Defining plasma polymerization: New insight into what we should be measuring

Andrew Michelmore; Christine Charles; Rod W. Boswell; Robert D. Short; Jason D. Whittle

doi:10.1021/am401484b

Defining plasma polymerization: New insight into what we should be measuring

Andrew Michelmore^*, Christine Charles, Rod W. Boswell, Robert D. Short, Jason D. Whittle

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

32 Citations (Scopus)

Abstract

External parameters (RF power and precursor flow rate) are typically quoted to define plasma polymerization experiments. Utilizing a parallel-plate electrode reactor with variable geometry, it is shown that these parameters cannot be transferred to reactors with different geometries in order to reproduce plasma polymer films using four precursors. Measurements of ion flux and power coupling efficiency confirm that intrinsic plasma properties vary greatly with reactor geometry at constant applied RF power. It is further demonstrated that controlling intrinsic parameters, in this case the ion flux, offers a more widely applicable method of defining plasma polymerization processes, particularly for saturated and allylic precursors.

Original language	English
Pages (from-to)	5387-5391
Number of pages	5
Journal	ACS applied materials & interfaces
Volume	5
Issue number	12
DOIs	https://doi.org/10.1021/am401484b
Publication status	Published - 26 Jun 2013

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title = "Defining plasma polymerization: New insight into what we should be measuring",

abstract = "External parameters (RF power and precursor flow rate) are typically quoted to define plasma polymerization experiments. Utilizing a parallel-plate electrode reactor with variable geometry, it is shown that these parameters cannot be transferred to reactors with different geometries in order to reproduce plasma polymer films using four precursors. Measurements of ion flux and power coupling efficiency confirm that intrinsic plasma properties vary greatly with reactor geometry at constant applied RF power. It is further demonstrated that controlling intrinsic parameters, in this case the ion flux, offers a more widely applicable method of defining plasma polymerization processes, particularly for saturated and allylic precursors.",

keywords = "deposition rate, functional retention, ion flux, plasma polymerization",

author = "Andrew Michelmore and Christine Charles and Boswell, \{Rod W.\} and Short, \{Robert D.\} and Whittle, \{Jason D.\}",

year = "2013",

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doi = "10.1021/am401484b",

language = "English",

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journal = "ACS applied materials \& interfaces",

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T1 - Defining plasma polymerization

T2 - New insight into what we should be measuring

AU - Michelmore, Andrew

AU - Charles, Christine

AU - Boswell, Rod W.

AU - Short, Robert D.

AU - Whittle, Jason D.

PY - 2013/6/26

Y1 - 2013/6/26

N2 - External parameters (RF power and precursor flow rate) are typically quoted to define plasma polymerization experiments. Utilizing a parallel-plate electrode reactor with variable geometry, it is shown that these parameters cannot be transferred to reactors with different geometries in order to reproduce plasma polymer films using four precursors. Measurements of ion flux and power coupling efficiency confirm that intrinsic plasma properties vary greatly with reactor geometry at constant applied RF power. It is further demonstrated that controlling intrinsic parameters, in this case the ion flux, offers a more widely applicable method of defining plasma polymerization processes, particularly for saturated and allylic precursors.

AB - External parameters (RF power and precursor flow rate) are typically quoted to define plasma polymerization experiments. Utilizing a parallel-plate electrode reactor with variable geometry, it is shown that these parameters cannot be transferred to reactors with different geometries in order to reproduce plasma polymer films using four precursors. Measurements of ion flux and power coupling efficiency confirm that intrinsic plasma properties vary greatly with reactor geometry at constant applied RF power. It is further demonstrated that controlling intrinsic parameters, in this case the ion flux, offers a more widely applicable method of defining plasma polymerization processes, particularly for saturated and allylic precursors.

KW - deposition rate

KW - functional retention

KW - ion flux

KW - plasma polymerization

UR - https://www.scopus.com/pages/publications/84879530626

U2 - 10.1021/am401484b

DO - 10.1021/am401484b

M3 - Article

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VL - 5

SP - 5387

EP - 5391

JO - ACS applied materials & interfaces

JF - ACS applied materials & interfaces

IS - 12

ER -

Defining plasma polymerization: New insight into what we should be measuring

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