Status: ALUMNI
State: WA
Project Term: 04/05/2013 - 08/31/2017
Program: OPEN 2012
Award: $2,339,676

Integral Consulting

Integral Consulting is developing a cost-effective ocean wave buoy system that will accurately measure its own movements as it follows the surface wave motions of the ocean and relay this real-time wave data. Conventional real-time wave measurement buoys are expensive, which limits the ability to deploy large networks of buoys. Data from Integral Consulting’s buoys can be used as input to control strategies of wave energy conversion (WEC) devices and allow these controlled WECs to capture significantly more energy than systems that do not employ control strategies. Integral Consulting’s…

Status: Selected
State: TBD
Project Term: TBD
Program: COOLERCHIPS
Award: TBD

Intel Federal

Intel Federal will develop ultra-low-thermal resistance, coral-shaped immersion cooling heat sinks integrated with a 3D vapor chamber cavity for high-power devices. Intel’s design would address the challenge of adapting two-phase immersion cooling by optimizing 3D vapor chambers to spread the heat more effectively. This is paired with innovative boiling enhancement coatings to reduce thermal resistance by promoting high nucleation site density.

Status: ACTIVE
State: LA
Project Term: 09/18/2019 - 06/30/2024
Program: HITEMMP
Award: $1,419,417

International Mezzo Technologies

International Mezzo Technologies will design, manufacture, and test a compact, nickel-based superalloy supercritical carbon dioxide (sCO2) recuperator (a type of heat exchanger). The recuperator will incorporate laser-welded micro tubes and function at 800°C (1,472°F) and 275 bar (3,989 psi). Currently, the cost of recuperators for power systems operating in these conditions is prohibitive. Laser welding micro tubes offers a low-cost approach to fabricating heat exchangers, which could increase the economic competitiveness of sCO2 power cycles. Mezzo’s program could provide a pathway to…

Status: ALUMNI
State: MI
Project Term: 01/06/2016 - 04/05/2017
Program: IDEAS
Award: $499,999

Inventev

Inventev is developing a proof-of-concept for a commercially viable generator system that is integrated with a truck transmission. The project will involve the design and fabrication of transmission and power electronics subsystems, integration of those systems into a Ford F550 chassis-cab truck, and conversion of the standard gasoline engine to a low-pressure natural gas engine. The project aims to create a 120kW low-cost, low-emission mobile power generator using natural gas with a cost target of 6-to-7 cents per kilowatt-hour. Of particular significance is the ability to use the same…

Status: ACTIVE
State: MD
Project Term: 08/09/2021 - 02/08/2024
Program: Exploratory Topics
Award: $500,000

InventWood

InventWood proposes to develop and manufacture lightweight 3D wood corrugated honeycomb structures to replace metal counterparts. Compared with widely used aluminum, 3D wood has similar mechanical strength, possesses one-third the density and one-fourteenth the cost, and reduces CO2 emissions by 90% in its manufacture. Project goals include: (1) improving 3D corrugated wood performance to achieve a mechanical strength of up to 500 MPa; (2) improving 3D wood performance to meet structural material requirements, including bending, compression, fatigue resistance, and thermal-cycling and water…

Status: ALUMNI
State: CA
Project Term: 10/01/2021 - 09/30/2023
Program: ECOSynBio
Award: $1,657,763

Invizyne Technologies

Invizyne Technologies proposes an electrically powered cell-free enzymatic approach for upgrading ethanol into more useful chemicals. Because carbon for 99% of organic chemicals is petroleum-derived, replacing petroleum carbon with carbon captured from the atmosphere could greatly mitigate carbon emissions. Atmospheric CO2 represents a potentially limitless source of inexpensive carbon, but there are significant challenges to converting captured CO2 into useful chemicals and fuels. While recent technologies can capture CO2 by converting it into simple chemicals such as formate or ethanol,…

Status: ACTIVE
State: CA
Project Term: 08/08/2022 - 08/07/2024
Program: Exploratory Topics
Award: $496,177

Invizyne Technologies

Invizyne will develop efficient cell-free enzyme cascade reactions as an alternative, more commercially competitive approach to microbe-produced biofuels. Cell-free technology is still relatively new. However, Invizyne has already been successful in improving enzyme stability and process optimization to push down the cost curve of biofuels. The team seeks to address a barrier to market penetration for cell-free technologies by simplifying and reducing the cost of enzyme production. If successful, this approach could enable a cell-free enzyme system that produces isobutanol at below $3 per…

Status: ALUMNI
State: MA
Project Term: 01/16/2017 - 08/31/2021
Program: IONICS
Award: $6,761,565

Ionic Materials

Ionic Materials will develop a lithium metal (not lithium ion) rechargeable battery cell that employs a novel solid polymer electrolyte that enables the world’s first truly safe lithium metal rechargeable battery cell. Scientists at the City University of New York have found that Ionic Material’s proprietary ionic conducting polymer is the most highly lithium conducting solid state polymer material ever measured (at room temperature). This polymer has high ionic conductivity across a range of temperatures, can be reliably extruded into very thin films, is non-flammable, has attractive…

Status: ALUMNI
State: MA
Project Term: 04/01/2019 - 09/30/2021
Program: OPEN 2018
Award: $2,061,799

Ionic Materials

Ionic Materials will develop a more energy dense (by volume and mass) rechargeable battery based on an aluminum-alkaline chemistry. At the center of Ionic Materials’ innovation is a new polymer-based material that suppresses the formation of undesired chemical products that prevent aluminum-alkaline batteries from recharging. Aluminum is a highly abundant natural resource and costs much less than cobalt, nickel, and lithium, key elements in today’s state-of-the-art batteries. Aluminum-alkaline chemistries are also inherently safer than LIBs, making them more appropriate for use in electric…

Status: ALUMNI
State: IA
Project Term: 04/08/2020 - 05/31/2022
Program: DIFFERENTIATE
Award: $1,979,995

Iowa State University (ISU)

Iowa State University will develop novel machine learning tools to accelerate the inverse design of new microstructures in photovoltaics. The team will create a new deep generative model called bi-directional inverse design networks to combat challenges in real-world inverse design problems. The proposed inverse design tools, if successful, will produce novel, manufacturable material microstructures with improved electromagnetic properties relative to existing technology for better, more efficient solar energy.

Status: ALUMNI
State: IA
Project Term: 08/11/2016 - 12/31/2017
Program: IDEAS
Award: $371,726

Iowa State University (ISU)

Iowa State University (ISU) will develop a catalytic autothermal pyrolysis (CAP) process for the production of aromatics and olefins that refiners blend into transportation fuels. Pyrolysis is the decomposition of substances by heating - the same process used to render wood into charcoal, caramelize sugar, and dry roast coffee beans. Traditionally, energy for pyrolysis is provided through indirect heat exchange, employing high temperature heat exchangers within reactors or conveying hot solids into reactors with the feedstock. This approach complicates the design and operation of reactors…

Status: ALUMNI
State: IA
Project Term: 02/01/2017 - 09/30/2019
Program: IONICS
Award: $1,631,957

Iowa State University (ISU)

Iowa State University (ISU) will develop new lithium-ion-conducting glassy solid electrolytes to address the shortcomings of present-day lithium batteries. The electrolytes will have high ionic conductivities and excellent mechanical, thermal, chemical, and electrochemical properties. Because glasses lack grain boundaries, they will also be impermeable to lithium dendrites, branchlike metal fibers that can short-circuit battery cells. These glassy solid electrolytes can enhance the safety, performance, manufacturability, and cost of lithium batteries. In addition to the electrolyte…

Status: CANCELLED
State: IA
Project Term: 01/15/2010 - 10/14/2011
Program: OPEN 2009
Award: $2,490,248

Iowa State University (ISU)

Iowa State University (ISU) is genetically engineering a species of aquatic microalgae called Chlamydomonas for more energy efficient conversion of sunlight and carbon dioxide to biofuels. Current microalgae genetic technologies are imprecise and hinder the rapid engineering of a variety of desirable traits into Chlamydomonas. In the absence of genetic engineering, it remains unlikely that current microalgae technologies for biofuel production will be able to economically compete with traditional fossil fuels. ISU is developing a portfolio of technologies for rapid genetic modification and…

Status: CANCELLED
State: IA
Project Term: 06/01/2016 - 06/30/2018
Program: OPEN 2015
Award: $2,274,303

Iowa State University (ISU)

The team led by Iowa State University (ISU) will develop an All Solid-State Sodium Battery (ASSSB) that will have a high energy content, can easily be recycled, and rely on highly abundant and extremely low cost starting materials. Commercially available sodium-based batteries operate at elevated temperatures, which decreases the efficiency and safety of the system. The team seeks to improve all three of the main components of a sodium-based battery: the anode, cathode, and electrolyte separator. The team’s anode is a porous carbon nanotube layer that will serve as a framework on which sodium…

Status: ALUMNI
State: IA
Project Term: 06/12/2017 - 03/31/2020
Program: ROOTS
Award: $1,099,513

Iowa State University (ISU)

Iowa State University (ISU) will develop new sensors that measure the amount of nitrogen in soils and plants multiple times per day throughout the growing season. Nitrogen fertilizer is the largest energy input to U.S. corn production. However, its use is inefficient due to a lack of low-cost, effective nitrogen sensors. Year-to-year variation in nitrogen mineralization, due to differences in soil water and temperature, creates tremendous uncertainty about the proper fertilizer input and can cause farmers to over-apply. As a result, nitrogen fertilizer is lost from croplands to the…

Status: CANCELLED
State: IA
Project Term: 09/01/2018 - 08/31/2021
Program: SENSOR
Award: $330,967

Iowa State University (ISU)

Reliable, accurate CO2 measurement to inform building system operations can substantially benefit energy use in U.S. buildings. To meet this need, a demonstrated evaluation protocol is required to assess accuracy and reliability of CO2 sensing technologies across a number of influencing factors The Iowa State research team will develop comprehensive testing protocols and contribute to development of guidelines to assess the accuracy and reliability of CO2 sensing technologies being developed through the SENSOR program. The outputs of this project will also inform both the R&D and…

Status: ALUMNI
State: NM
Project Term: 01/10/2017 - 05/09/2019
Program: SHIELD
Award: $2,149,590

IR Dynamics

IR Dynamics will develop a low-cost nanomaterial technology to be incorporated into flexible window films that will improve thermal insulation and solar heat gain. The team’s nanomaterial will incorporate two materials. First, low-cost nanosheets will increase thermal resistance. Second, a new type of nanomaterial will allow heat, in the form of infrared radiation (IR) from the sun, to pass through the window when it is cold outside, helping to warm the room in cold weather. When it is hot outside, the material will block the solar IR from passing through the window and warming the interior.…

Status: ALUMNI
State: CO
Project Term: 10/01/2012 - 06/30/2015
Program: GRIDS
Award: $1,724,842

ITN Energy Systems

ITN Energy Systems is developing a vanadium redox flow battery for residential and small-scale commercial energy storage that would be more efficient and affordable than today’s best energy storage systems. In a redox flow battery, chemical reactions occur that allow the battery to absorb or deliver electricity. Unlike conventional batteries, flow batteries use a liquid (also known as an electrolyte) to store energy; the more electrolyte that is used, the longer the battery can operate. Vanadium electrolyte-based redox flow battery systems are a technology for today’s market, but they require…

Status: ALUMNI
State: CO
Project Term: 01/01/2010 - 06/30/2013
Program: OPEN 2009
Award: $5,991,065

ITN Energy Systems

ITN Energy Systems is addressing the high cost of electrochromic windows with a new manufacturing process: roll-to-roll deposition of the film onto flexible plastic surfaces. Production of electrochromic films on plastic requires low processing temperatures and uniform film quality over large surface areas. ITN is overcoming these challenges using its previous experience in growing flexible thin-film solar cells and batteries. By developing sensor-based controls, ITN's roll-to-roll manufacturing process yields more film over a larger area than traditional film deposition methods.…

Status: ALUMNI
State: CA
Project Term: 04/30/2014 - 05/18/2016
Program: RANGE
Award: $2,717,969

Jet Propulsion Laboratory (JPL)

NASA’s Jet Propulsion Laboratory (JPL) is developing a new metal-hydride/air battery. Current electric vehicle batteries use costly components and require packaging and shielding to ensure safety. To address this, JPL’s technology will incorporate safe, inexpensive, and high-capacity materials for both the positive and negative electrodes of the battery as part of a novel design. Additionally, JPL’s design will use a membrane developed to prevent water loss and CO2 entry within the battery. High power performance and decreased costs will be possible with the use of a single catalyst material…

Status: ACTIVE
State: MA
Project Term: 09/26/2023 - 01/07/2027
Program: COOLERCHIPS
Award: $1,292,719

JetCool Technologies

JetCool will develop a microconvective cooling technology that combines and optimizes two distinct cooling approaches to provide the highest levels of energy efficiency in data centers. JetCool’s micro-convective cooling modules lower CPU temperatures, reducing leakage current and resulting in power savings of 8-10% while an in-server radiator eliminates the need for server-dedicated air cooling in the data center to provide significant additional energy savings.

Status: ALUMNI
State: MD
Project Term: 10/01/2015 - 03/31/2017
Program: IDEAS
Award: $489,889

Johns Hopkins University

Johns Hopkins University will develop and assess components of a self-powered system to convert methane (the main component in natural gas) into carbon fiber. Methane can be separated into carbon and hydrogen, or burned for energy. The team will develop processes to use methane both to power the system and serve as carbon feedstock in a four stage system. First, methane is decomposed into hydrogen and carbon, and combined into a carbon/metal aggregate. Second, the carbon/metal aggregate is melted, producing a liquid melt containing carbon dissolved within it. Third, the melt is solidified…

Status: ALUMNI
State: MD
Project Term: 02/15/2016 - 12/31/2017
Program: IDEAS
Award: $500,000

Johns Hopkins University

Johns Hopkins University will study the adsorption compression phenomenon for ways to enhance the reaction rate for commercially relevant reactions. Adsorption is the adhesion of molecules from a gas, liquid, or dissolved solid to a surface, creating layers of the “adsorbate” on the surface of the host material. The Johns Hopkins team will explore the physical state where the forces acting parallel to the surface of adsorbate molecules can in certain conditions be far higher than forces associated with adsorption of additional molecules on the surface. This phenomenon is called adsorption…

Status: ALUMNI
State: MD
Project Term: 06/28/2019 - 12/27/2023
Program: OPEN 2018
Award: $3,690,304

Johns Hopkins University

Johns Hopkins will scale up a novel process to convert natural gas into hydrogen and solid carbon with no water input while reducing carbon dioxide (CO2) emissions. Leveraging industrial partners Southern Company and Cabot Corporation, the team will scale up its cyclic process based on early laboratory demonstration. ETCH, INC, is commercializing the process, which is expected to produce H2 from NG at costs comparable to the state-of-the art commercial technologies, while lowering energy input, reducing CO2 emissions, and producing high-value pure carbon materials.

Status: ACTIVE
State: MD
Project Term: 05/01/2020 - 10/30/2024
Program: Exploratory Topics
Award: $2,250,000

Johns Hopkins University

Johns Hopkins University aims to develop an energy-efficient, scalable approach to convert methane into hydrogen and valuable graphitized carbon fibers (GCFs).The team will design an electrothermal reactor to pyrolyze (decompose) methane into hydrogen and low-quality carbon products, such as graphite particles, which will then be spun and heated to GCFs. These high-quality fibers can be used for construction material applications. The fully electrified manufacturing processes will be highly scalable, and built to accommodate various feedstocks and intermittent renewable energy sources.…

Status: ACTIVE
State: MD
Project Term: 02/23/2021 - 02/22/2024
Program: Exploratory Topics
Award: $1,469,452

Johns Hopkins University

Johns Hopkins University aims to catalytically convert low-cost #3-7 plastic mixtures into para-xylene, one of the most valuable hydrocarbon products. Johns Hopkins' primary design of the hydrocracking process first converts hydrocarbon plastics selectively to volatile hydrocarbons with xylene isomers as the predominant products. Then a post-reaction separation unit derives pure para-xylene as the desired product. The unit allows recycling of the residual H2 and possibly other hydrocarbons back to the hydrocracker. The ultimate goal of this project is to enable energy-efficient and…

Status: ACTIVE
State: MD
Project Term: 01/13/2023 - 01/22/2026
Program: MINER
Award: $2,000,000

Johns Hopkins University

Johns Hopkins University (JHU) will develop sustainable mining of critical elements from gangue minerals. The concept is based on the electrosynthesis of hydrochloric acid or HCl and base (sodium hydroxide or NaOH) via salt splitting and using renewable electricity as the power source. JHU will use the produced HCl to leach targeted metals from low-grade minerals and NaOH to react with CO2 and generate sodium carbonate (Na2CO3). Recombining the metal chlorides with Na2CO3 will allow for subsequential precipitation of manganese, cobalt, nickel, or copper carbonates and magnesium or iron…

Status: ACTIVE
State: MD
Project Term: 09/21/2023 - 09/20/2025
Program: Exploratory Topics
Award: $500,000

Johns Hopkins University

Johns Hopkins University will develop a new class of materials called high-entropy glass-ceramics that could store more nuclear waste by percent weight than industry-standard glasses. The novel materials could significantly lower the infrastructure cost of nuclear waste disposal deep underground by reducing the volume of deep earth that must be excavated for every kilogram of waste.

Status: ACTIVE
State: MD
Project Term: 09/22/2023 - 09/21/2025
Program: Exploratory Topics
Award: $500,000

Johns Hopkins University

Johns Hopkins University will develop a process using new electrocatalysts to make amino acids, the building blocks of proteins, that could accelerate the development of chemicals and food. The novel process would synthesize amino acids using chemical feedstocks that can be derived from merely air, water, and renewable electricity to substantially reduce carbon dioxide emissions in food and chemical production.

Status: ACTIVE
State: PA
Project Term: 05/23/2022 - 05/22/2025
Program: REMEDY
Award: $4,334,490

Johnson Matthey

Johnson Matthey, Oak Ridge National Laboratory, and Consol Energy will adapt the Catalytic Oxidation METhane (COMET™) methane abatement system to convert vent air methane at a Consol Energy coal mining site. The COMET methane system has shown potential for controlling dilute methane emissions. The team will use cost-effective technology to achieve over 99.5% methane conversion efficiency at temperatures below 1112 ºF for methane concentration in the range of 0.1-1.6%, representing nearly all ventilation air methane sources in the U.S. The work will focus on further developing the catalyst…

Status: ALUMNI
State: NY
Project Term: 09/15/2017 - 03/31/2021
Program: PNDIODES
Award: $2,192,619

JR2J

Advanced doping methods are required to realize the potential of gallium nitride (GaN)-based devices for future high efficiency, high power applications. Ion implantation is a doping process used in other semiconductor materials such as Si and GaAs but has been difficult to use in GaN due to the limited ability to perform a damage recovery anneal in GaN. JR2J will develop an innovative laser spike annealing technique to activate implanted dopants in GaN. Laser spike annealing is a high-temperature (above 1300 ºC) heat treatment technique that activates the dopants in GaN and repairs damage…

Status: ALUMNI
State: MA
Project Term: 05/12/2020 - 07/31/2022
Program: DIFFERENTIATE
Award: $2,697,922

Julia Computing

Julia Computing, Inc. will develop a neural component machine learning tool to reduce the total energy consumption of heating, ventilation, and air conditioning (HVAC) systems in buildings. As of 2012, buildings consume 40 percent of the nation’s primary energy, with HVAC systems comprising a significant portion of this consumption. It has been demonstrated that the use of modeling and simulation tools in the design of a building can yield significant energy savings—up to 27 percent of total energy consumption. However, these simulation tools are still too slow to be practically useful. Julia…

Status: ACTIVE
State: ME
Project Term: 12/21/2021 - 12/20/2024
Program: MARINER
Award: $592,865

Kelson Marine

Kelson will continue developing simulation tools and methods for accurate and efficient design of U.S. macroalgae farms, building on the work done under the University of New England MARINER award. To maximize the impact of this effort, Kelson will implement these simulation methods in an open-source software tool that will be uniquely capable of analyzing the hydro-structural performance of offshore macroalgae farms. The team will extend the tool’s functionality based on macroalgae farmer feedback and demonstrate to stakeholders and regulators how the open-source tool can support a robust…

Status: CANCELLED
State: CA
Project Term: 03/08/2013 - 10/01/2017
Program: OPEN 2009
Award: $4,705,000

Kohana Technologies

Kohana Technologies is developing wind turbines with a control system that delivers compressed air from special slots located in the surface of its blades. The compressed air dynamically adjusts the aerodynamic performance of the blades, and can essentially be used to control lift, drag, and ultimately power. This control system has been shown to exhibit high levels of control in combination with an exceptionally fast response rate. The deployment of such a control system in modern wind turbines would lead to better management of the load on the system during peak usage, allowing larger…

Status: CANCELLED
State: NC
Project Term: 03/10/2014 - 03/09/2018
Program: SWITCHES
Award: $3,224,993

Kyma Technologies

Kyma Technologies will develop a cost-effective technique to grow high-quality gallium nitride (GaN) seeds into GaN crystal boules, which are used as the starting material for a number of semiconductor devices. Currently, growing boules from GaN seeds is a slow, expensive, and inconsistent process, so it yields expensive electronic devices of varying quality. Kyma will select the highest quality GaN seeds and use a proprietary hydride vapor phase epitaxy growth process to rapidly grow the seeds into boules while preserving the seed’s structural quality and improving its purity.

Status: ALUMNI
State: IL
Project Term: 01/29/2014 - 08/31/2020
Program: REMOTE
Award: $6,896,121

LanzaTech

LanzaTech will combine methane fermentation expertise, experimental bioreactor characterization, as well as advanced simulation and modeling to develop a novel gas fermentation system that can significantly improve gas to liquid mass transfer, or the rate at which methane gas is delivered to a biocatalyst. This unique bioreactor concept seeks to efficiently transfer methane to microbial biocatalysts by reducing the energy demand required for high transfer rates. Although methane is a flammable gas, the new technology also maintains the safe operation necessary for a small-scale conversion…

Status: ACTIVE
State: IL
Project Term: 09/20/2021 - 09/30/2024
Program: ECOSynBio
Award: $4,160,263

LanzaTech

LanzaTech will create transformative technology to directly convert CO2 to ethanol at 100% carbon efficiency with technical assistance from the University of Michigan and Oak Ridge National Laboratory. The team will develop a novel biocatalyst that leverages affordable, renewable hydrogen (H2) to capture and fix CO2 directly into ethanol, a biofuel and feedstock for valuable products. The core inputs are carbon-free renewable energy, water, and CO2. The alcohol-to-jet process developed by Pacific Northwest National Laboratory and LanzaTech Gas fermentation can leverage renewable H2 to…

Status: ALUMNI
State: CA
Project Term: 08/01/2015 - 06/30/2018
Program: ALPHA
Award: $2,436,685

Lawrence Berkeley National Laboratory (LBNL)

LBNL, in coordination with Cornell University, will develop a driver for magneto-inertial fusion based on ion beam technology that can be manufactured with low-cost, scalable methods. Ion beams are commonly used in research laboratories and manufacturing, but currently available technology cannot deliver the required beam intensities at low enough cost to drive an economical fusion reactor. LBNL will take advantage of microelectromechanical (MEMS) technology to develop a design consisting of thousands of mini ion “beamlets” densely packed on silicon wafers – up to thousands of beamlets per 4…

Status: ALUMNI
State: CA
Project Term: 03/19/2020 - 06/22/2022
Program: DIFFERENTIATE
Award: $1,800,000

Lawrence Berkeley National Laboratory (LBNL)

Over the past 50 years, progress in optical metamaterial device design has led to the manipulation of light over a wide range of wavelengths spanning the ultraviolet to the far infrared, resulting in technological advancements such as selective radiative absorbers for solar energy and daytime passive cooling using deep space. Further advances in optical metamaterial devices could enable increased energy efficiency, reduced national primary energy consumption, inexpensive long duration energy storage, and next generation solid-state heat engines. Lawrence Berkley National Laboratory (LBNL)…

Status: ALUMNI
State: CA
Project Term: 07/16/2010 - 12/31/2014
Program: Electrofuels
Award: $3,439,506

Lawrence Berkeley National Laboratory (LBNL)

Lawrence Berkeley National Laboratory (LBNL) is improving the natural ability of a common soil bacteria called Ralstonia eutropha to use hydrogen and carbon dioxide for biofuel production. First, LBNL is genetically modifying the bacteria to produce biofuel at higher concentrations. Then, LBNL is using renewable electricity obtained from solar, wind, or wave power to produce high amounts of hydrogen in the presence of the bacteria—increasing the organism's access to its energy source and improving the efficiency of the biofuel-creation process. Finally, LBNL is tethering electrocatalysts…

Status: ALUMNI
State: CA
Project Term: 10/01/2010 - 09/30/2013
Program: GRIDS
Award: $1,900,136

Lawrence Berkeley National Laboratory (LBNL)

Lawrence Berkeley National Laboratory (LBNL) is designing a flow battery for grid storage that relies on a hydrogen-bromine chemistry which could be more efficient, last longer, and cost less than today's lead-acid batteries. Flow batteries are fundamentally different from traditional lead-acid batteries because the chemical reactants that provide their energy are stored in external tanks instead of inside the battery. A flow battery can provide more energy because all that is required to increase its storage capacity is to increase the size of the external tanks. The hydrogen-bromine…

Status: ALUMNI
State: CA
Project Term: 09/01/2017 - 08/31/2018
Program: IDEAS
Award: $500,000

Lawrence Berkeley National Laboratory (LBNL)

Lawrence Berkeley National Laboratory (LBNL) will develop a high power density, rapid-start, metal-supported solid oxide fuel cell (MS-SOFC), as part of a fuel cell hybrid vehicle system that would use liquid bio-ethanol fuel. In this concept, the SOFC would accept hydrogen fuel derived from on-board processing of the bio-ethanol and air, producing electricity to charge an on-board battery and operate the motor. The project aims to develop and demonstrate cell-level MS-SOFC technology providing unprecedented high power density and rapid start capability initially using hydrogen and simulated…

Status: ALUMNI
State: CA
Project Term: 07/22/2019 - 07/21/2023
Program: OPEN 2018
Award: $3,170,000

Lawrence Berkeley National Laboratory (LBNL)

Lawrence Berkeley National Laboratory (LBNL) is developing a metal-supported SOFC (MS-SOFC) stack that produces electricity from an ethanol-water blend at high efficiency and energy density. This technology will enable light- to medium-duty hybrid passenger EVs to operate at a long range, with higher efficiency than gasoline vehicles and lower greenhouse gas (GHG) emissions than current vehicles. LBNL’s MS-SOFCs are mechanically rugged: they can heat from room temperature to their approximately 700°C (1292 °F) operating temperature within a few minutes without cracking and tolerate rapid…

Status: ACTIVE
State: CA
Project Term: 02/21/2019 - 02/20/2024
Program: OPEN 2018
Award: $4,872,671

Lawrence Berkeley National Laboratory (LBNL)

LBNL will use advanced microfabrication technology to build and scale low-cost, compact, higher-power multi-beam ion accelerators. These accelerators will be able to increase the ion current up to 100 times, helping to enable a new learning curve for compact accelerator technology. MEMS (micro-electro mechanical systems) technology enables massively parallel, low-cost batch fabrication of ion beam accelerators. The team proposes to scale ion accelerators based on MEMS to higher beam power and pack hundreds to thousands of ion beamlets on silicon wafers. Ions will be injected and accelerated…

Status: ALUMNI
State: CA
Project Term: 01/01/2012 - 03/26/2015
Program: PETRO
Award: $4,836,807

Lawrence Berkeley National Laboratory (LBNL)

Lawrence Berkeley National Laboratory (LBNL) is modifying tobacco to enable it to directly produce fuel molecules in its leaves for use as a biofuel. Tobacco is a good crop for biofuels production because it is an outstanding biomass crop, has a long history of cultivation, does not compete with the national food supply, and is highly responsive to genetic manipulation. LBNL will incorporate traits for hydrocarbon biosynthesis from cyanobacteria and algae, and enhance light utilization and carbon uptake in tobacco, improving the efficiency of photosynthesis so more fuel can be produced in the…

Status: ALUMNI
State: CA
Project Term: 01/01/2014 - 12/31/2016
Program: REMOTE
Award: $3,500,000

Lawrence Berkeley National Laboratory (LBNL)

Lawrence Berkeley National Laboratory (LBNL) is genetically engineering a bacterium called Methylococcus in order to produce an enzyme that binds methane with a common fuel precursor to create a liquid fuel. This process relies on methylation, a reaction that requires no oxygen or energy inputs but has never been applied to methane conversion.” First, LBNL will construct a unique enzyme called a “PEP methylase” from an existing enzyme. The team will then bioengineer new metabolic pathways for assimilating methane and conversion to liquid fuels.

Status: ALUMNI
State: CA
Project Term: 06/12/2017 - 09/11/2023
Program: ROOTS
Award: $2,706,657

Lawrence Berkeley National Laboratory (LBNL)

Lawrence Berkeley National Laboratory (LBNL) will develop an imaging-modeling toolbox to aid in the development of more efficient crops at field scales. The approach is based on a root phenotyping method called Tomographic Electrical Rhizosphere Imaging (TERI). TERI works by applying a small electrical signal to a plant, then measuring the impedance responses through the roots and correlating those responses to root and soil properties. Key target traits of the LBNL project include root mass, root surface area, rooting depth, root distribution in soil, and soil moisture content and texture.…

Status: ALUMNI
State: CA
Project Term: 07/28/2017 - 06/30/2021
Program: ROOTS
Award: $2,299,999

Lawrence Berkeley National Laboratory (LBNL)

Lawrence Berkeley National Laboratory (LBNL) will develop a field-deployable instrument that can measure the distribution of carbon in soil using neutron scattering techniques. The system will use the Associated Particle Imaging (API) technique to determine the three-dimensional carbon distribution with a spatial resolution on the order of several centimeters. A compact, portable neutron generator emits neutrons that excite carbon and other nuclei. The excited carbon isotopes emit gamma rays that can be detected above the ground with spectroscopic detectors and used as a proxy to estimate the…

Status: ACTIVE
State: CA
Project Term: 11/01/2020 - 05/01/2024
Program: Exploratory Topics
Award: $1,000,000

Lawrence Berkeley National Laboratory (LBNL)

The Lawrence Berkeley National Lab (LBNL) CARBON STANDARD team will develop advanced machine learning tools for a cross-scale quantification of carbon intensity (CI) during biofuel feedstock production. LBL will act as the integrator across all SMARTFARM teams to analyze complex, multi-physics, and multi-scale datasets, and develop scaling approaches across the variety of CI monitoring fields.

Status: ACTIVE
State: CA
Project Term: 06/02/2023 - 12/01/2025
Program: Exploratory Topics
Award: $1,498,003

Lawrence Berkeley National Laboratory (LBNL)

The Lawrence Berkeley National Laboratory (LBNL) team proposes to probe for LENR at external excitation energies below 500 eV, systematically varying materials and conditions while monitoring nuclear event rates with a suite of diagnostics. The team will draw from knowledge based on previous work using higher energy ion beams as an external excitation source for LENR on metal hydrides electrochemically loaded with deuterium.