Broadband reflectors, concentrated solar power systems, and methods of using the same

What is claimed is: 1 . A broadband reflector comprising: a UV-reflective multilayer optical film having a first major surface and comprising a UV-reflective optical layer stack, wherein the UV-reflective optical layer stack comprises first optical layers and second optical layers, wherein at least a portion of the first optical layers and at least a portion of the second optical layers are in intimate contact and have different refractive indexes, and wherein the UV-reflective optical layer stack is reflective to UV-light; a VIS/IR-reflective multilayer optical film comprising a VIS/IR-reflective optical layer stack, wherein the VIS/IR-reflective optical layer stack comprises third optical layers and fourth optical layers, wherein at least a portion of the third optical layers and at least a portion of the fourth optical layers are in intimate contact and have different refractive indexes, and wherein the VIS/IR-reflective multilayer optical film is reflective to VIS/IR-light; and a UV-absorbing layer disposed between the first major surface of the UV-reflective multilayer optical film and the VIS/IR-reflective multilayer optical film, wherein the UV-absorbing layer comprises a polymer and a UV-absorber. 2 . The broadband reflector of claim 1 , wherein the third optical layers and fourth optical layers respectively comprise a polyethylene terephthalate and a THV, a polyethylene terephthalate and an OTP, a PEN and a THV, a PEN and an OTP, a PEN and a PMMA, a polyethylene terephthalate and a coPMMA, a PEN and a coPMMA layer pairs, a coPEN and a PMMA layer pairs, a coPEN and an OTP, a coPEN and a THV, a sPS and an OTP, a sPS and a THV, a PMMA and a THV, a COC and a THV, or an EVA and a THV. 3 . The broadband reflector of claim 1 , further comprising an adhesive layer disposed on the VIS/IR-reflective multilayer optical film opposite the UV-absorbing layer. 4 . The broadband reflector claim 1 , wherein the first optical layers and second optical layers respectively comprise a polyethylene terephthalate and a coPMMA, a sPS and an OTP, a sPS and a THV, a PMMA and a THV, a COC and a THV, or an EVA and a THV. 5 . The broadband reflector claim 1 , wherein the UV-reflective multilayer optical film further comprises a tie layer that comprises the first major surface of the UV-reflective multilayer optical film. 6 . The broadband reflector of claim 5 , wherein the tie layer comprises an inorganic tie layer. 7 . The broadband reflector of claim 1 , wherein the broadband reflector has an average light reflectivity of at least 90 percent over a wavelength range of from 300 to 2494 nanometers. 8 . The broadband reflector of claim 1 , wherein the UV-reflective multilayer optical film further comprises a second major surface opposite the first major surface, and wherein the UV-reflective multilayer optical film further comprises an abrasion resistant layer that forms the second major surface of the UV-reflective multilayer optical film. 9 . The broadband reflector of claim 8 , wherein the abrasion resistant layer comprises: an antisoiling component selected from the group consisting of fluoropolymers, silicone polymers, titanium dioxide particles, polyhedral oligomeric silsesquioxanes, and combinations thereof. 10 . A concentrated solar power system comprising: at least one broadband reflector of claim 1 capable of being aligned to direct solar radiation onto a hollow receiver; and a heat transfer fluid partially disposed within the hollow receiver. 11 . The concentrated solar power system of claim 10 , further comprising an electrical generator in fluid communication with the hollow receiver. 12 . The concentrated solar power system of claim 10 , further comprising a celestial tracking mechanism for the at least one broadband reflector. 13 . The concentrated solar power system of claim 12 , wherein the celestial tracking mechanism comprises a louver pivotally mounted adjacent the hollow receiver, wherein the louver comprises the at least one broadband reflector. 14 . A method of harnessing solar energy, the method comprising reflecting solar radiation using at least one broadband reflector of claim 1 onto a hollow receiver containing a heat transfer fluid to provide a heated heat transfer fluid. 15 . The method of claim 14 , further comprising thermally heating at least a portion of a building with heat given off from the heated heat transfer fluid. 16 . The method of claim 14 , further comprising generating electrical power using the heated heat transfer fluid. 17 . A method of using the broadband reflector of claim 1 , the method comprising: adhering the broadband reflector to an existing solar reflector adapted for use in a concentrated solar power system. 18 . A solar collection device comprising at least one solar cell and a broadband reflector according to claim 1 positioned in proximity to the at least one solar cell.