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The MME program supports fundamental research leading to improved manufacturing machines and equipment, and their application in manufacturing processes.  Key goals of the program are to advance the transition of manufacturing from skill-based to knowledge-based activities, and to advance technologies that will enable the manufacturing sector to reduce its environmental impacts.  A focus is on the advancement of manufacturing machines and related systems engineering that will enable energy manufacturing, namely the manufacture of facilities and equipment that will enable the conversion of renewable resources into energy products such as electricity and liquid fuels, on a large scale.  The program also supports research on laser processing, joining processes and additive manufacturing machines and processes encompassing feature scales from microns to meters (nanometer scale additive manufacturing is supported under the Nanomanufacturing program).

While geothermal power is an attractive potential source for sustainable energy production, the high heat temperature requirements (typically >150?C) of most geothermal capture systems constrain geographic distribution and economic viability of geothermal energy production. Advancement of strategic material or mineral recovery aims to address this limitation. By partnering with geothermal and mineral industry stakeholders to develop additional revenue streams from brines, the economic viability of geothermal projects will increase while also allowing for increased geographic diversity of this clean, round-the-clock energy source. Rare earths and strategic minerals are essential for modern industry, especially clean-energy technologies, but are subject to supply risk in the face of ever-increasing demand. As an example, consumer uses of lithium batteries have soared over the last decade, powering everything from electric cars to tablets to cell phones. Global demand for lithium carbonate is expected to exceed 250,000 tons by 2017?a 60% increase over current usage. As demand grows in this burgeoning market, a reliable supply of critical materials for advanced manufacturing technologies is a growing concern. This program aims to help alleviate this type of supply bottleneck. The Energy Department seeks up to ten 1-2 year feasibility and/or applied R&D projects that will lead to commercialized technologies. Geothermal mining of rare earth and near-critical metals are the focus of this research, with the intent to effectively lower the cost of geothermal energy production while diversifying and stabilizing the supply of critical materials for domestic industries.

The MME program supports fundamental research leading to improved manufacturing machines and equipment, and their application in manufacturing processes. Key goals of the program are to advance the transition of manufacturing from skill-based to knowledge-based activities, and to advance technologies that will enable the manufacturing sector to reduce its environmental impacts. A focus is on the advancement of manufacturing machines and related systems engineering that will enable energy manufacturing, namely the manufacture of facilities and equipment that will enable the conversion of renewable resources into energy products such as electricity and liquid fuels, on a large scale. The program also supports research on laser processing, joining processes and additive manufacturing machines and processes encompassing feature scales from microns to meters 

The Geospace Section of the Division of Atmospheric and Geospace Sciences, to ensure the health and vitality of solar and space sciences on university teaching faculties, is pleased to offer awards for the creation of new tenure-track faculty positions within the intellectual disciplines which comprise the space sciences. The aim of these awards is to integrate research topics in solar and space physics into basic physics, astronomy, electrical engineering, geoscience, meteorology, computer science, and applied mathematics programs, and to develop space physics graduate programs capable of training the next generation of leaders in this field. Space Science is interdisciplinary in nature and the Faculty Development in the Space Sciences awardees will be expected to establish partnerships within the university community.

DARPA is soliciting innovative research proposals in the field of UV laser technology that will enable enhanced detection and discrimination of specific biological and chemical compounds using Raman spectroscopy. The goal of the Laser UV Sources for Tactical Efficient Raman (LUSTER) program is to develop compact, efficient, high-power ultraviolet lasers capable of achieving output power >1 W, wall-plug efficiency >10%, linewidth < 0.01 nm and all at wavelengths between 220-240 nm. Various methods such as direct electrical injection, electron beam pumping, second harmonic generation or other alternatives will be considered as long as all of the metrics can be met or exceeded. See the full DARPA-BAA-14-20 document attached.

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.Areas of interest include: Functional Materials - materials that possess native properties and functions that can be controlled by external forces such as temperature, light, electric field, pH, etc. These include materials that exhibit properties such as electronic, magnetic, piezoelectric, ferroelectric, photovoltaic, chromogenic, shape memory, thermoelectric or self-healing, etc. Structural Materials - materials that, in service, bear mechanical load. Length scales from nano to meso to macro are of interest as are materials in the bulk or in special configuration such as thin film. These include materials such as metals, polymers, composites, biomaterials, ceramics, hybrids, cement, etc. Materials Processing - processes that convert material into useful form as either intermediate or final composition. These include processes such as extrusion, molding, casting, deposition, sintering, printing, etc. Proposed research should include the consideration of cost, performance, and feasibility of scale-up, as appropriate. Research that addresses multi-scale and/or multi-functional materials systems is encouraged as is research in support of envir

The MME program supports fundamental research leading to improved manufacturing machines and equipment, and their application in manufacturing processes. Key goals of the program are to advance the transition of manufacturing from skill-based to knowledge-based activities, and to advance technologies that will enable the manufacturing sector to reduce its environmental impacts. A focus is on the advancement of manufacturing machines and related systems engineering that will enable energy manufacturing, namely the manufacture of facilities and equipment that will enable the conversion of renewable resources into energy products such as electricity and liquid fuels, on a large scale. The program also supports research on additive manufacturing, laser processing and bonding/joining processes encompassing feature scales from microns to meters. Proposals with focus on materials for these processes are also welcome in MME. Note: nanometer scale additive manufacturing is supported under the Nanomanufacturing program.Investigators wishing to serve on a proposal review panel should email the Program Director with a short biographical sketch, a list of areas of expertise and a link to their home page. REU/RET supplement requests should be submitted by March 31 each year.

The Energy, Power, and Adaptive Systems (EPAS) program invests in the design and analysis of intelligent and adaptive engineering networks, including sensing, imaging, controls, and computational technologies for a variety of application domains. EPAS places emphasis on electric power networks and grids, including generation, transmission and integration of renewable, sustainable and distributed energy systems; high power electronics and drives; and understanding of associated regulatory and economic structures. Topics of interest include alternate energy sources, the Smart Grid, and interdependencies of critical infrastructure in power and communications. The program also places emphasis on energy scavenging and alternative energy technologies, including solar cells, ocean waves, wind, and low-head hydro. In addition, the program supports innovative test beds, and laboratory and curriculum development to integrate research and education.  EPAS invests in adaptive dynamic programming, brain-like networked architectures performing real-time learning, neuromorphic engineering, telerobotics, and systems theory. The program supports distributed control of multi-agent systems with embedded computation for sensor and adaptive networks. EPAS provides additional emphasis on emerging areas, such as quantum systems engineering, quantum and molecular modeling and simulation of devices and systems.

The Division of Materials Research (DMR), the Division of Mathematical Sciences (DMS), the Division of Electrical, Communications and Cyber Systems (ECCS), and the Office of Advanced Cyberinfrastructure (OAC) seek to rapidly accelerate quantum materials design, synthesis, characterization, and translation of fundamental materials engineering and information research for quantum devices, systems, and networks. The new program of Enabling Quantum Leap: Convergent Accelerated Discovery Foundries for Quantum Materials Science, Engineering, and Information (Q-AMASE-i) aims to support these goals by establishing Foundries with mid-scale infrastructure for rapid prototyping and development of quantum materials and devices. The new materials, devices, tools and methods developed by Q-AMASE-i will be shared with the science and engineering communities through a Foundry-operated network. Technology transfer of Foundry activities will be enabled by close cooperation with industrial partners.

The GO Competition is a series of prize challenges to accelerate the development and comprehensive evaluation of grid software solutions. The first GO Competition, Challenge 1, is an algorithm competition focused on the security-constrained optimal power flow (SCOPF) problem for the electric power sector. Awardees under this FOA will be required to participate in Challenge 1. As described in detail in Appendix A1 to this FOA and on the GO Competition website (https://gocompetition.energy.gov/), Challenge 1 is anticipated to launch in the Fall of 2018. Participation in the GO Competition Challenge 1 will be open to anyone that satisfies the applicable requirements in Rules Document specified on the GO Competition website (https://gocompetition.energy.gov/competition-rules), not just those awarded under ARPA-E DE-FOA-0001952. The purpose of this FOA is to provide grants: (i) to further incentivize and identify innovative research for solution methods applicable to Challenge 1, and (ii) to enable broader diversity in team domain expertise, i.e., to encourage teams to participate that do not traditionally focus on the particular problems that are targeted but otherwise have innovative approaches for this class of mathematical programs. While Challenge 1 focuses on a power systems problem, the Challenge and this FOA target a much broader audience (e.g., those specialized in operations research, applied mathematics, optimization methods and algorithms, controls etc.). Existing grid software was designed for a power grid centered on conventional generation and transmission technologies.

Complete information, including the full FOA, can be found on the EERE Exchange website at https://eere-exchange.energy.gov. This Funding Opportunity Announcement (FOA) will fund research that can enable significant reductions in the lifetime costs of power electronics (PE) for solar photovoltaic (PV) energy that align with meeting the SunShot 2030 goals, and likewise enable versatile control functionalities to support grid integration of solar PV for enhanced grid services. Power electronics technology is fundamental for renewable energy systems, and especially for solar PV as the critical link between solar PV arrays and the electric grid. In comparison to the state of the art, the SunShot Initiative seeks to fund early-stage solar PE research projects to enable the following objectives: 1) Lower the lifetime cost of residential, commercial, and utility-scale solar PV inverter/converter solutions; 2) Develop innovative modular, multi-purpose solar PV power electronics designs that offer enhanced services for improved lifetime value and lower grid integration costs.

The Geospace Section of the Division of Atmospheric and Geospace Sciences is pleased to offer awards for the creation of new tenure-track faculty positions within the intellectual disciplines which comprise the space sciences to ensure the health and vitality of solar and space sciences on university teaching faculties. The aim of these awards is to integrate research topics in solar and space physics into basic physics, astronomy, electrical engineering, geoscience, meteorology, computer science, and applied mathematics programs, and to develop space physics graduate programs capable of training the next generation of leaders in this field. Space Science is interdisciplinary in nature and the Faculty Development in the Space Sciences awardees will be expected to establish partnerships within the university community.  NSF funding will support the entire academic year salary and benefits of the newly recruited tenure-track faculty member for a duration of up to five years with a total award amount not to exceed $1,500,000.

* interfacial plasma (i.e., low temperature plasma coming into contact with liquid to produce new chemical reactivity through a gas-liquid interface); * interaction of plasma with biomaterials (e.g., understanding how plasma-produced chemical reactivity is delivered through multiple interfaces, such as liquid, cells, tissue, polymers); * control of plasma-electromagnetic interaction (e.g., fundamental understanding of how radio-frequency electromagnetic power produces controllable plasmas to enable microelectronics processing); * Plasma catalysis (e.g., understanding the plasma reactivity and catalyst selectivity); * Plasma aided combustion (e.g., control of pulsed plasmas to improve the efficiency of chemical processing); * Interface between plasma and solid-state physics (e.g., understanding the boundary layer between plasma and solid-state surface); * Coherent structures (e.g., understanding electric self-organization in low temperature plasmas); * Other emerging areas such as plasma aided aeronautics, plasma process control through machine learning, etc.

The mission of the DOE FE Solid Oxide Fuel Cell (SOFC) program is to enable the efficient generation of low-cost electricity for (a) 2nd Generation natural gas-fueled SOFC DG systems and modular, coal-fueled systems and (b) Transformational coal or natural gas-fueled utility-scale systems with carbon capture and sequestration (CCS). The program supports the overarching goals of the Clean Coal and Carbon Management Research Program (CCCMRP) through the collaboration between the R&D that addresses the technical and economic barriers to commercial viability and the development and deployment of SOFC power systems that validate those solutions.

The Department of Energys (DOEs) National Energy Technology Laboratory (NETL) on behalf of the Office of Electricity Delivery and Energy Reliability (OE) Cybersecurity for Energy Delivery Systems (CEDS) Research and Development (R&D) program is seeking applications under this Funding Opportunity Announcement (Announcement) to conduct research, development and demonstrations (RD&D) for innovative approaches to advance cyber resilient energy delivery systems. This RD&D will lead to next generation tools and technologies that are not available today that will become widely adopted throughout the energy sector to reduce the risk that a cyber incident could disrupt energy delivery.

The Geotechnical Engineering and Materials Program (GEM) supports fundamental research in soil and rock mechanics and dynamics in support of physical civil infrastructure systems. Also supported is research on improvement of the engineering properties of geologic materials for infrastructure use by mechanical, biological, thermal, chemical, and electrical processes. The Program supports the traditional areas of foundation engineering, earth structures, underground construction, tunneling, geoenvironmental engineering, and site characterization, as well as the emerging area of bio-geo engineering, for civil engineering applications, with emphasis on sustainable geosystems. Research related to the geotechnical engineering aspects of geothermal energy and geothermal heat pump systems is also supported. The GEM program encourages knowledge dissemination and technology transfer activities that can lead to broader societal benefit and implementation for provision of physical civil infrastructure. The Program also encourages research that explores and builds upon advanced computing techniques and tools to enable major advances in Geotechnical Engineering.

The Office of Naval Research (ONR) is interested in receiving white papers and proposals in support of advancing high temperature superconducting wire technology for future naval applications. Work under this program will consist of basic and applied research, and it will be funded under Budget Activity 1 and 2 (as defined in DoD Financial Management Regulation Vol. 2B, Ch. 5). The overall S&T effort is envisioned to be conducted at the TRL 1-3 stage. The overall objective of this program is to advance the state of art characteristics of high temperature superconductors to support applications demanding power delivery, pulsed current delivery, AC and DC magnetic fields, and magnetic energy storage. Interested parties are welcome to propose against one or more topics listed below. Topic Area 1: Superconducting Materials Topic Area 2: Superconducting Tape Processing and Modification Topic Area 3: Superconductors for Novel Applications Topic Area 4: Superconducting State Protections The research opportunity described in this announcement falls under the FY 18 Long Range BAA, Appendix 1, Section IV, entitled "Sea Warfare and Weapons Department (Code 33)," for the following specific thrusts and focused research areas: (1) Paragraph A "Ship Systems and Engineering Research," subparagraph 3, entitled "Electrical and Thermal Systems" and (2) Paragraph D "Naval Energy Resiliency and Sustainability."

The Solutions Project unites science, business, culture, and community to accelerate the transition towards 100% clean, renewable energy for all people and purposes. The Solutions Project's Fighter Fund is a rapid response grantmaking program that provides support to pivotal frontline leaders accelerating the transition to clean energy in the United States. The Fund's interest areas include the following: state policy campaigns supporting 100% clean energy for 100% of the people; fossil fuel infrastructure resistance; indigenous organizing and indigenous led movements; supporting transparent, cleaner, and democratically controlled rural electric cooperatives; and community-owned clean energy demonstration projects in need of seed capital. Nonprofit organizations throughout the United States are eligible to apply for grants ranging from $500 to $25,000. Requests will be reviewed on a rolling basis throughout 2018. Visit The Solutions Project website to learn more about the Fighter Fund.

The U.S. Army Research Office (ARO) in partnership with the Intelligence Advanced Research Projects Activity (IARPA) seeks research and development of technology and techniques for energy-efficient, high data rate transmission of digital signals between computing systems operating at room and cryogenic temperatures. The focus in the SuperCables program is research and demonstration of components to convert from low level electrical signals in circuits operating at a temperature of approximately 4 kelvins to conventional optical signals at room temperature and to move the information therein from one environment to the other. Pending results of this program, IARPA may support a follow-on program to develop the complete system for bidirectional data transmission between room temperature and 4 kelvins.

The Biosensing program is part of the Engineering Biology and Health cluster, which also includes 1) the Biophotonics program; 2) the Cellular and Biochemical Engineering program; 3) the Disability and Rehabilitation Engineering program; and 4) the Engineering of Biomedical Systems program. The Biosensing program supports fundamental engineering research on devices and methods for measurement and quantification of biological analytes. Examples of biosensors include, but are not limited to, electrochemical/electrical biosensors, optical biosensors, plasmonic biosensors, and paper-based and nanopore-based biosensors. In addition to advancing biosensor technology development, proposals that address critical needs in biomedical research, public health, food safety, agriculture, forensic, environmental protection, and homeland security are highly encouraged. Proposals that incorporate emerging nanotechnology methods are especially encouraged.