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The intent of this Department of Energy, National Energy Technology Laboratory funding opportunity announcement is to solicit applications for selection and award in FY 2014 that focus on the following technical topic areas (1) gas hydrate reservoir-response field experiments in Alaska and (2) field programs for marine gas hydrate characterization. These projects will support program goals and represent a critical component of advancing several of the specific mandates previously established for the Methane Hydrate Program under the Methane Hydrate Act of 2000 (as amended by Section 968 of the Energy Policy Act of 2005).

he Electrochemical Systems program is part of the Chemical Process Systems cluster, which includes also 1) Catalysis; 2) Molecular Separations; and 3) Process Systems, Reaction Engineering, and Molecular Thermodynamics. The goal of the Electrochemical Systems program is to support fundamental engineering research that will enable innovative processes involving electro- or photochemistry for the sustainable production of electricity, fuels, and chemicals. Processes for sustainable energy and chemical production must be scalable, environmentally benign, reduce greenhouse gas production, and utilize renewable resources. Research projects that stress fundamental understanding of phenomena that directly impact key barriers to improved system or component-level performance (e.g., energy efficiency, product yield, process intensification) are encouraged. Processes for energy storage should address fundamental research barriers for the applications of renewable electricity storage or for transport propulsion

The purpose of this Request for Information is to seek information from power generation equipment manufacturers, utilities, power plant architect-engineers, and other stakeholders that can be used as input to a Department of Energy Fossil Energy Research and Development program that will culminate in the design, construction, and operation of a coal-based pilot-scale power plant by 2025. The coal-based pilot plant will be used as the basis for scaling up to a commercial offering that is highly efficient (40 percent or greater higher heating value), modular (unit sizes of approximately 50 to 350 MW), and economical for both international and domestic power generation. The pilot plant and commercial offering does not have to capture and store carbon dioxide, but must be carbon capture ready. This is solely a request for information and is not a Funding Opportunity Announcement. U.S. Department of Energy is not accepting applications to this Request for Information.

The Catalysis program is part of the Chemical Process Systems cluster, which also includes: 1) the Electrochemical Systems program; 2) the Interfacial Engineering program; and 3) the Process Systems, Reaction Engineering, and Molecular Thermodynamics program. The goals of the Catalysis program are to increase fundamental understanding in catalytic engineering science and to advance the development of catalytic materials and reactions that are beneficial to society. Research in this program should focus on new concepts for catalytic materials and reactions, utilizing synthetic, theoretical, and experimental approaches. Target applications include fuels, specialty and bulk chemicals, environmental catalysis, biomass conversion to fuels and chemicals, conversion of greenhouse gases, and generation of solar hydrogen, as well as efficient routes to energy utilization. Heterogeneous catalysis represents the main thrust of the program. Proposals related to both gas-solid and liquid-solid heterogeneous catalysis are welcome, as are proposals that incorporate concepts from homogeneous catalysis. Topic areas that are of particular interest include: · Renewable energy-related catalysis with applications in electrocatalysis, photocatalysis, and catalytic conversion of biomass-derived chemicals. Catalysis aimed at closing the carbon cycle (especially conversion of CO2, methane, and natural gas to fuels and chemical intermediates). · Catalytic alternatives to traditionally non-catalytic reaction processes, as well as new catalyst designs for established catalytic processes. · Environmental catalysis (including energy-efficient and green routes to fuels and chemicals). ·

The goal of the Combustion and Fire Systems program is to generate cleaner global and local environments, enhance public safety, improve energy and homeland security, and enable more efficient energy conversion and manufacturing. 

The Office of Basic Energy Sciences (BES), U.S. Department of Energy (DOE), announces its interest in receiving applications from small collaborative groups of investigators for support of combined experimental and theoretical efforts to advance ultrafast chemical and materials science. 

Due to the ubiquitous presence of catalysis in the many aspects of goods and services impacting our lives, the Catalysis and Biocatalysis program has many potential directions for funding support.  Programs in this area encompass a blend of fundamental and innovative applied research drivers.  All programs are hypothesis-driven, and the experimental programs aimed at resolving the issues frequently combine a variety of approaches.  Chemical engineering and chemistry are intertwined.  Proposals which receive funding in this Program may include any number of the following broad scopes: Catalyst Synthesis, Characterization, Behavior and Performance Kinetics and Mechanisms of Key Catalytic Reactions Catalysis at Surfaces or in Reactor Process Streams Synthesis and Fabrication of Component Materials and Catalyst Composites Modeling and Fundamental Studies of a Catalyst or Catalytic Process Catalysts and Studies for Renewable Energy Systems. These approaches apply equally to classical inorganic or carbon catalysts as well as to enzymatic or biocatalysts.  Specialized materials synthesis procedures may be necessary to provide active catalysts in any of the studies.  Applications-driven studies, such as Biomass conversion catalysis, Electrocatalysis and Photocatalysis, involving energy interconversion devices or systems employing catalysts are highly desired.

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 Chemical Catalysis Program supports experimental and theoretical research directed towards the fundamental understanding of the chemistry of catalytic processes at the molecular level.  The Program accepts proposals on catalytic approaches, which facilitate, direct, and accelerate efficient chemical transformations.  This includes the design and synthesis of catalytic species on the molecular, supramolecular, and nanometer scales as well as studies of the dynamics of homogeneous and heterogeneous catalytic processes.  Processes of interest include (but are not limited to): polymerization catalysis, single site catalysis, and biologically-inspired catalysis.  Applications of modeling, theory, and simulation to catalytic processes are also relevant.  Fundamental studies of energy-related catalytic processes, CO2 conversion, electrocatalysis (such as in water splitting and fuel cells), and photocatalysis (such as in solar energy conversion) are welcome in the program.

The Chemical Catalysis Program supports experimental and theoretical research directed towards the fundamental understanding of the chemistry of catalytic processes at the molecular level. The Program accepts proposals on catalytic approaches which facilitate, direct, and accelerate efficient chemical transformations. This includes the design and synthesis of catalytic and pre-catalytic species on the molecular, supramolecular, and nanometer scales; and studies of the dynamics of homogeneous and heterogeneous catalytic processes. Processes of interest include (but are not limited to) polymerization catalysis, single site catalysis, asymmetric catalysis, and biologically-inspired catalysis. Applications of modeling, theory, and simulation to catalytic processes are also relevant. Submissions that advance chemical catalysis and address national needs for sustainability are of particular interest. These include fundamental studies of energy-related catalytic processes, CO2 conversion, electrocatalysis (such as in water splitting and fuel cells), photocatalysis (such as in solar energy conversion), catalytic conversions of fossil fuels and biomass, and environmentally-friendly chemical processes.The Program does not support applied catalysis research that focuses on scale-up, processing, transport dynamics, long-term stability and other engineering aspects of catalysis. The Program also does not support biocatalysis research with purely biological enzymes and cellular systems.

SBR is part of the Environmental System Science (ESS) activity within the Climate and Environmental Sciences Division (CESD) of BER. The CESD mission is to enhance the seasonal to multi-decadal predictability of the Earth system by using long-term field experiments, DOE user facilities, modeling and simulation, uncertainty characterization, best-in-class computing, process research, and data analytics and management to inform the development of advanced solutions to the nation's energy challenges. The 2018 CESD Strategic Plan identifies five scientific grand challenges and associated research questions that will be addressed through the research programs and User Facilities within the division over the next five years (https://science.energy.gov/~/media/ber/pdf/workshop%20reports/2018_CESD_Strategic_Plan.pdf)

The mission of DOE's Fossil Energy R&D Program is to ensure the nation can continue to rely on traditional resources for clean, secure and affordable energy while enhancing environmental protection. The Carbon Capture program focuses on developing technologies to control emissions from either post-combustion units (e.g., pulverized coal) or pre-combustion (e.g., Integrated Gasification Combined Cycle, or IGCC). First Generation technologies (i.e. those that are currently being demonstrated or that are commercially available) exist, and Second Generation Technologies (i.e., those that include technology components currently in R&D and are expected to be ready for demonstration in the 2020-2025 timeframe) have shown potential for improvement towards an economic goal for cost of capture at less than $40/tonne, but are still cost prohibitive for broad deployment to the existing coal fleet. For Fiscal Year (FY) 2018, the Carbon Capture Program will solicit applications under this FOA to develop technologies in the area of pre-combustion carbon capture. Approaches that look at either hydrogen (H2) separation or carbon dioxide (CO2) separation will be accepted. The carbon capture technologies developed through this FOA will have direct application to coal gasification processes where coal derived synthesis gas or hydrogen are produced. Additionally, because gasification technology is often used to produce industrial chemicals, the technologies developed through this FOA will also be directly applicable to industrial gasifiers.

The Office of Basic Energy Sciences (BES), U.S. Department of Energy (DOE), announces its interest in receiving applications from small groups of investigators for support of experimental and theoretical efforts to advance ultrafast chemical and materials sciences that utilize x-ray free electron lasers.

The Office of Basic Energy Sciences (BES), U.S. Department of Energy (DOE), announces its interest in receiving applications from single investigator or small groups of investigators for support of experimental and theoretical efforts to advance materials and chemical sciences research for quantum information sciences (QIS).

This Funding Opportunity Announcement (FOA) supports the research and development of key early-stage technical challenges for fuel cells and for hydrogen fuel production, delivery and storage, and will leverage the private sector to address institutional barriers that impact progress in the field. The goal of this research activity is to provide affordable, clean, safe, and reliable energy from diverse domestic resources, providing the benefits of increased energy security and reduced emissions through early-stage research and development. The global fuel cell market increased its growth 40% in 2016, with revenues of over $1.6 billion in 2016 and over 20,000 fuel cell units for material handling equipment purchased in the U.S. alone since 2009. Light duty vehicles are an emerging application for fuel cells that has earned substantial commercial and government interest worldwide due to the superior efficiencies, reductions in petroleum consumption, and reductions in criteria pollutants fuel cells make possible.

In 2010, NSF established the Science, Engineering, and Education for Sustainability (SEES)1 investment area to lay the research foundation for decision capabilities and technologies aimed at mitigating and adapting to environmental changes that threaten sustainability. Some SEES investments advanced a systems-based approach to understanding, predicting, and reacting to stress upon, and changes in, the linked natural, social, and built environments. In this context, the importance of understanding the interconnected and interdependent systems involving food, energy, and water (FEW) has emerged. The NSF aims to specifically focus on advancing knowledge of the nitrogen and phosphorus cycles; the production and use of fertilizers for food production; and the detection, separation, and reclamation/recycling of nitrogen- and phosphorus-containing species in and from complex aqueous environments.

In 2010, NSF established the Science, Engineering, and Education for Sustainability (SEES)1 investment area to lay the research foundation for decision capabilities and technologies aimed at mitigating and adapting to environmental changes that threaten sustainability. Some SEES investments advanced a systems-based approach to understanding, predicting, and reacting to stress upon, and changes in, the linked natural, social, and built environments. In this context, the importance of understanding the interconnected and interdependent systems involving food, energy, and water (FEW) has emerged. The NSF aims to specifically focus on advancing knowledge of the nitrogen and phosphorus cycles; the production and use of fertilizers for food production; and the detection, separation, and reclamation/recycling of nitrogen- and phosphorus-containing species in and from complex aqueous environments.

The mission of DOE's Fossil Energy R&D Program is to ensure the nation can continue to rely on traditional resources for clean, secure and affordable energy while enhancing environmental protection. The Carbon Capture program focuses on developing technologies to control emissions from either post-combustion units (e.g., pulverized coal) or pre-combustion (e.g., Integrated Gasification Combined Cycle, or IGCC). First Generation technologies (i.e. those that are currently being demonstrated or that are commercially available) exist, and Second Generation Technologies (i.e., those that include technology components currently in R&D and are expected to be ready for demonstration in the 2020-2025 timeframe) have shown potential for improvement towards an economic goal for cost of capture at less than $40/tonne, but are still cost prohibitive for broad deployment to the existing coal fleet. For Fiscal Year (FY) 2018, the Carbon Capture Program will solicit applications under this FOA to develop technologies in the area of pre-combustion carbon capture. Approaches that look at either hydrogen (H2) separation or carbon dioxide (CO2) separation will be accepted. The carbon capture technologies developed through this FOA will have direct application to coal gasification processes where coal derived synthesis gas or hydrogen are produced. Additionally, because gasification technology is often used to produce industrial chemicals, the technologies developed through this FOA will also be directly applicable to industrial gasifiers. Finally, as these technologies are successfully developed, they can represent an export opportunity to other countries that have a larger installed base of gasifiers than the U.S.

The Process Separations program is part of the Chemical Process Systems cluster, which includes also 1) Catalysis; 2) Process Systems, Reaction Engineering, and Molecular Thermodynamics; and 3) Energy for Sustainability. The Process Separations program supports research focused on novel methods and materials for separation processes, such as those central to the chemical, biochemical, bioprocessing, materials, energy, and pharmaceutical industries. A fundamental understanding of the interfacial, transport, and thermodynamic behavior of multiphase chemical systems as well as quantitative descriptions of processing characteristics in the process-oriented industries is critical for efficient resource management and effective environmental protection. The program encourages proposals that address long standing challenges and emerging research areas and technologies, have a high degree of interdisciplinary work coupled with the generation of fundamental knowledge, and the integration of education and research. Research topics of particular interest include fundamental molecular-level work on: Design of scalable mass separating agents and/or a mechanistic understanding of the interfacial thermodynamics and transport phenomena that relate to purification of gases, chemicals, or water

Request for Information - Upgrading Carbon Derived from Methane Pyrolysis This is a Request for Information (RFI) only. This RFI is not accepting application for financial assistance. The purpose of this RFI is solely to solicit input for ARPA-E consideration to inform the possible formulation of future programs. The Advanced Research Projects Agency -Energy (ARPA-E) in the US Department of Energy is seeking information concerning technologies to produce hydrogen and elemental carbon from the thermal decomposition of methane (also known as methane pyrolysis, methane cracking, or methane splitting). Recognizing that the value of the carbon product would be a key factor in the economic feasibility of such processes, ARPA-E seeks input from experts in the fields of materials science (including advanced carbon fiber synthesis), process engineering, methane pyrolysis, plasma chemistry, and chemical engineering regarding potential mechanisms for the bulk conversion of carbon materials, specifically from less valuable forms (e.g. amorphous carbon) or mixtures, to more valuable single allotropes or controlled mixtures of high-value carbon structures. Consistent with the agency's mission, ARPA-E is seeking insights on clearly disruptive, novel technologies for such conversions, early in the R&D cycle, and not integration strategies for existing technologies. The information you provide may be used by ARPA-E in support of program planning.

The goal of the Environmental Engineering program is to support transformative research which applies scientific and engineering principles to avoid or minimize solid, liquid, and gaseous discharges, resulting from human activities on land, inland and coastal waters, and air, while promoting resource and energy conservation and recovery.  The program also fosters cutting-edge scientific research for identifying, evaluating, and monitoring the waste assimilative capacity of the natural environment and for removing or reducing contaminants from polluted air, water, and soils. Any proposal investigating sensors, materials or devices that does not integrate these products with an environmental engineering activity or area of research may be returned without review.

The goal of the Environmental Engineering program is to support transformative research which applies scientific and engineering principles to avoid or minimize solid, liquid, and gaseous discharges, resulting from human activities on land, inland and coastal waters, and air, while promoting resource and energy conservation and recovery.  The program also fosters cutting-edge scientific research for identifying, evaluating, and monitoring the waste assimilative capacity of the natural environment and for removing or reducing contaminants from polluted air, water, and soils. Any proposal investigating sensors, materials or devices that does not integrate these products with an environmental engineering activity or area of research may be returned without review.