High temperature stable selective emitters can significantly increase efficiency and radiative power in thermophotovoltaic (TPV) systems. However, optical properties of structured emitters reported so far degrade at temperatures approaching 1200?°C due to various degradation mechanisms. We have realized a 1D structured emitter based on a sputtered W-HfOsub2/sub layered metamaterial and demonstrated desired band edge spectral properties at 1400?°C. To the best of our knowledge the temperature of 1400?°C is the highest reported for a structured emitter, so far. The spatial confinement and absence of edges stabilizes the W-HfOsub2/sub multilayer system to temperatures unprecedented for other nanoscaled W-structures. Only when this confinement is broken W starts to show the well-known self-diffusion behavior transforming to spherical shaped W-islands. We further show that the oxidation of W by atmospheric oxygen could be prevented by reducing the vacuum pressure below 10sup-5/sup?mbar. When oxidation is mitigated we observe that the 20?nm spatially confined W films survive temperatures up to 1400?°C. The demonstrated thermal stability is limited by grain growth in HfOsub2/sub, which leads to a rupture of the W-layers, thus, to a degradation of the multilayer system at 1450?°C.
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