Available Technologies

Currently, there is no tool that can enable phase evolution as a function of simultaneous variations in alloy chemistry (multiple alloying elements) and time-temperature during sintering of powder metallurgy alloys.

The recycling process we proposed here is a modified hydrometallurgy method, which is efficient, facile, low- cost and environmentally friendly. Green organic acid and solvent are only two chemicals needed in the closed-loop recycling process.

The invention provides a low-cost, compact electromechanical, versatile, computer-controlled device that can be fitted inside cryostats, closed-cycle refrigerators, and similar cryogenic devices while carrying multiple samples.

Traditional thermosetting polymers are widely used due to their excellent stability and mechanical performance. However, these materials are typically derived from non-renewable petrochemical sources and are difficult to recycle, often ending up in landfills or incinerated.

To promote all electrification and maximize use of renewable energy, electric driven heat pumps need to incorporate energy storage functions.

A novel high flux direct air capture (HiDAC) contactor is developed by using materials to increase the effective surface area for CO2-solvent contact.

In this work, we developed a strong superwood veneer plywood composite. The developed materials have a high strength of ~640 MPa in a direction, which is about 22 times than that in another direction (29 MPa).

The proposed solution provides a pathway towards synthesis and production of high conductivity materials that are needed to enable solid-state batteries.

This technology aims to provide and integrated and oxidation resistant cladding or coating onto carbon-based composites in seconds.