Electrode at which electrons flow into the electrolyte is

In an electrolytic cell the electrode at which the electrons enter the solution and the chemical change that occurs at this electrode are called respectively as:

Electrolusis involves electronation and de-electronation at the redpective electrodes. Anode of electrolytic cell is the electrode at which de-electronation takes place whereas at cathode electronation is noticed. If two or more ions of same charge are to be electronated or de-electronated, the ion having lesser discharge potential is dischargeed. Discharge potential of an ion refers for E_(OP)^(@) or E_(RP)^(@) as the case may be. The products formed at either electrode is given in terms of Faraday's laws of electrolysis i.e., w = (E.i.t)/(96500) E. 5 litre solution of 0.4 M Ni(NO_(3))_(2) is electrolysed using Pt electrodes with 2.4125 ampere current for 10 hour:

Electrolusis involves electronation and de-electronation at the redpective electrodes. Anode of electrolytic cell is the electrode at which de-electronation takes place whereas at cathode electronation is noticed. If two or more ions of same charge are to be electronated or de-electronated, the ion having lesser discharge potential is dischargeed. Discharge potential of an ion refers for E_(OP)^(@) or E_(RP)^(@) as the case may be. The products formed at either electrode is given in terms of Faraday's laws of electrolysis i.e., w = (Eit)/(96500) A. During electrolysis of CH_(3)COONa_((aq.)) the mole ratio of gases formed at cathode and anode is :

Electrolusis involves electronation and de-electronation at the redpective electrodes. Anode of electrolytic cell is the electrode at which de-electronation takes place whereas at cathode electronation is noticed. If two or more ions of same charge are to be electronated or de-electronated, the ion having lesser discharge potential is dischargeed. Discharge potential of an ion refers for E_(OP)^(@) or E_(RP)^(@) as the case may be. The products formed at either electrode is given in terms of Faraday's laws of electrolysis i.e., w = (Eit)/(96500) B. During electrolysis of HCOONNa_((aq.)) , the gas liberated at andoe and cathode are respectively:

Electrolusis involves electronation and de-electronation at the redpective electrodes. Anode of electrolytic cell is the electrode at which de-electronation takes place whereas at cathode electronation is noticed. If two or more ions of same charge are to be electronated or de-electronated, the ion having lesser discharge potential is dischargeed. Discharge potential of an ion refers for E_(OP)^(@) or E_(RP)^(@) as the case may be. The products formed at either electrode is given in terms of Faraday's laws of electrolysis i.e., w = (Eit)/(96500) During electrolysis of CuSO_(4(aq.)) , the pH of solution becomes :

Electrolusis involves electronation and de-electronation at the redpective electrodes. Anode of electrolytic cell is the electrode at which de-electronation takes place whereas at cathode electronation is noticed. If two or more ions of same charge are to be electronated or de-electronated, the ion having lesser discharge potential is dischargeed. Discharge potential of an ion refers for E_(OP)^(@) or E_(RP)^(@) as the case may be. The products formed at either electrode is given in terms of Faraday's laws of electrolysis i.e., w = (Eit)/(96500) F. The volume of octane required to be used for its combustion by the oxygen liberated during electrolysis of an NaNO_(3(aq.)) by passing 9.65 ampere current for 1 hr. is :