This invention describes an improved method for extracting rare earth elements (REEs) from coal ash at ambient temperatures. This technology is available for licensing and/or further collaborative research from the U.S. Department of Energy’s National Energy Technology Laboratory.

Challenge
As China currently controls the supply and prices of almost all the world’s REEs, developing a domestic supply is critical for the continued manufacturing of technologies that support nearly all modern devices, including critical systems for energy and national defense. REE extraction efforts from domestic sources of coal and coal-related resources have emerged as a viable solution, but successful methods must be both cost-effective and environmentally friendly.

Current methods and technologies for REE extraction from ore and other sources can be hazardous and expensive to implement without harming the environment or workers. For example, common practices employ high temperatures and strong acids or bases. This technology seeks to overcome these and other issues with current REE extraction methods by turning to a material that is currently viewed as a waste – coal ash.

This patent-pending technology establishes a novel system and method for the microwave-assisted dry reforming of methane. The technology is available for licensing and/or further collaborative research from the U.S. Department of Energy’s National Energy Technology Laboratory.

Challenge

Traditional steam reforming of methane to produce hydrogen (H₂), which is then reacted with carbon (CO) to produce methanol and other industrial commodity chemicals, is an extremely energy intensive process with large carbon footprint. For example, the steam reforming reaction produces 10 tons of carbon dioxide (CO₂) for every ton of H₂. Methane dry reforming uses an alternative reaction that uses CO₂ as a soft oxidant to produce CO and H₂ from methane, which can be further processed into methanol or hydrocarbons. Further, using CO₂ to produce commodity chemicals, such as H₂ and CO, can generate revenue to offset carbon capture costs, reduce the carbon footprint of fossil-fuel powered processes, and allow sustainable use of fossil fuel resources.

Traditional dry reforming techniques are extremely energy intensive and require very high temperatures (>800C) that make it unpractical economically compared with the lower-temperature, carbon-positive, methane steam reforming. Microwave-assisted catalysis has been demonstrated as an enabling technology to promote high temperature chemical processes. Unlike traditional thermal heating, microwaves can rapidly heat catalysts to extremely high temperatures without heating the entire reactor volume. This reduces heat management issues of conventional reactors and enables rapid heating/cooling cycles. Ultimately, this can allow reactors to utilize excess renewable energy on an intermittent basis (load follow) to promote traditionally challenging, thermally-driven reactions for on-demand chemical production.

Microwave absorption is a function of the electronic and magnetic properties of the material, and a properly designed catalyst may function as a both a microwave heater and a reactive surface for driving the desired reaction. Microwave absorption is extremely sensitive to the catalyst’s chemical state and electronic structure, and effective catalysts must maintain microwave activity across a wide range of temperatures in both oxidative and reductive environments.

This invention describes a uniquely engineered 2-D amorphous carbon film and a memristor fabricated with coal-derived carbon quantum dots as the dielectric (switching) media for resistive random-access memory (RRAM). The atomic dielectric carbon layer can provide large storage density and 3-D packing ability, allowing memory and logic devices to be integrated in one chip, providing faster data processing with low energy consumption. This patent application is jointly owned by NETL and the University of Illinois-Urbana Champaign (UIUC) and it is available for licensing and/or further collaboration.

Challenge
Memory is essential to future computing with the exponential growth of data. These emerging memory technologies aim to revolutionize the existing memory hierarchy. Various emerging memory technologies are actively being investigated to meet ideal performance characteristics. RRAM has various advantages such as easy fabrication, simple metal-insulator-metal structure, excellent scalability, nanosecond speed, and long data retention. RRAM has been commercialized since 2013. Despite showing great promise over conventional RAM and its popularity in academia, RRAM has not become commercially popular. This is due to high device variability and high operation voltage.

NETL has developed a unique biocatalyst that is robust to environmental challenges and adaptable to feedstock and condition variability.

To combat climate change and move towards a circular carbon economy, technologies are needed to capture, store, and/or convert waste carbon. Microbial gas fermentation is one approach that exploits the natural ability of microorganisms to capture and utilize gaseous waste feedstocks. 

The NETL process uses an enriched microbial biocatalyst to convert carbon into acetate and other short-chain fatty acids. The innovation represents an improved way for direct conversion of carbon dioxide (CO₂) and CO waste gases into value added products with a lower carbon footprint and energy inputs compared to current methods for production of commercial short-chain fatty acids. 

The global acetic acid market is estimated to be $21.5 billion and projected to reach $34.2 billion by 2030.

The invention is available for license and/or CRADA.

Challenge
To combat climate change, slow CO₂ emissions, and move towards a circular carbon economy, technologies are needed to capture, store, and/or convert waste carbon. Microbial gas fermentation is one approach that exploits the natural ability of microorganisms to capture and utilize gaseous one-carbon waste feedstocks.

These technologies are high-performance CO₂ separation membranes made from polyphosphazene polymer blends.  NETL’s technology was originally developed to aid in separating CO₂ from flue gas emitted by fossil-fuel power plants. The NETL membrane is cross-linked chemically using low intensity UV irradiation, a facile technique that improves the membrane’s mechanical toughness compared to its uncrosslinked polyphosphazene constituents. Membranes fabricated with this technique have demonstrated permeability of up to 610 barrer, with CO₂/N₂ selectivity in excess of 30, at a practical separation temperature of 40°C. NETL’s patent-pending technology is being bundled with Idaho National Laboratory’s (INL) patented technology, with NETL handling licensing.  NETL would work with a potential licensee and INL to license the technology. 

Challenge: 
Membrane-based separation is one of the most promising solutions for CO₂ removal from post-combustion flue gases produced in power generation. Technoeconomic analyses show that membranes aimed for this application must possess high gas permeability; however, most high permeability materials suffer from poor mechanical properties or unacceptable loss in performance over time due to physical aging. This technology is a successful attempt to turn one of these high-performance materials with poor mechanical properties into one amenable for use in practical separation membranes with virtually no physical aging issues.
 

This invention describes the synthesis and application of nanostructured copper (Cu) catalysts that selectively convert carbon dioxide (CO₂) into carbon monoxide (CO). This technology is available for licensing and/or further collaborative research from the U.S. Department of Energy’s National Energy Technology Laboratory.

Challenge
The electrochemical CO₂ reduction reaction (CO₂RR) is an appealing strategy for addressing man-made CO₂ emissions because it can leverage excess renewable energy to produce carbon-neutral chemicals and fuels. However, the economic viability of large-scale CO₂RR systems will depend on the ability to selectively and efficiently form desirable products. Because it is earth-abundant and can produce a variety of products, Cu is a popular CO₂RR catalyst. Unfortunately, the wide product distribution of Cu introduces inefficiencies in the form of chemical separation steps.

This invention describes basic immobilized amine sorbents (BIAS) with improved pelletization process and formulation for use in CO₂ capture processes. This technology is available for licensing and/or further collaborative research from the U.S. Department of Energy’s National Energy Technology Laboratory.

Challenge
BIAS sorbents demonstrate high CO₂ capture capacity and thermal stability over multiple steam regeneration cycles and represent a promising approach for CO₂ removal from a variety of source points, including coal and natural gas combustion power plants. Bench- and pilot-scale testing have demonstrated the feasibility of commercial-scale BIAS sorbents. However, full commercialization of BIAS sorbents requires pelletization. Commercially available silica typically serves as the support for amine-based particle sorbents, yet these materials are not commercially feasible due to their relatively low mechanical strength and difficult management in dynamic reactor systems. Thus, the development of an economical method of fabricating a strong silica-supported BIAS pellet is a primary concern.

Research is active on a method to convert methane into synthesis gas using mixed metal oxides. The resulting syngas could be used to manufacture more valuable chemicals. This technology is available for licensing and/or further collaborative research from the U.S. Department of Energy’s National Energy Technology Laboratory.

Challenge

Natural gas (NG), which is composed primarily of methane, is one of the most abundant, low-cost carbon-containing feedstocks available. The economically available route to produce valuable chemicals from methane is via synthesis gas followed by different chemical routes to manufacture the desired chemicals. In a large-scale industrial plant, the production of syngas accounts for a large part of the total costs. Therefore, it is important to develop more efficient and cost-effective methods for the conversion of methane to syngas.

The U.S. Department of Energy’s National Energy Technology Laboratory (NETL) has developed a laser induced breakdown spectroscopy (LIBS) probe featuring simplified construction that minimizes the need for optical elements from the probes data collection path, reducing potential interference with the transmission of high quality spectra. By reducing the complexity and cost of the laser head, the invention maximizes the amount and quality of light returned for analysis and increases the usefulness of LIBS research.

Research is currently active on the patented technology titled, "Kick Detection at the Bit Using Wellbore Geophysics." This technology is available for licensing and/or further collaborative research from the U.S. Department of Energy’s National Energy Technology Laboratory.