Cathode electrode catalyst of fuel cell, and reaction acceleration method

1 . A cathode electrode catalyst of a fuel cell, for which cathode electrode catalyst a core-shell catalyst for accelerating an oxygen reduction reaction is used, wherein: the cathode electrode catalyst has, on a surface thereof on which an oxygen reduction reaction occurs, the (110) surface of the face centered cubic lattice; and the cathode electrode catalyst has a shell whose layer of the platinum has, on the (110) surface of the surface of the cathode electrode catalyst, a greater lattice constant than a lattice constant of a platinum bulk material so as to be closer to a lattice constant of the silver, which is the core material, said core-shell catalyst for accelerating an oxygen reduction reaction comprising: silver as a core material; and platinum as a shell material, said core-shell catalyst having a shell that includes 1 to 3 atomic layers of the platinum, said core-shell catalyst having, on a surface thereof, a (110) surface of a face centered cubic lattice. 2 . The cathode electrode catalyst as set forth in claim 1 , wherein the shell of the cathode electrode catalyst includes 1 to 3 atomic layers of the platinum. 3 . A reaction acceleration method for accelerating an oxygen reduction reaction by use of a (110) surface that is formed on a surface of a core-shell catalyst containing: silver as a core material; and platinum as a shell material, said reaction acceleration method comprising: a first step of molecularly adsorbing an oxygen molecule onto the (110) surface; a second step of forming a water molecule by causing (i) the oxygen molecule adsorbed onto the (110) surface and (ii) a proton to react with each other; and a third step of desorbing the water molecule from the (110) surface, wherein: the core-shell catalyst is used for a cathode electrode catalyst of a fuel cell, and the oxygen reduction reaction is accelerated by use of the (110) surface that is formed on a surface of the cathode electrode catalyst on which surface the oxygen reduction reaction occurs; the cathode electrode catalyst has a shell whose layer of the platinum has, on the (110) surface of the surface of the cathode electrode catalyst, a greater lattice constant than a lattice constant of a platinum bulk material so as to be closer to a lattice constant of the silver, which is the core material; in the first step, the oxygen molecule is molecularly adsorbed onto an adsorption site on the (110) surface, which adsorption site is present between platinum atoms in a [−110] direction, which is an in-plane direction, so that (i) a center of gravity of the oxygen molecule is located at the adsorption site and (ii) the oxygen molecule is arranged in the [−110] direction, which is the in-plane direction; in the second step, in a state in which the oxygen molecule which has been adsorbed onto the (110) surface is adsorbed onto the adsorption site, the oxygen molecule and the proton are caused to react with each other so that the water molecule is formed; in the third step, the water molecule is desorbed from the (110) surface; and in a state in which a drive voltage of the fuel cell is applied, the cathode electrode catalyst is lower in activation barrier for causing a reaction to proceed in the third step, as compared with a catalyst consisting solely of platinum.