Single Entity Electrochemistry and Its Application to Nanomaterial Synthesis
Single entity analysis is an important research topic in electrochemistry. Thus far, collisions of nanomaterials and subsequent interaction between electrodes and particles have been studied. Single entity electrochemistry exhibited inherent heterogeneity distinct from that of ensembles. By showing...
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Published in | Israel journal of chemistry Vol. 63; no. 12 |
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Language | English |
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01.12.2023
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Abstract | Single entity analysis is an important research topic in electrochemistry. Thus far, collisions of nanomaterials and subsequent interaction between electrodes and particles have been studied. Single entity electrochemistry exhibited inherent heterogeneity distinct from that of ensembles. By showing various current responses, single entity electrochemistry allows us to investigate the adsorbed chemical species on the electrode surface (dielectrics, hard nanoparticles, soft nanoparticles), enabling analysis of electrode‐particle interaction at the nanoscale. Electrochemical analysis of soft nanoparticles enabled the detection of biological materials and was applied to the synthesis of nanoparticles to be used as electrocatalysts. It shows great promise as a synthetic method for various structures of nanoparticles by reducing metal ions volume confined emulsion nanodroplets. |
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AbstractList | Single entity analysis is an important research topic in electrochemistry. Thus far, collisions of nanomaterials and subsequent interaction between electrodes and particles have been studied. Single entity electrochemistry exhibited inherent heterogeneity distinct from that of ensembles. By showing various current responses, single entity electrochemistry allows us to investigate the adsorbed chemical species on the electrode surface (dielectrics, hard nanoparticles, soft nanoparticles), enabling analysis of electrode‐particle interaction at the nanoscale. Electrochemical analysis of soft nanoparticles enabled the detection of biological materials and was applied to the synthesis of nanoparticles to be used as electrocatalysts. It shows great promise as a synthetic method for various structures of nanoparticles by reducing metal ions volume confined emulsion nanodroplets. Abstract Single entity analysis is an important research topic in electrochemistry. Thus far, collisions of nanomaterials and subsequent interaction between electrodes and particles have been studied. Single entity electrochemistry exhibited inherent heterogeneity distinct from that of ensembles. By showing various current responses, single entity electrochemistry allows us to investigate the adsorbed chemical species on the electrode surface (dielectrics, hard nanoparticles, soft nanoparticles), enabling analysis of electrode‐particle interaction at the nanoscale. Electrochemical analysis of soft nanoparticles enabled the detection of biological materials and was applied to the synthesis of nanoparticles to be used as electrocatalysts. It shows great promise as a synthetic method for various structures of nanoparticles by reducing metal ions volume confined emulsion nanodroplets. |
Author | Ahn, Hyokyum Park, Joon Ho Ahn, Hyun S. |
Author_xml | – sequence: 1 givenname: Joon Ho surname: Park fullname: Park, Joon Ho organization: Yonsei University – sequence: 2 givenname: Hyokyum orcidid: 0000-0002-6014-0916 surname: Ahn fullname: Ahn, Hyokyum organization: Yonsei University – sequence: 3 givenname: Hyun S. surname: Ahn fullname: Ahn, Hyun S. email: ahnhs@yonsei.ac.kr organization: Yonsei University |
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Snippet | Single entity analysis is an important research topic in electrochemistry. Thus far, collisions of nanomaterials and subsequent interaction between electrodes... Abstract Single entity analysis is an important research topic in electrochemistry. Thus far, collisions of nanomaterials and subsequent interaction between... |
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SubjectTerms | Biological materials Chemical synthesis Electrocatalysts Electrochemical analysis Electrochemistry electrodeposition Electrodes emulsion Heterogeneity Nanomaterials Nanoparticles Particle interactions single entity electrochemistry |
Title | Single Entity Electrochemistry and Its Application to Nanomaterial Synthesis |
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