High-Entropy Oxide Solar Selective Absorber

[1] Green MA(2015)Solar cell efficiency tables (Version 45) Prog. Photovolt. Res. Appl. 23 1-9

[2] Emery K(2009)Keeping the energy debate clean: how do we supply the world’s energy needs? Proc. IEEE 98 42-66

[3] Hishikawa Y(2013)Characterization of pyromark 2500 paint for high-temperature solar receivers J. Sol. Energy Eng. 246 111898-1606

[4] Warta W(2022)Long-term thermal stability and failure mechanisms of Pyromark 2500 for high-temperature solar thermal receivers Sol. Energy Mater. Sol. Cells 19 100609-232

[5] Dunlop ED(2021)High-efficiency, air-stable manganese–iron oxide nanoparticle-pigmented solar selective absorber coatings toward concentrating solar power systems operating at 750 °C Mater. Today Energy 517 1601-1420

[6] Abbott D(2009)Direct current reactive sputtering Cr–Cr2O3 cermet solar selective surfaces for solar hot water applications Thin Solid Films 122 226-123

[7] Ho CK(2014)The spectral properties and thermal stability of CrAlO-based solar selective absorbing nanocomposite coating Sol. Energy Mater. Sol. Cells 501 144025-18

[8] Mahoney AR(2020)Enhanced thermal stability of solar selective absorber based on nano-multilayered TiAlON films deposited by cathodic arc evaporation Appl. Surf. Sci. 94 1412-2579

[9] Ambrosini A(2010)Structure, optical properties and thermal stability of pulsed sputter deposited high temperature HfOx/Mo/HfO2 solar selective absorbers Sol. Energy Mater. Sol. Cells 2 107-333

[10] Bencomo M(2014)High-entropy alloys: a critical review Mater. Res. Lett. 6 8485-13

[1] Green MA(2015)Solar cell efficiency tables (Version 45) Prog. Photovolt. Res. Appl. 23 1-9

[2] Emery K(2009)Keeping the energy debate clean: how do we supply the world’s energy needs? Proc. IEEE 98 42-66

[3] Hishikawa Y(2013)Characterization of pyromark 2500 paint for high-temperature solar receivers J. Sol. Energy Eng. 246 111898-1606

[4] Warta W(2022)Long-term thermal stability and failure mechanisms of Pyromark 2500 for high-temperature solar thermal receivers Sol. Energy Mater. Sol. Cells 19 100609-232

[5] Dunlop ED(2021)High-efficiency, air-stable manganese–iron oxide nanoparticle-pigmented solar selective absorber coatings toward concentrating solar power systems operating at 750 °C Mater. Today Energy 517 1601-1420

[6] Abbott D(2009)Direct current reactive sputtering Cr–Cr2O3 cermet solar selective surfaces for solar hot water applications Thin Solid Films 122 226-123

[7] Ho CK(2014)The spectral properties and thermal stability of CrAlO-based solar selective absorbing nanocomposite coating Sol. Energy Mater. Sol. Cells 501 144025-18

[8] Mahoney AR(2020)Enhanced thermal stability of solar selective absorber based on nano-multilayered TiAlON films deposited by cathodic arc evaporation Appl. Surf. Sci. 94 1412-2579

[9] Ambrosini A(2010)Structure, optical properties and thermal stability of pulsed sputter deposited high temperature HfOx/Mo/HfO2 solar selective absorbers Sol. Energy Mater. Sol. Cells 2 107-333

[10] Bencomo M(2014)High-entropy alloys: a critical review Mater. Res. Lett. 6 8485-13