Ion conductive inks and solutions for additive manufacturing of lithium microbatteries

The invention claimed is: 1. A method of making a micro-battery, comprising the steps of: creating a three dimensional model of a micro-battery separator, wherein said three dimensional model of a micro-battery separator has sides, a top, and a bottom, and comprises anode micro-channels extending from said top to said sides and cathode micro-channels extended from said bottom to said sides; using said three dimensional model of a micro-battery separator to produce a micro-battery separator by additive manufacturing, wherein said additive manufacturing uses ion conductive ink to produce said micro-battery separator, and wherein said micro-battery separator has sides, a top, and a bottom, and comprises anode micro-channels extending from said top to said sides and cathode micro-channels extended from said bottom to said sides; creating a seal for the micro-battery by adding a material that seals said sides of said micro-battery separator leaving said top and said bottom unsealed; positioning a top electrical conductive plate on said top of said micro-battery separator; adding a top electrode connected to said top electrical conductive plate; positioning a bottom electrical conductive plate on said bottom of said micro-battery separator; adding a bottom electrode connected to said bottom electrical conductive plate; filling said anode micro-channels in said micro-battery separator with anode material; filling said cathode micro-channels in said micro-battery separator with cathode material; and adding an outer casing. 2. The method of making a micro-battery of claim 1 , wherein said additive manufacturing is projection micro-stereolithography. 3. The method of making a micro-battery of claim 1 , wherein said additive manufacturing is 3D printing. 4. The method of making a micro-battery of claim 1 , wherein said ion conductive ink is Lithium Bis(trifluoromethane)sulfonimide, LiTFSI) and tetraglyme solvent. 5. The method of making a micro-battery of claim 1 , wherein said ion conductive ink is methacrylpropylsulfate (MPS) salts and PEGDA. 6. The method of making a micro-battery of claim 1 , wherein said ion conductive ink is methacrylpropylsulfate salts and PEGDA/PEGMA having a chemical structure. 7. The method of making a micro-battery of claim 1 , wherein said micro-battery separator has a matrix of anode micro-channels and a matrix of cathode micro-channels wherein said matrix of anode micro-channels and said matrix of cathode micro-channels do not interconnect and form self-contained matrices for said anode material in said anode micro-channels and said cathode material in said cathode micro-channels. 8. The method of making a micro-battery of claim 7 , wherein said matrix of anode micro-channels and said matrix of cathode micro-channels are interwoven to provide an interpenetrating network.