High altitude aircraft with integrated solar cells, and associated systems and methods

What is claimed is: 1. A solar powered aircraft, comprising: a substrate having a curvature to form a lift surface; a plurality of solar cells carried by, bonded to, and impressed into the substrate; and electrical connections between the solar cells carried by the substrate, wherein the electrical connections link the solar cells together to power the solar powered aircraft while in flight, wherein the solar cells are disposed, at least partially, within recesses impressed into the substrate and wherein the substrate comprises a multi-layer structure including: first and second fabric layers coated in cured adhesive; and a center core layer disposed between and adhered to the first and second fabric layers, wherein the solar cells are impressed and extend into at least the first fabric layer and at least a portion of the center core layer and are in intimate contact with the first fabric layer, and wherein the recesses in which the solar cells are disposed intimately conform to a shape of each individual solar cell of the plurality of solar cells without intervening gaps. 2. The solar powered aircraft of claim 1 , wherein the solar cells are bonded along backsides of the solar cells to bottom surfaces of the recesses and along side edges of the solar cells to side walls of the recesses with one or more adhesives to form an intimately integrated assembly that transmits loads from one solar cell to another via surrounding portions of the substrate along one or more load paths. 3. The solar powered aircraft of claim 1 , wherein the cured adhesive material is cured when applying the heat and the pressure to the solar cells and the substrate to simultaneously bond and shape the solar cells and the substrate into the lift surface of the solar powered aircraft. 4. The solar powered aircraft of claim 1 , further comprising: a protective layer disposed over active surfaces of the solar cells and the substrate with an additional adhesive, wherein the protective layer is transparent to wavelengths that activate a current generation function of the solar cells. 5. The solar powered aircraft of claim 4 , wherein the solar cells are bare crystalline solar cells that are in intimate contact with the protective layer and the first fabric layer of the substrate without individual packaging surrounding each of the solar cells. 6. The solar powered aircraft of claim 1 , wherein the center core layer comprises one of a foam core or a honeycomb core. 7. The solar powered aircraft of claim 1 , wherein the solar cells are bare crystalline solar cells that are in intimate contact with the first fabric layer of the substrate. 8. The solar powered aircraft of claim 7 , wherein the first fabric layer and the center core layer conform to a shape of each of the solar cells. 9. An aircraft, comprising: a substrate having a curvature to form a lift surface; a plurality of solar cells carried by, bonded to, and impressed into recesses within the substrate, wherein the substrate includes: first and second fabric layers coated in adhesive material; and a core layer disposed between and adhered to the first and second fabric layers; and electrical connections between the solar cells carried by the substrate, the electrical connections coupled to link the solar cells together to provide power to the aircraft while in flight, wherein the solar cells are bare crystalline solar cells that are in intimate contact with the first fabric layer of the substrate, wherein the first fabric layer and the center core layer conform to a shape of each of the solar cells, wherein the recesses in which the solar cells are disposed intimately conform to the shape of each individual bare crystalline solar cell of the plurality of bare crystalline solar cells without intervening gaps. 10. The aircraft of claim 9 , wherein the solar cells are disposed, at least partially, within recesses impressed and extending into the substrate. 11. The aircraft of claim 10 , wherein the solar cells are bonded along backsides of the solar cells to bottom surfaces of the recesses and along side edges of the solar cells to side walls of the recesses with one or more adhesives to form an intimately integrated assembly that transmits compressive loads from one solar cell to another via surrounding portions of the substrate along one or more load paths. 12. The aircraft of claim 11 , further comprising: a protective layer disposed over active surfaces of the solar cells and the substrate with an additional adhesive, wherein the protective layer is transparent to wavelengths that activate a current generation function of the solar cells. 13. The aircraft of claim 12 , wherein the solar cells are in intimate contact with the protective layer and the substrate without individual packaging surrounding each of the solar cells. 14. The aircraft of claim 9 , wherein the adhesive material is cured when applying the heat and the pressure to the solar cells and the substrate to simultaneously bond and shape the solar cells and the substrate into the lift surface of the aircraft.