Structures for increased current generation and collection in solar cells with low absorptance and/or low diffusion length

What is claimed is: 1. A solar cell device comprising: a substrate comprising a front side surface and a backside surface; an epitaxial region overlying the substrate, wherein the epitaxial region comprises a first Bragg reflector disposed below a first solar cell and a second Bragg reflector disposed below the first Bragg reflector, wherein the first solar cell comprises a dilute nitride composition and has a first bandgap, wherein the first Bragg reflector is operable to reflect a first range of radiation wavelengths back into the first solar cell and the second Bragg reflector is operable to reflect a third range of wavelengths back into the first solar cell, and the first Bragg reflector and the second Bragg reflector are operable to cool the solar cell device by reflecting a second range of radiation wavelengths that are outside the photogeneration wavelength range of the first solar cell or that are less than 50% absorbed by the first solar cell; a capping layer disposed above the top surface of the first solar cell; a first metal contact disposed below the backside surface; and a second metal contact disposed above the top surface of the capping layer. 2. The solar cell device of claim 1 , wherein the first solar cell comprises GaInNAs or GaInNAsSb. 3. The solar cell device of claim 1 , further comprising a second solar cell disposed above the top surface of the first solar cell, wherein the second solar cell has a bandgap that is higher than the bandgap of the first solar cell. 4. The solar cell device of claim 1 , wherein the first Bragg reflector comprises a tunnel junction formed between a p-type layer and an n-type layer of the first Bragg reflector. 5. The solar cell device of claim 4 , wherein the tunnel junction comprises a carbon doped AlGaAs p-side layer and a tellurium doped GaAs n-type layer. 6. The solar cell device of claim 5 , wherein the AlGaAs has an aluminum mole fraction of 60% to 90%. 7. The solar cell device of claim 4 , wherein the tunnel junction p-type and n-type layers have thicknesses between 100 Å and 1000 Å. 8. The solar cell device of claim 1 , wherein the first Bragg reflector comprises a layer composed of a material that has been doped by two or more n-type dopants. 9. The solar cell device of claim 8 , wherein the two different n-type dopants comprise tellurium and silicon. 10. The solar cell device of claim 1 , wherein the first Bragg reflector comprises a back-surface field (BSF) layer of an adjacent solar cell. 11. The solar cell device of claim 1 , wherein the first Bragg reflector comprises an emitter layer, a window layer, or a front-surface-field (FSF) layer of an adjacent solar cell. 12. A solar cell device comprising: a substrate; a first solar cell; and an epitaxial region overlying the substrate, wherein the epitaxial region comprises a first Bragg reflector disposed below a first solar cell and a second Bragg reflector disposed below the first Bragg reflector, wherein the first solar cell comprises a dilute nitride composition and has a first bandgap, wherein the first Bragg reflector is operable to reflect a first range of radiation wavelengths back into the first solar cell and the second Bragg reflector is operable to reflect a third range of wavelengths back into the first solar cell, and the first Bragg reflector and the second Bragg reflector are operable to cool the solar cell device by reflecting a second range of radiation wavelengths that are outside the photogeneration wavelength range of the first solar cell or that are less than 50% absorbed by the first solar cell; wherein the first Bragg reflector and the second Bragg reflector comprise one or more solar cell structures of an adjacent solar cell, chosen from a list including: a p-type tunnel junction layer; an n-type tunnel junction layer; a back-surface field (BSF) layer; an emitter layer; a window layer; a front-surface-field (FSF) layer; or an electrical contact layer. 13. The solar cell device of claim 12 , wherein the first solar cell comprises GaInNAs or GaInNAsSb. 14. The solar cell device of claim 12 , further comprising a second solar cell disposed above the top surface of the first solar cell, wherein the second solar cell has a bandgap that is higher than the bandgap of the first solar cell. 15. The solar cell device of claim 12 , wherein the first Bragg reflector comprises a tunnel junction formed between a p-type layer and an n-type layer of the first Bragg reflector. 16. The solar cell device of claim 15 , wherein the tunnel junction comprises a carbon doped AlGaAs p-side layer and a tellurium doped GaAs n-type layer. 17. The solar cell device of claim 16 , wherein the AlGaAs has an aluminum mole fraction of 60% to 90%. 18. The solar cell device of claim 15 , wherein the tunnel junction p-type and n-type layers have thicknesses between 100 Å and 1000 Å. 19. The solar cell device of claim 12 , wherein the first Bragg reflector comprises a layer composed of a material that has been doped by two or more n-type dopants. 20. The solar cell device of claim 19 , wherein the two different n-type dopants comprise tellurium and silicon.