Crystallinity and mechanical effects from annealing Parylene thin films

Parylene is commonly used as thin film polymer for MEMS devices and smart materials. This paper investigates the impact on bulk properties due to annealing various types of Parylene films. A thin film of Parylene N, C and a hybrid material consisting of Parylene N and C were deposited using a standa...

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Bibliographic Details
Published in:Thin solid films 2016-03, Vol.603, p.371-376
Main Authors: Jackson, Nathan, Stam, Frank, O'Brien, Joe, Kailas, Lekshmi, Mathewson, Alan, O'Murchu, Cian
Format: Article
Language:English
Subjects:
Annealing
Crystallinity
Hybrid
Modulus
Parylene
Polymer
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Summary:Parylene is commonly used as thin film polymer for MEMS devices and smart materials. This paper investigates the impact on bulk properties due to annealing various types of Parylene films. A thin film of Parylene N, C and a hybrid material consisting of Parylene N and C were deposited using a standard Gorham process. The thin film samples were annealed at varying temperatures from room temperature up to 300°C. The films were analyzed to determine the mechanical and crystallinity effects due to different annealing temperatures. The results demonstrate that the percentage of crystallinity and the full-width-half-maximum value on the 2θ X-ray diffraction scan increases as the annealing temperature increases until the melting temperature of the Parylene films was achieved. Highly crystalline films of 85% and 92% crystallinity were achieved for Parylene C and N respectively. Investigation of the hybrid film showed that the individual Parylene films behave independently to each other, and the crystallinity of one film had no significant impact to the other film. Mechanical testing showed that the elastic modulus and yield strength increase as a function of annealing, whereas the elongation-to-break parameter decreases. The change in elastic modulus was more significant for Parylene C than Parylene N and this is attributed to the larger change in crystallinity that was observed. Parylene C had a 112% increase in crystallinity compared to a 61% increase for Parylene N, because the original Parylene N material was more crystalline than Parylene C so the change of crystallinity was greater for Parylene C. •A hybrid material consisting of Parylene N and C was developed.•Parylene N has greater crystallinity than Parylene C.•Phase transition of Parylene N due to annealing results in increased crystallinity.•Annealing caused increased crystallinity and elastic modulus in Parylene films.•Annealed hybrid Parylene films crystallinity behave independently.
ISSN:0040-6090
1879-2731
DOI:10.1016/j.tsf.2016.02.047