TS-074441 — Chemical looping gasification and combustion are promising pathways for low‑carbon energy conversion, CO₂ capture, and syngas production, but their commercial deployment is constrained by the performance of available oxygen carrier materials. Existing metal oxide oxygen carriers often suffer f…

TS-073930 — Many industrial gas–solid reactions, such as ironmaking, chemical looping, and other redox-based processes, are fundamentally constrained by thermodynamic equilibrium in conventional reactor designs. Single-inlet/single-outlet reactors force tradeoffs between gas conversion and solid conversion,…

TS-073184 — Direct air capture (DAC) technologies are essential for meeting global carbon‑reduction goals, yet most current systems remain limited by high energy demand, high cost, and materials with insufficient stability. Traditional solid‑sorbent DAC approaches require significant thermal input for reg…

TS-071809 — The Need Syngas is an essential intermediate for producing high-value chemicals such as gasoline, methanol, and dimethyl ether. Current industrial methods (steam reforming, autothermal reforming, and partial oxidation) are energy-intensive, costly, and environmentally burdensome. Moreover, these met…

TS-071808 — The Need Industrial syngas and hydrogen production processes are highly energy-intensive and contribute significantly to carbon emissions due to reliance on fossil fuel combustion. Existing methods require multiple unit operations, resulting in low efficiency and high operational costs. There is a c…

TS-071806 — The Need Current syngas production from methane relies on energy-intensive air separation units (ASUs) to supply molecular oxygen, driving up capital and operating costs. Conventional catalysts also suffer from carbon deposition at low oxidant concentrations, limiting process flexibility and efficie…

TS-061849 — The Rare Earth Element Trap-Extract-Precipitate (REE-TEP) process is a cost-effective and environmentally benign approach to recover rare earth elements (REEs) from acidic waste streams. It involves beneficial reuse of readily available industrial by-products and a naturally occurring organic ligand resulting in REE concentrate that can be commercially processed to produce rare earth oxides (REOs).