In this article, we provide a perspective overview of the iconic properties, recent application-oriented research, and future commercialization opportunities of thin film metallic glasses (TFMGs). A brief review on the preparation and fundamental properties of TFMGs will be given first. TFMGs possess attractive properties such as corrosion resistance, extremely low roughness, and antibacterial characteristics, which give rise to various applications in biomedical devices, sensors, and tribology. Therefore, a number of our representative works will be reviewed to showcase the benefits of TFMGs over traditional materials and processing in these applications. In addition, new perspectives in the research and development of TFMGs and opportunities for commercialization will also be highlighted.
Elastic
moduli, E, of free-standing polystyrene
(PS) single-layers and polystyrene–polydimethylsiloxane (PS-PDMS)
bilayers are measured by uniaxial tensile testing at room temperature
under different strain rates, γ̇, and for PS thicknesses, h, from 8 to 130 nm. As γ̇ increases, E increases initially, then approaches the bulk value, E
bulk, when γ̇ exceeds a characteristic
value (≡ τ–1) that decreases with increasing h. The noted variation of E with γ̇
shows that stress relaxation occurs in the films during measurement
when γ̇τ ≪ 1, while the noted variation of
τ–1 with h shows that thinner
films relax faster. Consequently, E decreases with
decreasing h if γ̇ is small, but displays
independence of h if γ̇ is large. Visually,
the crossover takes place at around γ̇ = 0.0015 s–1, where at γ̇τ > 1 for all films.
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This paper demonstrates a stainless-steel (SS) nano-pyramid structure (diameter of ~20–50 nm and pore size of 156.1 nm) sputter-coated on mixed cellulose ester (MCE) membrane for the use in separation of oil/water emulsions. SS-coated MCE membrane presented a superhydrophilic, antifouling surface as well as underwater superoleophobicity. The coated membrane achieved excellent separation efficiency of >99% when applied to light oil-water emulsions with a range of viscosities and densities. The highest permeation flux measured was 1,555 L m−2 h−1 when applied to toluene-in-water emulsions. The membrane also presented outstanding recyclability, as evidenced by oil rejection rate retaining at >99% through four separation cycles. The coated membrane was also shown to work well under harsh conditions including salty water, extreme pH values (1–14), and high temperatures (60 °C). In addition, our fabrication route of SS-coated MCE employs low process temperature while being highly scalable, which is favorable for industrial-scale applications.
A new method to fabricate an Au-rich interconnected ligament substrate by dealloying the Au-based metallic glass ribbon for surface-enhanced Raman scattering (SERS) applications was investigated in this study. Specifically, three substrates, Au film, Au-based metallic glass ribbon, and dealloyed Au-based metallic glass ribbon, were studied. The dealloyed surface showed ligament nanostructure with protruding micro-islands. Based on the field emission scanning electron microscopy, reflection and scattering measurements, the dealloyed Au-based metallic glass provided a large surface area, multiple reflections, and numerous fine interstices to produce hot spots for SERS enhancements. The SERS signal of analyte, p-aminothiophenol, in the micro-island region of dealloyed Au-based metallic glass was about 2 orders of magnitude larger than the flat Au film. Our work provides a new method to fabricate the inexpensive and high SERS enhancements substrates.
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