Solid state battery design with mixed ionic and electronic conductor

What is claimed is: 1. A solid-state battery comprising: an anode including a first ionically conductive solid electrolyte material having a coating thereon with susceptibility to reduction in a presence of lithium metal such that, upon contact with lithium metal, the coating partially reduces to a mixed ionic and electronic conductor including a partially reduced species of titanium or partially reduced germanium such that the coating forms an electronic conductivity zone in the anode with both ionic and an electronic conductivity, the anode being in electrical contact with an anode current collector; a cathode; and a separator formed of a second ionically conductive solid electrolyte material which is in contact with the first ionically conductive solid electrolyte material via the coating, but not susceptible to reduction in a presence of lithium metal during cycling and not soluble for titanium or germanium such that the separator allows for migration of lithium ions from the mixed ionic and electronic conductor and impedes propagation or exchange of titanium or germanium such that the electronic conductivity zone does not enter the separator and is contained within the anode, the separator being positioned between and in ionic contact with the anode and cathode. 2. The solid-state battery of claim 1 , wherein the mixed ionic and electronic conductor is reduced lithium aluminum titanium phosphate, reduced lithium lanthanum titanate, or reduced lithium aluminum germanium phosphate. 3. The solid-state battery of claim 1 , wherein the separator is a polymer or sulfide-based separator. 4. The solid-state battery of claim 1 , wherein the separator is a titanium-free or germanium-free solid electrolyte separator. 5. The solid-state battery of claim 1 , wherein the separator is a lithium lanthanum zirconate separator or a lithium phosphorous oxynitride separator. 6. The solid-state battery of claim 1 , wherein the mixed ionic and electronic conductor forms a continuous 3D network in ionic contact with the separator and electronic contact with the anode current collector. 7. The solid-state battery of claim 6 , wherein the anode further comprises a continuous 3D matrix of the second ionically conductive solid electrolyte material. 8. The solid-state battery of claim 7 , wherein the coating is coated on the continuous 3D matrix such that the first ionically conductive solid electrolyte material can reduce to the mixed ionic and electronic conductor upon contact with lithium metal. 9. A solid-state battery comprising: an anode including a continuous network of a first ionically conductive solid electrolyte material having a coating thereon with a susceptibility to reduction in a presence of lithium metal such that, upon contact with lithium metal, the coating partially reduces to a mixed ionic and electronic conductor including partially reduced titanium or partially reduced germanium; a cathode; and a separator formed of a second ionically conductive solid electrolyte material, in contact with the first ionically conductive solid electrolyte material via the coating, which is not susceptible to reduction in a presence of lithium metal and is not soluble for partially reduced titanium or partially reduced germanium such that the separator has a susceptibility for migration of lithium ions from the mixed ionic and electronic conductor and impedes propagation or exchange of titanium or germanium from the mixed ionic and electronic conductor, the separator being positioned between and in ionic contact with the anode and cathode, wherein the continuous network is in ionic contact with the separator and in electrical contact with an anode current collector. 10. The solid-state battery of claim 9 , wherein the continuous network is a 3D network that includes a 3D matrix of the second ionically conductive solid electrolyte material. 11. The solid-state battery of claim 10 , wherein the coating is coated on the 3D matrix to form the 3D network. 12. The solid-state battery of claim 9 , wherein the separator is a titanium-free separator or a germanium-free separator. 13. The solid-state battery of claim 9 , wherein the separator is a polymer or sulfide-based separator. 14. The solid-state battery of claim 9 , wherein the separator is a lithium lanthanum zirconate separator or a lithium phosphorous oxynitride separator.