Molecular layer deposition (MLD) is able to produce ultrathin polymer films with control over thickness, cross-linking, and chemical composition. With these capabilities, MLD should be useful in the fabrication of novel polymer membranes on porous supports. However, confining a continuous MLD film to the surface of porous substrates is difficult because of MLD film growth in the pores. The deposition in the pores lowers the conductance of the porous support. This paper presents a method to deposit continuous polymer films on top of porous substrates. In this method, Al2O3 plasma-enhanced atomic layer deposition (PE-ALD) using trimethylaluminum and oxygen plasma as the reactants was first used to cap the pores of the substrate. Subsequently, a polyamide MLD film was deposited on the Al2O3 PE-ALD capping layer using m-phenylenediamine and trimesoyl chloride as the reactants. The Al2O3 pore caps were then removed from the porous substrate by etching from the backside using a timed exposure to a dilute sodium hydroxide solution. This method was demonstrated using anodic aluminum oxide (AAO) and polyethersulfone (PES) porous substrates. Al2O3 PE-ALD film growth was limited to the top of the porous substrate, resulting in rapid surface recombination or high sticking coefficients for the reactive plasma species within the pores. Gas permeance measurements confirmed the pore capping of the AAO substrates. The reopening of the pores by dissolving the Al2O3 pore caps with a sodium hydroxide solution was monitored using gas permeance versus etch time. The removal of the Al2O3 pore caps from the PES substrates could also dissolve the Al2O3 layer underneath the MLD film. The loss of this Al2O3 layer led to the detachment of the MLD film from the PES substrate. However, the MLD film could be anchored to the PES support at fractures located in the Al2O3 film prior to the MLD. The Al2O3 film fracture allowed the MLD film to anchor firmly to the PES substrate by MLD in the pores of the PES porous substrate. The distance between the anchor points was a function of fracture density. This distance could be controlled by applying a tensile stress to the Al2O3 PE-ALD film to fracture the film through sample bending. This method produced firmly anchored polymer MLD films on top of the PES porous substrates.
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Continuous polymer films deposited on top of porous substrates using plasma-enhanced atomic layer deposition and molecular layer deposition
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September 2020
Research Article|
August 24 2020
Continuous polymer films deposited on top of porous substrates using plasma-enhanced atomic layer deposition and molecular layer deposition
Special Collection:
Atomic Layer Deposition (ALD)
Brian C. Welch
;
Brian C. Welch
1
Department of Mechanical Engineering, University of Colorado
, Boulder, Colorado 80309
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Olivia M. McIntee
;
Olivia M. McIntee
1
Department of Mechanical Engineering, University of Colorado
, Boulder, Colorado 80309
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Anand B. Ode
;
Anand B. Ode
2
Department of Chemistry, University of Colorado
, Boulder, Colorado 80309
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Bonnie B. McKenzie;
Bonnie B. McKenzie
3
Sandia National Laboratories
, Albuquerque, New Mexico 87185
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Alan R. Greenberg
;
Alan R. Greenberg
1
Department of Mechanical Engineering, University of Colorado
, Boulder, Colorado 803094
Membrane Science, Engineering and Technology Center, University of Colorado
, Boulder, Colorado 80309
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Victor M. Bright
;
Victor M. Bright
1
Department of Mechanical Engineering, University of Colorado
, Boulder, Colorado 80309
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Steven M. George
Steven M. George
2
Department of Chemistry, University of Colorado
, Boulder, Colorado 80309
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Note: This paper is part of the 2021 Special Topic Collection on Atomic Layer Deposition (ALD).
J. Vac. Sci. Technol. A 38, 052409 (2020)
Article history
Received:
April 19 2020
Accepted:
July 21 2020
Citation
Brian C. Welch, Olivia M. McIntee, Anand B. Ode, Bonnie B. McKenzie, Alan R. Greenberg, Victor M. Bright, Steven M. George; Continuous polymer films deposited on top of porous substrates using plasma-enhanced atomic layer deposition and molecular layer deposition. J. Vac. Sci. Technol. A 1 September 2020; 38 (5): 052409. https://doi.org/10.1116/6.0000271
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