Layered window in thermophotovoltaic devices

The invention claimed is: 1. A thermophotovoltaic device comprising: a thermophotovoltaic absorber having a first side configured to receive electromagnetic radiation radiated from a thermal source and generate electricity from the received electromagnetic radiation; and a front window positioned on the first side of the thermophotovoltaic absorber such that electromagnetic radiation travels through the front window before reaching the first side of the thermophotovoltaic absorber, the front window comprising an outer front window layer and an inner front window layer positioned between the outer front window layer and the first side of the thermophotovoltaic absorber, wherein the outer front window layer comprises a material having a first bandgap; the inner front window layer comprises a material having a second bandgap; the thermophotovoltaic absorber comprises a material having a third bandgap; the first bandgap is the same as or larger than the second bandgap; and the first bandgap and the second bandgap are both the same as or larger than the third bandgap. 2. The thermophotovoltaic device of claim 1 , wherein the first bandgap is greater than 1 eV, the third bandgap is less than 1 eV, and the second bandgap is between the first bandgap and the third bandgap. 3. The thermophotovoltaic device of claim 1 , further comprising an intermediate front window layer positioned between the outer front window layer and the inner front window layer, the intermediate front window layer having a bandgap between the first bandgap and the second bandgap. 4. The thermophotovoltaic device of claim 1 , wherein: the outer front window layer comprises a material having a first doping concentration; the inner front window layer comprises a material having a second doping concentration; and the first doping concentration is the same as or larger than the second doping concentration. 5. The thermophotovoltaic device of claim 4 , wherein the inner front window layer is doped with Si, Te, Se, or S and the outer front window layer is doped with Si, Te, Se, or S. 6. The thermophotovoltaic device of claim 4 , wherein the inner front window layer is doped to a concentration of between 5×10 16 cm −3 and 5×10 18 cm −3 ; and the outer front window layer is doped to a concentration of between 2.5×10 18 cm −3 and 5×10 19 cm −3 . 7. The thermophotovoltaic device of claim 6 , wherein: the outer front window layer further comprises a material having a first conduction band energy level and a first valence band energy level; the inner front window layer comprises a material having a second conduction band energy level and a second valence band energy level; the thermophotovoltaic absorber comprises a material having a third conduction band energy level and a third valence band energy level; the first conduction band energy level is greater than the second conduction band energy level; the second conduction band energy level is greater than the third conduction band energy level; the first valence band energy level is less than the second valence band energy level; and the second valence band energy level is less than the third valence band energy level. 8. The thermophotovoltaic device of claim 7 , wherein: the thermophotovoltaic absorber has an n-type doping; the difference between the first conduction band energy level and the second conduction band energy level is less than 77 meV; the difference between the second conduction band energy level and the third conduction band energy level is less than 77 meV; the inner front window layer and the outer front window layer have n-type doping and are doped to a concentration of greater than 1×10 18 cm −3 ; and the difference between the first valence band energy level and the second valence band energy level and/or the difference between the second valence band energy level and the third valence band energy level is greater than 77 meV; such that electrons move between and through the conduction bands of the outer front window layer, the inner front window layer, and the thermophotovoltaic absorber more freely than holes move between and through the valence bands of the outer front window layer, the inner front window layer, and the thermophotovoltaic absorber to form an electron-selective contact. 9. The thermophotovoltaic device of claim 7 , wherein: the thermophotovoltaic absorber has an p-type doping; the difference between the first valence band energy level and the second valence band energy level is less than 77 meV; the difference between the second valence band energy level and the third valence band energy level is less than 77 meV; the inner front window layer and the outer front window layer have p-type doping and are doped to a concentration of greater than 1×10 18 cm −3 ; and the difference between the first conduction band energy level and the second conduction band energy level and/or the difference between the second conduction band energy level and the third conduction band energy level is greater than 77 meV; such that holes move between and through the valence bands of the outer front window layer, the inner front window layer, and the thermophotovoltaic absorber more freely than electrons move between and through the conduction bands of the outer front window layer, the inner front window layer, and the thermophotovoltaic absorber to form a hole-selective contact. 10. The thermophotovoltaic device of claim 1 , wherein the thermophotovoltaic absorber comprises a III/V semiconductor material. 11. The thermophotovoltaic device of claim 10 , wherein the inner front window layer comprises a III/V semiconductor material and the outer front window layer comprises a III/V semiconductor material. 12. The thermophotovoltaic device of claim 11 , wherein: the thermophotovoltaic absorber comprises GaAs; the inner front window layer comprises InGaP or AlGaAs; and the outer front window layer comprises AlInP, AlInGaP, InGaP or AlGaAs. 13. The thermophotovoltaic device of claim 11 , wherein: the thermophotovoltaic absorber comprises InGaAs; the inner front window layer comprises InP, GaAsSb, or InGaAsP; and the outer front window layer comprises InP. 14. The thermophotovoltaic device of claim 11 , wherein: the thermophotovoltaic absorber comprises GaSb; the inner front window layer comprises AlGaSb or AlAsSb; and the outer front window layer comprises AlGaSb or AlAsSb. 15. A method of making a thermophotovoltaic device comprising: depositing an outer front window layer; depositing an inner front window layer; and depositing a thermophotovoltaic absorber on the inner front window layer such that a first side of the thermophotovoltaic absorber contacts the inner front window layer and the inner front window layer is positioned is positioned between the thermophotovoltaic absorber and the outer front window layer; wherein the thermophotovoltaic absorber is configured to receive electromagnetic radiation radiated from a thermal source and generate electricity from the received electromagnetic radiation, and wherein the outer front window layer comprises a material having a first bandgap; the inner front window layer comprises a material having a second bandgap; the thermophotovoltaic absorber comprises a material having a third bandgap; the first bandgap is the same as or larger than the second bandgap; and the first bandgap and the second bandgap are both the same as or larger than the third bandgap. 16. The method of claim 15 , wherein: depositing the outer front window layer comprises depositin