Mechanical Properties of Thin-Film Parylene–Metal–Parylene Devices
نویسندگان
چکیده
Structures and testing methods for measuring the adhesion strength, minimum bending diameter, and bending fatigue performance of thin-film polymer electronic architectures were developed and applied to Parylene–metal–Parylene systems with and without the moisture barrier Al2O3 [deposited using atomic layer deposition (ALD)]. Parylene–metal– Parylene interfaces had the strongest average peel test strength and Parylene–Parylene interfaces had the weakest peel test strength. Layers of ALD Al2O3 deposited within the device increased the average peel strength for Parylene–Parylene interfaces when combined with silane A-174, but did not increase that of the Parylene–metal–Parylene interface. Metal traces in the middle of 24 μm thick Parylene–metal–Parylene devices had a minimum bending diameter of ~130 μm before breaking and being measured as an open circuit. The addition of one layer of Al2O3 above the traces allowed them to be completely creased when bent away from the Al2O3 layer without producing an open circuit, but increased the minimum bending diameter to ~450 μm when bent towards the Al2O3. Although fatigue testing produced cracks in all devices after 100k bends, the insulation of the Parylene–metal–Parylene devices without Al2O3 performed well with electrochemical impedance spectroscopy showing only small decreases in impedance magnitude and small increases of impedance phase at low frequencies. However, devices with Al2O3 failed during EIS due to Al2O3 being deteriorated by water.
منابع مشابه
Formation of three-dimensional Parylene C structures via thermoforming
The thermoplastic nature of Parylene C is leveraged to enable the formation of three-dimensional structures using a thermal forming (thermoforming) technique. Thermoforming involves the heating of Parylene films above its glass transition temperature while they are physically confined in the final desired conformation. Micro and macro scale three-dimensional structures composed of Parylene thin...
متن کاملTowards flexible organic thin film transistors (OTFTs) for biosensing
We have studied parylene-N and parylene-C for their use as substrates and gate dielectrics in OTFTs. Parylene-N films with a thickness of 300 nm show the required dielectric properties, as verified by breakthrough-voltage measurements. The surface roughness measured for 300 nm thick parylene-N films is 4–5 nm. However, initial growth of parylene depends on the subjacent surface. This results in...
متن کاملHigh Aspect Ratio Parylene Etching for Microfluidics and Biomems
A novel technique for producing high aspect ratio parylene structures via switching chemistry plasma etching is presented. Parylene C, or poly(monochloro-p-xylylene), has become an increasingly popular MEMS material for its excellent properties and biocompatibility. However, the inability to fabricate closely-spaced high aspect ratio (HAR) structures severely limits the use of parylene, particu...
متن کاملRobust mechanical property measurements of fibrous parylene-C thin-film substrate via moiré contouring technology.
Parylene-C is a bio-inert, bio-compatible and relatively inexpensive material with many bio-medical applications from coatings for implantable devices to bio-scaffolds. The main objective of this research was to demonstrate a novel approach to accurately measure the mechanical properties of free-standing fibrous thin-film substrates (TFS) of parylene-C. For that purpose, a two-stage experimenta...
متن کاملCorrosion Behavior of Parylene-Metal-Parylene Thin Films in Saline
In this paper, we study the corrosion behavior of parylene-metalparylene thin films using accelerated-lifetime soak tests. The samples under test are thin film resistors with a 200 nm layer of Au sandwiched by parylene-C on both sides, fabricated with parylenemetal skin technology. The samples are tested in hot saline both passively and actively, and different failure modes are observed using o...
متن کامل