Electrochemical Process for Forming a Solid Electrolyte

1 . A method for forming a solid electrolyte coating on a substrate, the method comprising: providing a first and a second electrode, coating a sol-gel precursor solution of the solid electrolyte coating on the substrate and electrically contacting the sol-gel precursor solution with the first and the second electrode, the sol-gel precursor solution being capable of forming a gel in presence of a voltage, and generating the voltage across the sol-gel precursor solution via the first and the second electrodes, thereby transforming the sol-gel precursor solution into a gel. 2 . The method of claim 1 , wherein the substrate is a conductive substrate comprised in the first electrode. 3 . The method of claim 2 , wherein the conductive substrate is used as a cathode when the voltage is generated across the sol-gel precursor solution. 4 . The method of claim 1 , wherein the second electrode is a conductive blade, and wherein electrically contacting the sol-gel precursor solution with the second electrode comprises using the conductive blade to blade coat the sol-gel precursor solution on the substrate , thereby forming the coating thereon. 5 . The method of claim 1 , wherein the second electrode is a conductive slot-die, and wherein electrically contacting the sol-gel solution with the second electrode comprises using the conductive slot-die to apply the sol-gel precursor solution on the substrate, thereby forming the coating thereon. 6 . The method of claim 4 , wherein generating the voltage across the sol-gel precursor solution comprises intermittently generating the voltage across the sol-gel precursor solution, and wherein coating the sol-gel precursor solution of the solid electrolyte coating on the substrate and electrically contacting the sol-gel precursor solution with the first and the second electrode comprises, continuously while intermittently generating the voltage across the sol-gel precursor solution: applying the sol-gel precursor solution of the solid electrolyte coating on the substrate, and moving the substrate relatively to the second electrode, and wherein the method further comprises, subsequent to intermittently generating the voltage across the sol-gel precursor solution washing the gel. 7 . The method of according to claim 5 , wherein coating the sol-gel precursor solution of the solid electrolyte coating on the substrate and electrically contacting the sol-gel precursor solution with the first and the second electrode comprises: intermittently applying the sol-gel precursor solution of the solid electrolyte coating on the substrate, and while intermittently applying the sol-gel precursor solution of the solid electrolyte coating on the substrate, continuously moving the substrate relatively to the second electrode, and wherein the method further comprises, subsequent to intermittently generating the voltage across the sol-gel precursor solution, of washing the gel. 8 . The method of claim 1 , wherein the solid electrolyte coating is a composite electrolyte comprising a porous matrix and an electrolyte present therein, and wherein the sol-gel precursor solution comprises (i) a matrix precursor capable of forming a gel in presence of the voltage, (ii) a template material for guiding the formation of the gel, and (iii) an electrolyte compound. 9 . The method of according to claim 8 , wherein the electrolyte compound comprises a metal salt, the metal salt comprising: a metal cation selected from Li + , Na + , K + , Ca 2+ , Mg 2+ , and Al 3+ , and an anion selected from ClO 4 − , BF 4 − , PF 6 − , bistriflimide, bis(trifluoromethylsulfonyl)imide, bis(fluorosulfonyl)imide, bis-(perfluoroethylsulfonyl)imide, and bis(oxalate)borate. 10 . The method of claim 8 , wherein the template material comprises at least one of an ionic liquid, a polymer, a surfactant, or a polymerized ion liquid. 11 . The method of claim 8 , wherein the matrix precursor comprises: one or more precursors to the sol-gel formation of an oxide of silicon, aluminium, zirconium, titanium, or a combination thereof, or one or more precursor to the sol-gel formation of a phosphate. 12 . The method of claim 1 , further comprising: before coating the sol-gel precursor solution of the solid electrolyte coating on the substrate and electrically contacting the sol-gel precursor solution with the first and the second electrode, forming a sol-gel precursor solution of a solid electrolyte coating, and subsequently aging the sol-gel precursor solution, wherein coating the sol-gel precursor solution of the solid electrolyte coating on the substrate and electrically contacting the sol-gel precursor solution with the first and the second electrode comprises coating the aged sol-gel precursor solution. 13 . The method of claim 1 , further comprising a step d of drying or baking the gel. 14 . A process for forming a composite electrode, the process comprising: providing a first and a second electrode, coating a sol-gel precursor solution of a solid electrolyte coating on a conductive substrate that is comprised in the first electrode and electrically contacting the sol-gel precursor solution with the first and the second electrode, the sol-gel precursor solution being capable of forming a gel in presence of a voltage, wherein the conductive substrate comprises a porous active electrode material and wherein coating the sol-gel precursor solution of the solid electrolyte coating on the substrate and electrically contacting the sol-gel precursor solution with the first and the second electrode results in impregnating the porous active electrode material with the sol-gel precursor solution, and generating the voltage across the sol-gel precursor solution via the first and the second electrodes, thereby transforming the sol-gel precursor solution into a gel. 15 . A method for forming a solid-state battery comprising the steps of: forming a composite cathode electrode by providing a first and a second electrode, coating a sol-gel precursor solution of a solid electrolyte coating on a conductive substrate that is comprised in the first electrode and electrically contacting the sol-gel precursor solution with the first and the second electrode, the sol-gel precursor solution being capable of forming a gel in presence of a voltage, wherein the conductive substrate comprises a porous active electrode material and wherein coating the sol-gel precursor solution of the solid electrolyte coating on the substrate and electrically contacting the sol-gel precursor solution with the first and the second electrode results in impregnating the porous active electrode material with the sol-gel precursor solution, and generating the voltage across the sol-gel precursor solution via the first and the second electrodes, thereby transforming the sol-gel precursor solution into a gel; forming a solid electrolyte coating on an additional substrate by: providing a third and a fourth electrode, coating a sol-gel precursor solution of a solid electrolyte coating on the additional substrate that is conductive and that is comprised in the third electrode and electrically contacting the sol-gel precursor solution with the third and the fourth electrode, the sol-gel precursor solution being capable of forming a gel in presence of a voltage, wherein the additional substrate comprises a porous active electrode material and wherein coating the sol-gel precursor solution of the solid electrolyte coating on the additional substrate and electrically contacting the sol-gel precursor solution with the third and the fourth electrode results in impregnating the p