineering program supports fundamental and applied research on: Rates and mechanisms of important classes of catalyzed and uncatalyzed chemical reactions as they relate to the design, production, and application of catalysts, chemical processes, biochemical processes, and specialized materials Chemical and biochemical phenomena occurring at or near solid surfaces and interfaces Electrochemical and photochemical processes of engineering significance or with commercial potential Design and optimization of complex chemical and biochemical processes Dynamic modeling and control of process systems and individual process units Reactive processing of polymers, ceramics, and thin films Interactions between chemical reactions and transport processes in reactive systems, and the use of this information in the design of complex chemical and biochemical reactors  Recent emphasis on the development of sustainable energy technologies means that the support of projects on the processing aspects of chemical systems that further such technologies have high priority when funding decisions are made. Areas that focus on reactors of all types - fuel cells, batteries, microreactors, biochemical reactors, etc.; reactor design in general; and design and control of all systems associated with energy from renewable sources, have high priority for funding.

The Process and Reaction Engineering program supports fundamental and applied research on: Rates and mechanisms of important classes of catalyzed and uncatalyzed chemical reactions as they relate to the design, production, and application of catalysts, chemical processes, biochemical processes, and specialized materials Chemical and biochemical phenomena occurring at or near solid surfaces and interfaces Electrochemical and photochemical processes of engineering significance or with commercial potential Design and optimization of complex chemical and biochemical processes Dynamic modeling and control of process systems and individual process units Reactive processing of polymers, ceramics, and thin films Interactions between chemical reactions and transport processes in reactive systems, and the use of this information in the design of complex chemical and biochemical reactors  Recent emphasis on the development of sustainable energy technologies means that the support of projects on the processing aspects of chemical systems that further such technologies have high priority when funding decisions are made. Areas that focus on reactors of all types - fuel cells, batteries, microreactors, biochemical reactors, etc.; reactor design in general; and design and control of all systems associated with energy from renewable sources, have high priority for funding.