Optimization of electrochemical cell

What is claimed as new and desired to be protected by Letters Patent of the United States is: 1. A method for assembling an electrochemical cell, comprising the steps of: assembling a cell stack having a liquid electrolyte including a quantity of electrolytic water, an anode electrode, a separator, and a cathode electrode, said electrodes electrochemically communicated with said liquid electrolyte during said assembling step, with components of said cell stack having an as-synthesized set of properties, a pre-assembly set of properties before said electrodes are electrochemically communicated with said liquid electrolyte, and a post-communication set of properties after said electrodes are electrochemically communicated with said liquid electrolyte, wherein said sets of properties each include a water concentration of said liquid electrolyte and a quantity of component water in a component coupled to said liquid electrolyte of said cell stack; coupling, during said assembling step, said liquid electrolyte to said component; and transferring, during said coupling step, a post-assembly quantity of electrolytic water to said quantity of component water; and reducing, responsive to said transferring step, said water concentration of said liquid electrolyte. 2. The method of claim 1 wherein said water concentration of said liquid electrolyte of said pre-assembly set of properties includes a concentration c 1 with said concentration c 1 <1,000 ppm, and wherein said water concentration of said liquid electrolyte of said post-communication set of properties includes a concentration c 2 with said concentration c 2 <100 ppm. 3. The method of claim 1 wherein said water concentration of said liquid electrolyte of said pre-assembly set of properties includes a concentration c 1 with said concentration c 1 <1,000 ppm, and wherein said water concentration of said liquid electrolyte of said post-communication set of properties includes a concentration c 2 with said concentration c 2 <20 ppm. 4. The method of claim 1 wherein said component includes at least one of said electrodes and wherein said at least one electrode contains an active material including a transition metal cyanide coordination compound material. 5. The method of claim 1 wherein said component includes said anode electrode and said cathode electrode and wherein each of said electrodes contains an active material including a transition metal cyanide coordination compound material having a composition conforming to formula I, formula I including A x P y [R(CN) 6 ] z (H 2 O) n ; wherein A represents an alkali cation and P and R each represent a multivalent transition metal cation; wherein 0.5<z<1; and wherein x, y, and z are related based on electrical neutrality, x>0, y>0, z>0; and wherein n=6*(1−z)+m k , with n>0, with k=0 identifying as an as-synthesized material and k=1 to 4 identifying as a set of post-synthesized states for each particular electrode of said electrodes, and with 6*(1−z) identifying as a quantity of coordinated water of said compound material, and with each m k >0, each m k identifying as a quantity of interstitial water of said compound material for one of said states of said particular electrode, with each said quantity m k of interstitial water being equivalent to a weight percentage M k =m k *W H2O /W dry *100%, with W H2O being the molecular weight of water and W dry being the molecular weight for the composition of formula I excluding all of its water content, with each particular one of said electrodes including an M 0 identifying as an as-synthesized set of properties for said particular electrode, with M 1 identifying as a pre-communication set of properties for said anode electrode, with M 2 identifying as a pre-communication set of properties for said cathode electrode, with M 3 identifying as a post-communication set of properties for said anode electrode, and with M 4 identifying as a post-communication set of properties for said cathode electrode; and wherein said liquid electrolyte includes a polar organic solvent combined with an alkali metal salt and water having a water concentration, said water concentration including a pre-communication water concentration c 1 and including a post-communication water concentration c 2 and wherein c 1 >c 2 ; wherein said as-synthesized set of properties includes, for each said particular electrode, M 0 up to 45% for a set of as-synthesized materials, said set of as-synthesized materials including said composition of formula I; wherein said M 1 includes a range between 1% and 12% for a set of anode electrode materials of said anode electrode with M 1 ≤M 3 , said set of anode electrode materials including said composition of formula I wherein said M 2 includes a range between 1% and 12% for a set of cathode electrode materials of said cathode electrode with M 2 ≤M 4 , said set of cathode electrode materials including said composition of formula I and wherein M 3 +M 4 >M 1 +M 2 .