TS-074813 — Thermoelectric technologies offer a compelling route for waste heat recovery, solid-state cooling, and power generation, but their adoption remains limited by inherently low efficiency. Conventional materials are constrained by tradeoffs between electrical conductivity, thermopower, and thermal co…

TS-074726 — Potassium-based batteries are attractive for large-scale energy storage due to potassium’s abundance and favorable electrochemical properties. However, commercial development is limited by the lack of suitable solid electrolytes that combine high potassium-ion conductivity, chemical stability wi…

TS-074433 — Researchers and organizations studying polar and marine environments increasingly rely on ice cores to understand climate processes, contaminant transport, and biogeochemical change. However, existing ice core processing tools are largely optimized for relatively clean, homogeneous samples and str…

TS-074344 — Air conditioning is a major driver of global electricity demand, peak load stress, and greenhouse gas emissions, particularly in hot and humid climates. Conventional vapor-compression systems rely on electricity-intensive compressors, struggle with efficient humidity control, and are poorly matche…

TS-074333 — Chemical batteries provide high power output but are constrained by finite stored energy and the need for periodic recharging. This is often impossible in remote, sealed, or radiation‑intensive environments such as space systems, subsea platforms, and isolated terrestrial installations. Radiovol…

TS-074271 — Predictable, chemistry level control of biodegradable polymer behavior to simplify development, improve reproducibility, and enable differentiated biomedical products.

TS-074219 — This early‑stage electrochemical platform enables integrated CO₂ capture and permanent mineralization while supporting lower‑energy hydrogen production, offering a research‑driven pathway toward energy system decarbonization.

TS-074084 —

TS-074050 — As batteries are pushed toward faster charging and higher power operation, conventional electrode architectures struggle to deliver their full theoretical capacity. Dense electrodes often suffer from poor ion and electron transport, leading to large capacity losses at high charge and discharge rat…

TS-073880 — Industrial CO₂ electroreduction remains limited by high energy input, poor selectivity, and low formation rates of valuable multi‑carbon products. Conventional copper catalysts often favor hydrogen evolution or low‑value C₁ products such as methane, while catalysts that improve selectivity…