Electrochemical reaction cell enhancing reduction reaction

What is claimed is: 1. An electrochemical reaction cell enhancing a reduction reaction, comprising: a membrane electrode assembly including an electrolytic membrane, a cathode formed by sequentially stacking a first gas diffusion layer and a first catalyst layer on a first surface of the electrolytic membrane, and an anode formed by sequentially stacking a second catalyst layer and a second gas diffusion layer on a second surface of the electrolytic membrane; a first distribution plate stacked on the first catalyst layer to supply a reaction gas and a cathode electrolytic solution dissolved with the reaction gas to the first catalyst layer along separate channels, so that the cathode electrolytic solution penetrates and diffuses the first catalyst layer and the first gas diffusion layer to encounter the reaction gas at the first catalyst layer which is in contact with the channel to which the reaction gas is supplied to form a three-phase interface; and a second distribution plate stacked on the second gas diffusion layer to supply an anode electrolytic solution to the second gas diffusion layer. 2. The electrochemical reaction cell enhancing a reduction reaction according to claim 1 , wherein the first distribution plate includes: a plurality of micro channels arranged to cross each other in a latch form so that the cathode electrolytic solution is supplied thereto and accommodated therein, the micro channels being opened at one side which is in contact with the first catalyst layer; and a main channel continuously formed between the plurality of micro channels in a zigzag form so that the reaction gas flows therein, the main channel being opened at one side which is in contact with the first catalyst layer, wherein the cathode electrolytic solution accommodated in the micro channels penetrates through the first catalyst layer and the first gas diffusion layer and diffuses to the main channel adjacent thereto, and then encounters the reaction gas at the first catalyst layer to form a three-phase interface. 3. The electrochemical reaction cell enhancing a reduction reaction according to claim 2 , wherein the first gas diffusion layer is made of titanium sintered foam. 4. The electrochemical reaction cell enhancing a reduction reaction according to claim 2 , wherein the first gas diffusion layer is made of titanium sintered foam coated with a silver (Ag) catalyst. 5. The electrochemical reaction cell enhancing a reduction reaction according to claim 1 , further comprising: a first sealing member provided between the first distribution plate and the membrane to seal the first distribution plate and the first catalyst layer from each other. 6. The electrochemical reaction cell enhancing a reduction reaction according to claim 1 , wherein the second distribution plate includes a channel continuously formed in a zigzag form so that the anode electrolytic solution flows therein, the channel being opened at one side which is in contact with the second gas diffusion layer, and wherein the anode electrolytic solution penetrates and diffuses through the second gas diffusion layer and then is supplied to the second catalyst layer. 7. The electrochemical reaction cell enhancing a reduction reaction according to claim 5 , wherein the second gas diffusion layer is made of titanium sintered foam. 8. The electrochemical reaction cell enhancing a reduction reaction according to claim 5 , wherein the second gas diffusion layer is made of titanium sintered foam coated with an iridium oxide (IrO2) catalyst. 9. The electrochemical reaction cell enhancing a reduction reaction according to claim 1 , further comprising: a second sealing member provided between the second distribution plate and the membrane to seal the second distribution plate and the second gas diffusion layer from each other. 10. The electrochemical reaction cell enhancing a reduction reaction according to claim 1 , further comprising: a first end plate stacked on an outer side of the first distribution plate to supply the reaction gas and the cathode electrolytic solution dissolved with the reaction gas to the first distribution plate and to discharge a product gas generated by reacting with a proton penetrating the electrolytic membrane along with an unreacted reaction gas and an unreacted cathode electrolytic solution; and a second end plate stacked on an outer side of the second distribution plate to supply the anode electrolytic solution to the second distribution plate and discharge an unreacted anode electrolytic solution.