Advances in plasma-driven solution electrochemistry

Peter J. Bruggeman; Renee R. Frontiera; Uwe Kortshagen; Mark J. Kushner; Suljo Linic; George C. Schatz; Himashi Andaraarachchi; Subhajyoti Chaudhuri; Han Ting Chen; Collin D. Clay; Tiago C. Dias; Scott Doyle; Leighton O. Jones; Mackenzie Meyer; Chelsea M. Mueller; Jae Hyun Nam; Astrid Raisanen; Christopher C. Rich; Tanubhav Srivastava; Chi Xu; Dongxuan Xu; Yi Zhang

doi:10.1063/5.0248579

Advances in plasma-driven solution electrochemistry

Peter J. Bruggeman (Corresponding author-nrf)
, Renee R. Frontiera
, Uwe Kortshagen
, Mark J. Kushner
, Suljo Linic
, George C. Schatz
, Himashi Andaraarachchi
, Subhajyoti Chaudhuri
, Han Ting Chen
, Collin D. Clay
, Tiago C. Dias
, Scott Doyle
, Leighton O. Jones
, Mackenzie Meyer
, Chelsea M. Mueller
, Jae Hyun Nam
, Astrid Raisanen
, Christopher C. Rich
, Tanubhav Srivastava
, Chi Xu

Dongxuan Xu, Yi Zhang

Research output: Contribution to journal › Review article › peer-review

12 Citations (Scopus)

Abstract

Energetic species produced by gas-phase plasmas that impinge on a liquid surface can initiate physicochemical processes at the gas/liquid interface and in the liquid phase. The interaction of these energetic species with the liquid phase can initiate chemical reaction pathways referred to as plasma-driven solution electrochemistry (PDSE). There are several processing opportunities and challenges presented by PDSE. These include the potential use of PDSE to activate chemical pathways that are difficult to activate with other approaches as well as the use of renewable electricity to generate plasmas that could make these liquid-phase chemical conversion processes more sustainable and environmentally friendly. In this review, we focus on PDSE as an approach for controlled and selective chemical conversion including the synthesis of nanoparticles and polymers with desired but currently uncontrollable or unattainable properties as the next step in the use of PDSE. The underpinning redox chemistry and transport processes of PDSE are reviewed as many PDSE-driven processes are transport-limited due to the many short-lived highly reactive species involved.

Original language	English
Article number	071001
Journal	Journal of Chemical Physics
Volume	162
Issue number	7
DOIs	https://doi.org/10.1063/5.0248579
Publication status	Published - 21 Feb 2025
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2025 Author(s).

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

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10.1063/5.0248579

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Bruggeman, P. J., Frontiera, R. R., Kortshagen, U., Kushner, M. J., Linic, S., Schatz, G. C., Andaraarachchi, H., Chaudhuri, S., Chen, H. T., Clay, C. D., Dias, T. C., Doyle, S., Jones, L. O., Meyer, M., Mueller, C. M., Nam, J. H., Raisanen, A., Rich, C. C., Srivastava, T., ... Zhang, Y. (2025). Advances in plasma-driven solution electrochemistry. Journal of Chemical Physics, 162(7), Article 071001. https://doi.org/10.1063/5.0248579

@article{9521dbc8cfca4bb498a1ccdd9494818d,

title = "Advances in plasma-driven solution electrochemistry",

abstract = "Energetic species produced by gas-phase plasmas that impinge on a liquid surface can initiate physicochemical processes at the gas/liquid interface and in the liquid phase. The interaction of these energetic species with the liquid phase can initiate chemical reaction pathways referred to as plasma-driven solution electrochemistry (PDSE). There are several processing opportunities and challenges presented by PDSE. These include the potential use of PDSE to activate chemical pathways that are difficult to activate with other approaches as well as the use of renewable electricity to generate plasmas that could make these liquid-phase chemical conversion processes more sustainable and environmentally friendly. In this review, we focus on PDSE as an approach for controlled and selective chemical conversion including the synthesis of nanoparticles and polymers with desired but currently uncontrollable or unattainable properties as the next step in the use of PDSE. The underpinning redox chemistry and transport processes of PDSE are reviewed as many PDSE-driven processes are transport-limited due to the many short-lived highly reactive species involved.",

author = "Bruggeman, \{Peter J.\} and Frontiera, \{Renee R.\} and Uwe Kortshagen and Kushner, \{Mark J.\} and Suljo Linic and Schatz, \{George C.\} and Himashi Andaraarachchi and Subhajyoti Chaudhuri and Chen, \{Han Ting\} and Clay, \{Collin D.\} and Dias, \{Tiago C.\} and Scott Doyle and Jones, \{Leighton O.\} and Mackenzie Meyer and Mueller, \{Chelsea M.\} and Nam, \{Jae Hyun\} and Astrid Raisanen and Rich, \{Christopher C.\} and Tanubhav Srivastava and Chi Xu and Dongxuan Xu and Yi Zhang",

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doi = "10.1063/5.0248579",

language = "English",

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Bruggeman, PJ, Frontiera, RR, Kortshagen, U, Kushner, MJ, Linic, S, Schatz, GC, Andaraarachchi, H, Chaudhuri, S, Chen, HT, Clay, CD, Dias, TC, Doyle, S, Jones, LO, Meyer, M, Mueller, CM, Nam, JH, Raisanen, A, Rich, CC, Srivastava, T, Xu, C, Xu, D & Zhang, Y 2025, 'Advances in plasma-driven solution electrochemistry', Journal of Chemical Physics, vol. 162, no. 7, 071001. https://doi.org/10.1063/5.0248579

TY - JOUR

T1 - Advances in plasma-driven solution electrochemistry

AU - Frontiera, Renee R.

AU - Kortshagen, Uwe

AU - Kushner, Mark J.

AU - Linic, Suljo

AU - Schatz, George C.

AU - Andaraarachchi, Himashi

AU - Chaudhuri, Subhajyoti

AU - Chen, Han Ting

AU - Clay, Collin D.

AU - Dias, Tiago C.

AU - Doyle, Scott

AU - Jones, Leighton O.

AU - Meyer, Mackenzie

AU - Mueller, Chelsea M.

AU - Nam, Jae Hyun

AU - Raisanen, Astrid

AU - Rich, Christopher C.

AU - Srivastava, Tanubhav

AU - Xu, Chi

AU - Xu, Dongxuan

AU - Zhang, Yi

A2 - Bruggeman, Peter J.

PY - 2025/2/21

Y1 - 2025/2/21

N2 - Energetic species produced by gas-phase plasmas that impinge on a liquid surface can initiate physicochemical processes at the gas/liquid interface and in the liquid phase. The interaction of these energetic species with the liquid phase can initiate chemical reaction pathways referred to as plasma-driven solution electrochemistry (PDSE). There are several processing opportunities and challenges presented by PDSE. These include the potential use of PDSE to activate chemical pathways that are difficult to activate with other approaches as well as the use of renewable electricity to generate plasmas that could make these liquid-phase chemical conversion processes more sustainable and environmentally friendly. In this review, we focus on PDSE as an approach for controlled and selective chemical conversion including the synthesis of nanoparticles and polymers with desired but currently uncontrollable or unattainable properties as the next step in the use of PDSE. The underpinning redox chemistry and transport processes of PDSE are reviewed as many PDSE-driven processes are transport-limited due to the many short-lived highly reactive species involved.

AB - Energetic species produced by gas-phase plasmas that impinge on a liquid surface can initiate physicochemical processes at the gas/liquid interface and in the liquid phase. The interaction of these energetic species with the liquid phase can initiate chemical reaction pathways referred to as plasma-driven solution electrochemistry (PDSE). There are several processing opportunities and challenges presented by PDSE. These include the potential use of PDSE to activate chemical pathways that are difficult to activate with other approaches as well as the use of renewable electricity to generate plasmas that could make these liquid-phase chemical conversion processes more sustainable and environmentally friendly. In this review, we focus on PDSE as an approach for controlled and selective chemical conversion including the synthesis of nanoparticles and polymers with desired but currently uncontrollable or unattainable properties as the next step in the use of PDSE. The underpinning redox chemistry and transport processes of PDSE are reviewed as many PDSE-driven processes are transport-limited due to the many short-lived highly reactive species involved.

UR - https://www.scopus.com/pages/publications/85218356769

U2 - 10.1063/5.0248579

DO - 10.1063/5.0248579

M3 - Review article

C2 - 39968819

AN - SCOPUS:85218356769

SN - 0021-9606

VL - 162

JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

IS - 7

M1 - 071001

ER -

Advances in plasma-driven solution electrochemistry

Abstract

Bibliographical note

UN SDGs

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