Liquid metal nanolayer-linked MOF nanocomposites by laser shock evaporation

Abstract

Main text(Matter 4, 1–14; December 1, 2021)In this article, the authors originally stated “The LM nanolayer acts as a 3D heat-conductive highway that covers the MOF crystals uniformly, which boosts the thermal conductivity up to three times more than pristine MOFs without sacrificing their high porosity” in the Progress and Potential section of the article. The authors had mistakenly typed the value of “three times” from preliminary results, and the correct performance observed is “thermal conductivity up to five times more than pristine MOFs,” derived from the most recent results demonstrated in the paper. The authors apologize for any confusion. Main text(Matter 4, 1–14; December 1, 2021)In this article, the authors originally stated “The LM nanolayer acts as a 3D heat-conductive highway that covers the MOF crystals uniformly, which boosts the thermal conductivity up to three times more than pristine MOFs without sacrificing their high porosity” in the Progress and Potential section of the article. The authors had mistakenly typed the value of “three times” from preliminary results, and the correct performance observed is “thermal conductivity up to five times more than pristine MOFs,” derived from the most recent results demonstrated in the paper. The authors apologize for any confusion. (Matter 4, 1–14; December 1, 2021) In this article, the authors originally stated “The LM nanolayer acts as a 3D heat-conductive highway that covers the MOF crystals uniformly, which boosts the thermal conductivity up to three times more than pristine MOFs without sacrificing their high porosity” in the Progress and Potential section of the article. The authors had mistakenly typed the value of “three times” from preliminary results, and the correct performance observed is “thermal conductivity up to five times more than pristine MOFs,” derived from the most recent results demonstrated in the paper. The authors apologize for any confusion. Liquid metal nanolayer-linked MOF nanocomposites by laser shock evaporationAn et al.MatterOctober 27, 2021In BriefLow thermal conductivity of metal-organic frameworks (MOFs) restricts their kinetic performance. Here, we demonstrate a facile and straightforward manufacturing method, laser shock-induced evaporation, to deposit uniform liquid metal (LM) nanolayers on MOFs. Localized evaporation induced by selective laser absorption in LM fragments LM and deposits it as a thin layer on MOF surfaces. The layer acts as a 3D heat-conductive highway that boosts the thermal conductivity of [email protected] up to 500% compared with pristine MOFs. Full-Text PDF