Handbook of Laser Micro- And Nano-Engineering 2021
DOI: 10.1007/978-3-030-63647-0_30
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Laser Ablation in Liquids for Nanomaterial Synthesis and Applications

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Cited by 5 publications
(2 citation statements)
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“…Subsequently, primary NPs are formed in the liquid media through condensation nucleation, [ 6 ] while coalescence and growth contribute to the formation of larger secondary particle. [ 7–9 ] The production of NPs by PLAL offers several advantages, including the synthesis of surfactant‐free NPs; [ 10,11 ] the versatility of the process [ 12,13 ] that allows the generation of metallic; [ 14 ] alloyed metal, [ 15 ] oxide, [ 16 ] ceramic, [ 17 ] and organic NPs; [ 18 ] and the ability to produce NPs with complex structures and compositions that poses a challenge for standard chemical methods, [ 19–24 ] such as metastable bimetallic alloys, [ 25,26 ] or high‐entropy alloy NPs. [ 22 ] Producing NPs with a surfactant‐free surface is a highly desirable property in the field of biomedicine and catalysis [ 27 ] as the surface composition of the NPs strongly influences the biocompatibility and the cytotoxicity of the NPs, [ 28 ] the specific surface area of the nano‐catalysts, [ 2,10,29,30 ] and generally the active surface sites for light conversion, harvesting, and sensing.…”
Section: Introductionmentioning
confidence: 99%
“…Subsequently, primary NPs are formed in the liquid media through condensation nucleation, [ 6 ] while coalescence and growth contribute to the formation of larger secondary particle. [ 7–9 ] The production of NPs by PLAL offers several advantages, including the synthesis of surfactant‐free NPs; [ 10,11 ] the versatility of the process [ 12,13 ] that allows the generation of metallic; [ 14 ] alloyed metal, [ 15 ] oxide, [ 16 ] ceramic, [ 17 ] and organic NPs; [ 18 ] and the ability to produce NPs with complex structures and compositions that poses a challenge for standard chemical methods, [ 19–24 ] such as metastable bimetallic alloys, [ 25,26 ] or high‐entropy alloy NPs. [ 22 ] Producing NPs with a surfactant‐free surface is a highly desirable property in the field of biomedicine and catalysis [ 27 ] as the surface composition of the NPs strongly influences the biocompatibility and the cytotoxicity of the NPs, [ 28 ] the specific surface area of the nano‐catalysts, [ 2,10,29,30 ] and generally the active surface sites for light conversion, harvesting, and sensing.…”
Section: Introductionmentioning
confidence: 99%
“…Maga az ablációs rendszer egyszerű felépítésű, kevés eszközigényű, megfelelő biztonsági tréning mellett biztonsággal üzemeltethető rövid betanulás után. [71], [145] Hátrányai között szerepel a degradáció lehetősége és elrendezéstől függően a keltett részecskék esetleges aggregációja. Az alkalmazott lézertípus függvényében megfontolandó lehet a beszerzési és karbantartási költség, valamint a biztonsági előírások hozadékai is.…”
Section: Lézeres Abláció a Gyógyszeriparbanunclassified