Publications by authors named "Sophia Wahl"
Doping is usually the first step to tailor thermoelectrics. It enables precise control of the charge-carrier concentration and concomitant transport properties. Doping should also turn GeSe, which features an intrinsically a low carrier concentration, into a competitive thermoelectric.
View Article and Find Full Text PDFPhase-change materials (PCMs) allow for non-volatile resonance tuning of nanophotonic components. Upon switching, they offer a large dielectric contrast between their amorphous and crystalline phases. The recently introduced "plasmonic PCM" InSbTe (IST) additionally features in its crystalline phase a sign change of its permittivity over a broad infrared spectral range.
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- * PtSe-based PDs can be directly integrated onto silicon waveguides, achieving a maximum responsivity of 11 mA/W at a wavelength of 1550 nm and fast response times under 8.4 μs.
- * The material shows potential for infrared applications due to its chemical stability, low-temperature growth process, and high carrier mobility, making PtSe ideal for future optoelectronics and photonic-integrated circuits.
The chemical bond is one of the most powerful, yet much debated concepts in chemistry, explaining property trends in solids. Recently, a novel type of chemical bonding was identified in several higher chalcogenides, characterized by a unique property portfolio, unconventional bond breaking, and sharing of about one electron between adjacent atoms. This metavalent bond is a fundamental type of bonding in solids, besides covalent, ionic, and metallic bonding, raising the pertinent question as to whether there is a well-defined transition between metavalent and covalent bonds.
View Article and Find Full Text PDFThe high dielectric optical contrast between the amorphous and crystalline structural phases of non-volatile phase-change materials (PCMs) provides a promising route towards tuneable nanophotonic devices. Here, we employ the next-generation PCM InSbTe (IST) whose optical properties change from dielectric to metallic upon crystallization in the whole infrared spectral range. This distinguishes IST as a switchable infrared plasmonic PCM and enables a programmable nanophotonics material platform.
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