Hongliang Li

Sep 29, 2024 | nature.com | Laihao Luo |Hongliang Li

AbstractAcetone serves as an important solvent and building block for the chemical industry, but the current industrial synthesis of acetone is generally accompanied by the energy-intensive and costly cumene process used for phenol production. Here we propose a sustainable route for acetone synthesis via propane wet reforming at a moderate temperature of 350 oC with the use of platinum-tin nanoparticles supported on γ-aluminium oxide (PtSn/γ-Al2O3) as catalyst.

Jun 27, 2024 | mdpi.com | Chenxi Wang |Hongliang Li |Sang-Shin Lee

All articles published by MDPI are made immediately available worldwide under an open access license. No special permission is required to reuse all or part of the article published by MDPI, including figures and tables. For articles published under an open access Creative Common CC BY license, any part of the article may be reused without permission provided that the original article is clearly cited. For more information, please refer to https://www.mdpi.com/openaccess.

Jun 26, 2024 | science.org | Ellen White |Emil Gustavsson |Xinyang wang |Hongliang Li

AbstractSeamounts are ecological oases nurturing abundant fisheries resources and epibenthic megafauna in the vast oligotrophic ocean. Despite their significance, the formation mechanisms underlying these seamount ecological oases remain uncertain. To shed light on this phenomenon, this study conducted interdisciplinary in situ observations focusing on a shallow seamount in the oligotrophic ocean.

Apr 28, 2024 | nature.com | Hongliang Li |Zhenhua Gu |Zhigang Geng

AbstractThe electrochemical synthesis of propylene oxide is far from practical application due to the limited performance (including activity, stability, and selectivity). In this work, we spatially decouple the bromide-mediated process to avoid direct contact between the anode and propylene, where bromine is generated at the anode and then transferred into an independent reactor to react with propylene.

Apr 19, 2024 | nature.com | Xiangdong Kong |Hongliang Li |Zhigang Geng

AbstractHydroxylamine is an important nitrogenous feedstock for the chemical industry. Conventional hydroxylamine synthesis methods utilize ammonia as the nitrogen source and require harsh reaction conditions, leading to unfavourable environmental footprint. Here we develop a plasma-electrochemical cascade pathway (PECP) powered by electricity for sustainable hydroxylamine synthesis directly from ambient air and water at mild conditions.