Available Technologies

The present invention comprises a new sodium based electrolyte system that has an electrochemical window of 4V, which is suitable for use as electrolytes for high energy density supercapacitors.

Membrane-based dispersion-free supported liquid membrane solvent extraction (MSX) for the separation, concentration and recovery of rare earth elements such as neodymium, europium, yttrium, terbium and dysprosium enables the process to operate in a single step delivering multi

This invention targets the extraction of rare earth elements from fly ash residues. The residues are leached and the aqueous phase is then extracted using an organic phase.

This invention affords the quantitative extraction of rare earths present in phosphoric acid streams produced in phosphoric acid plants. The stream is typically 27%-30% P2O5 while the total amount of rare earths is estimated at 150-200 ppm.

A lubricant additive is an ionic liquid phosphonium salt. The phosphonium cation of the ionic liquid is in a symmetric quaternary structure ([PR4]+) having four hydrocarbyl groups with the same number (>=4) of carbon atoms.

The invention relates to testing systems and more specifically to systems for cryogenic characterization.

The present invention comprises ultrathin (<1 µm) high permselectivity carbon molecular sieve membranes (CMSM) for industrial gas separations.

The present invention comprises a new sol-gel precursor chemistry that will form flexible tin-doped indium oxide (ITO) nanofibers at diameters of 50-400nm.

A method has been developed at ORNL that selectively dissolves both aluminum and magnesium from aluminum based alloys in a non-aqueous solvent.

This invention describes a new method to prepare catalyst beads of bulk transition metal carbides, nitrides, and phosphides thereby expanding the area of potential industrial applications of these catalytic materials as unsupported bulk catalysts.