{"id":23606,"date":"2025-10-29T17:45:46","date_gmt":"2025-10-29T15:45:46","guid":{"rendered":"https:\/\/www.fbg.ub.edu\/?page_id=23606"},"modified":"2025-10-29T17:45:46","modified_gmt":"2025-10-29T15:45:46","slug":"sustainable-%ce%b3-valerolactone-production-via-photothermal-catalysis","status":"publish","type":"page","link":"https:\/\/www.fbg.ub.edu\/es\/que-hacemos\/tecnologias-materiales-y-licencias\/tecnologias-para-licenciar\/sustainable-%ce%b3-valerolactone-production-via-photothermal-catalysis\/","title":{"rendered":"Sustainable \u03b3-valerolactone Production via Photothermal Catalysis"},"content":{"rendered":"

Executive summary<\/h3>\n

This invention introduces a novel and sustainable photothermal catalytic method for synthesizing \u03b3-valerolactone (GVL), a high-value chemical platform with applications as biofuel, green solvent for the pharma industry, precursor for polymers and perfumery. The process utilizes biomass feedstocks and new scalable nickel-based catalysts that significantly reduce the energy requirements, reaction time and temperature, avoiding H2 gas, and enabling solar synthesis.<\/p>\n

Market need<\/h3>\n

GVL is a bio-based chemical with remarkable industrial potential, primarily due to its derivation from renewable biomass and its versatile properties as a green solvent, fuel additive, and chemical precursor. GVL is poised to replace traditional, hazardous solvents in sectors like pharmaceuticals, agrochemicals, and fine chemicals. Furthermore, it can be catalytically converted into a range of valuable products, including high-energy liquid fuels, polymers, and other specialty chemicals. GVL is a key player in the transition toward a more sustainable and bio-based economy. However, traditional methods for GVL synthesis involve harsh energy intensive conditions or fossil-derived inputs, limiting the environmental and economic viability.<\/p>\n

Proposed solution<\/h3>\n

Sustainable alternative to conventional \u03b3-valerolactone synthesis by:<\/p>\n