Recovery of valuable or toxic metals from silicon solar cells

What is claimed is: 1. A method for recycling materials from a silicon solar cell, the method comprising: vaporization of at least one polymeric layer of the silicon solar cell; chemical dissolution of a front electrode comprising silver, an interconnect of the silicon solar cell comprising tin, and copper in HNO 3 to form a metal-bearing solution; extraction of tin from the metal-bearing solution via sedimentation; sequentially electrowinning the first metal-bearing solution, comprising: placing the first metal-bearing solution in a three-electrode cell utilizing a first working electrode, a counter electrode, and a reference electrode, wherein the first working electrode comprises silver; applying a voltage between 0.3419 V and 0.7996 V versus standard hydrogen electrode to the first working electrode to deposit silver on the first working electrode; removing the first working electrode from the first metal-bearing solution and inserting a second working electrode into the first metal-bearing solution, wherein the second working electrode comprises copper; and applying a voltage between 0.1262 V and 0.3419 V versus standard hydrogen electrode to the second working electrode to deposit copper on the second working electrode; etching, using HF, at least one of a back electrode of the solar cell comprising aluminum or an anti-reflection layer of the solar cell comprising SiNx; and chemically removing an emitter layer of the solar cell using NaOH. 2. The method of claim 1 , further comprising treating waste chemicals produced during the chemical dissolution. 3. The method of claim 1 wherein the sequential electrowinning further comprises: removing the second working electrode from the metal-bearing solution and inserting a third working electrode into the metal-bearing solution, wherein the third working electrode comprises copper; and applying a more negative voltage than −0.1262 V versus standard hydrogen electrode to the third working electrode to deposit lead on the third working electrode. 4. A method for recycling materials from a silicon solar cell, the method comprising: providing a silicon solar cell comprising a silicon wafer positioned between an emitter and a back-surface field, a back electrode positioned on a back side of the silicon wafer, a front electrode comprising silver and positioned on the front side of the silicon wafer, and an anti-reflection layer positioned on the front side of the silicon wafer; chemical dissolution of the front electrode and an interconnect of the silicon solar cell comprising lead, tin, and copper to form a metal-bearing solution; extraction of tin from the metal-bearing solution via sedimentation; extraction of at least one of silver, lead, and copper from the metal-bearing solution via sequential electrowinning, comprising: placing the metal-bearing solution in a three-electrode cell utilizing a first working electrode, a counter electrode, and a reference electrode, wherein the first working electrode comprises silver; applying a voltage between 0.3419 V and 0.7996 V versus standard hydrogen electrode to the first working electrode to deposit silver on the first working electrode; removing the first working electrode from the metal-bearing solution and inserting a second working electrode into the metal-bearing solution, wherein the second working electrode comprises copper; applying a voltage between −0.1262 V and 0.3419 V versus standard hydrogen electrode to the second working electrode to deposit copper on the second working electrode; removing the second working electrode from the metal-bearing solution and inserting a third working electrode into the metal-bearing solution, wherein the third working electrode comprises copper; and applying a more negative voltage than −0.1262 V vs standard hydrogen electrode to the third working electrode to deposit lead on the third working electrode; etching, using hydrofluoric acid, a back electrode of the solar cell comprising aluminum and an anti-reflection layer of the solar cell comprising SiNx; chemically removing, using NaOH, a layer of the emitter of the silicon solar cell and a back-surface field of the silicon solar cell; and treating waste chemicals produced during the chemical dissolution. 5. The method of claim 4 , wherein the layer of the emitter comprises a heavily phosphorus doped layer, and the back-surface field comprises a heavily aluminum doped layer. 6. The method of claim 4 , wherein the anti-reflection layer comprises a silicon nitride layer.