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.
 

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.

The invention is a family of hydrophobic, low viscosity, low vapor pressure physical solvents with molecular structures consisting of two or more alkyl-ester functional groups on a central hydrocarbon chain. These solvents have been shown to possess high carbon dioxide (CO₂) solubility and absorption selectivity, which make them well suited for the removal of CO₂ from hydrogen (H₂) produced from synthesis gas. This technology is available for licensing and/or further collaborative research from the U.S. Department of Energy’s National Energy Technology Laboratory.

Challenge
Future integrated gasification combined cycle (IGCC) power plants and steam methane reforming (SMR) chemical plants have the potential to reduce the cost of CO₂ capture. These power and chemical plants generate high-pressure CO₂ gas streams from the in-situ water gas shift reaction when producing H₂ used to power the electrical turbines. A variety of methods have been proposed to capture CO₂, including solvent, sorbent, and membrane technologies, with continuous solvent looping systems currently considered to be the most advanced. Precombustion capture of CO₂ is typically accomplished using physical solvents.

State-of-the-art precombustion CO₂ capture processes predominantly employ hydrophilic physical solvents. Current commercial physical solvents touted for IGCC CO₂ capture were developed for removing acid gases from raw natural gas streams. Therefore, they were designed to remove significant amounts of water from the process gas. As such, the focus was on the purification of the process gas with less concern for generation of high-purity CO₂ streams suitable for pipeline transmission and sequestration. While water removal is important for natural gas pipeline applications, it is not favorable for applications in which the fuel stream is directly combusted on-site, as would be encountered in IGCC systems.

The invention is method of fabricating a hollow glass waveguide (tube that transmits light) that exhibits low loss in the visible or short-wave spectral region and is optimized for Raman spectroscopy or visible laser beam delivery. Prior art hollow capillaries suffer high optical loss and poor visible transmission, but the NETL invention produces these high-quality capillaries via a specialized deposition system. This technology is available for licensing and/or further collaborative research from the U.S. Department of Energy’s National Energy Technology Laboratory.

Challenge
Currently, there are no high-quality commercially produced visible-wave hollow waveguides. Commercial vendors can produce reasonable IR hollow waveguides, but visible-range waveguides exhibit high losses and high optical noise. The patented NETL Raman Gas Analyzer requires visible-range hollow waveguides with small internal diameters (a few hundred microns) and low optical noise. No vendor could produce these waveguides, so NETL constructed this new system of waveguide fabrication. Other spectroscopic systems would benefit from better waveguides including absorption spectrometers, microscopes, sensors, etc.
 

NETL's basic immobilized amine sorbents (BIAS) have previously been shown effective at removing heavy metals and radioactive ions from aqueous sources. Chelating the amines with metals such as iron or copper significantly increases the heavy metal capture affinity of the sorbents, up to 50% over the non-metal chelated amines. In this invention, the metal-chelated polyamine is chemically tethered to a solid silica support (SiO₂) via a crosslinker. The sorbents resist leaching by H₂O in an aqueous stream containing heavy oxyanion-based (and other) metals and demonstrate stability over a pH range of 5 - 14. Cationic heavy metals are captured by the amine functional groups (-NH₂, -NH, -N) from the polymeric network while oxyanionic metal species bind readily to the metal loaded sites. This technology is available for licensing and/or further collaborative research from the U.S. Department of Energy's National Energy Technology Laboratory.

Challenge

Heavy metals are common in industrial wastewater streams such as those associated with flue gas desulfurization (FGD), acid mine drainage, hydraulic fracturing, and nuclear fission. As heavy metals pose health and environmental hazards, there is a critical need to remediate them, i.e., safely and efficiently remove them from the aqueous sources. The US Resource Conservation and Recovery Act (RCRA) gave the US Environmental Protection Agency the authority to establish and enforce regulatory policies and toxicity limits arsenic (As), cadmium (Cd), chromium (Cr), lead (Pb), mercury (Hg), selenium (Se), and other metals. Many of these metals present a distinct challenge for capture because they are most commonly present in the polyatomic oxy-anion form. Sources for most of these contaminant metals result from the treatment of fossil fuel-derived, post-combustion flue gas with aqueous-based technologies. The well-known and widespread contamination of RCRA metals in drinking water and other terrestrial water sources either through natural processes or resulting from human activity, demands remediation.

The invention is a new type of amine-based sorbent material that has increased affinity towards heavy metal capture, from a variety of sources that exceeds the existing amine-sorbent ability by greater than 50%. This invention involves use of a polyamine that is chemically tethered to the surface of a solid silica support through use of a crosslinker and further stabilized through hydrogen bonding with a linker/cross linker. These sorbents can be used for the capture of heavy metals from a variety of aqueous sources. 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 US Resource Conservation and Recovery Act (RCRA) gave the US Environmental Protection Agency the authority to establish and enforce regulatory policies and toxicity limits regarding Arsenic (As), Cadmium (Cd), Chromium (Cr), Lead (Pb), Mercury (Hg), Selenium (Se), and other metals. Many of these metals present a distinct challenge for capture because they are most commonly present in the polyatomic oxy-anion form. Sources for most of these contaminant metals include flue gas desulfurization (FGD) wastewater streams. These streams result from the treatment of fossil fuel-derived, post combustion flue gas with aqueous-based technologies. The well-known and widespread contamination of metals in drinking water and other terrestrial water sources through natural processes or human activity, demands remediation. In addition, radioactive pollutants in aqueous form have raised concerns about exposure levels in the nearby communities because of fears that these fission products could make their way into the food chain.

Research is active on the patent pending technology titled, “MSE-Based Drilling Optimization Using Neural Network Simulation.” This technology is available for licensing and/or further collaborative research from the U.S. Department of Energy’s National Energy Technology Laboratory.

This invention describes a system and method for detecting corrosion in natural gas pipelines using an optical platform or a wireless platform. 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 U.S. Energy Information Administration states that natural gas accounts for nearly 30 percent of energy consumption in the United States. More than 300,000 miles of natural gas transmission and gathering lines deliver this valuable energy source to consumers. Like any energy infrastructure, this network of pipelines requires significant maintenance costs. In the case of natural gas pipelines, corrosion accounts for around 25 percent of incidents over the last 30 years, 61 percent of which was caused by internal corrosion.

The corrosion-related annual cost for such incidents amounts to $6 to $10 billion in the United States each year. Therefore, a need exists to monitor corrosion inside of the gas pipelines to implement corrosion mitigation and control before any failure.

This novel patent-pending methane conversion technology employees microwave-assisted catalysis for chemical conversion. 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, primarily composed of methane, is a cheap and abundant domestic resource that can be converted to a wide range of products including liquid transportation fuels and a wide range of chemical intermediates. However, traditional methods of converting methane to valuable chemicals first require it to be converted to synthesis gas.

A direct, one-step, method to convert the methane would have significant advantages over current indirect methods, including reduced costs and increased yields, but several technology barriers must first be overcome. Microwave-assisted catalyst reactions can provide a viable direct method for overcoming these barriers.

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.