Nanofiber electrode and method of forming same

What is claimed is: 1 . A method of forming an electrode for an electrochemical device, comprising the steps of: (a) mixing at least a first amount of a catalyst and a second amount of an ionomer or an uncharged polymer to form a liquid mixture; (b) delivering the liquid mixture into a metallic needle having a needle tip; (c) applying a voltage between the needle tip and a collector substrate positioned at a distance from the needle tip; and (d) extruding the liquid mixture from the needle tip at a flow rate such as to generate electrospun fibers and deposit the generated fibers on the collector substrate to form a mat comprising a porous network of fibers, wherein each fiber has a plurality of particles of the catalyst distributed thereon; 2 . The method of claim 1 , wherein the catalyst comprises platinum-supported carbon (Pt/C). 3 . The method of claim 1 , wherein the ionomer comprises Nafion®. 4 . The method of claim 1 , wherein the liquid mixture further comprises a third amount of a second polymer mixed with the first amount of catalyst and second amount of ionomer or uncharged polymer. 5 . The method of claim 4 , wherein the second polymer comprises polyacrylic acid (PAA). 6 . The method of claim 4 , wherein the ratios between the catalyst, the ionomer or uncharged polymer, and the second polymer are about 15:3:2 by weight. 7 . The method of claim 4 , wherein the ratios between the catalyst, the ionomer or uncharged polymer, and the second polymer are about 11:6:3 by weight. 8 . The method of claim 4 , wherein the ratios between the catalyst, the ionomer or uncharged polymer, and the second polymer are about 7:2:1 by weight. 9 . The method of claim 1 , wherein the collector substrate comprises a carbon paper or carbon cloth gas diffusion layer, disposed on a rotating drum collector. 10 . The method of claim 1 , wherein the voltage applied between the needle tip and the collector substrate is about 7.0 kV. 11 . The method of claim 1 , wherein the membrane comprises a polymer membrane. 12 . A proton exchange membrane (PEM) fuel cell, comprising: (a) a membrane-electrode-assembly (MEA) including: (i) a membrane having a first surface and an opposite, second surface; (ii) an anode disposed on the first surface of the membrane; and (iii) a cathode disposed on the second surface of the membrane; (b) a first flow-field plate having channels that are operative to direct a fuel to the anode; and (c) a second flow-field plate having channels that are operative to direct an oxidant to the cathode. 13 . The fuel cell of claim 12 , wherein the first flow-field plate is operative to direct hydrogen to the anode and the second flow-field plate is operative to direct oxygen to the cathode. 14 . The fuel cell of claim 12 , wherein at least one of the anode and cathode is formed by the steps of: mixing at least a first amount of a catalyst and a second amount of an ionomer or an uncharged polymer to form a liquid mixture; delivering the liquid mixture into a metallic needle having a needle tip; applying a voltage between the needle tip and a collector substrate positioned at a distance from the needle tip; extruding the liquid mixture from the needle tip at a flow rate such as to generate electrospun fibers and deposit the generated fibers on the collector substrate to form a mat comprising a porous network of fibers, wherein each fiber has a plurality of particles of the catalyst distributed thereon; and wherein forming the liquid mixture further comprises mixing a third amount of a second polymer with the first amount of catalyst and second amount of ionomer. 15 . The fuel cell of claim 14 , wherein the catalyst comprises platinum-supported carbon (Pt/C). 16 . The fuel cell of claim 14 , wherein the ionomer comprises Nafion®. 17 . The fuel cell of claim 14 , wherein the liquid mixture further comprises a third amount of a second polymer mixed with the first amount of catalyst and the second amount of ionomer or uncharged polymer. 18 . The fuel cell of claim 17 , wherein the second polymer comprises polyacrylic acid (PAA). 19 . The fuel cell of claim 17 , wherein the ratios between the catalyst, the ionomer or uncharged polymer, and the second polymer are about 15:3:2 by weight. 20 . The method of claim 17 , wherein the ratios between the catalyst, the ionomer or uncharged polymer, and the second polymer are about 11:6:3 by weight. 21 . The method of claim 17 , wherein the ratios between the catalyst, the ionomer or uncharged polymer, and the second polymer are about 7:2:1 by weight. 22 . The fuel cell of claim 14 , wherein the collector substrate comprises a carbon paper or carbon cloth gas diffusion layer, disposed on a rotating drum. 23 . The fuel cell of claim 14 , wherein the fibers are formed to have an average diameter of about 470 nm. 24 . The fuel cell of claim 14 , wherein the electrode, as formed, has a Pt loading in a range from about 0.025 to about 0.4 mg/cm 2 . 25 . The fuel cell of claim 12 , wherein the membrane is ionically conductive. 26 . The fuel cell of claim 14 , wherein the membrane is proton conductive. 27 . The fuel cell of claim 22 , wherein the proton conductive membrane comprises a perfluorosulfonic acid. 28 . The fuel cell of claim 1 , wherein the perfluorosulfonic acid membrane comprises Nafion®. 29 . The fuel cell of claim 12 , wherein the membrane is a nanofiber composite membrane. 30 . The fuel cell of claim 14 , wherein the catalyst comprises Pt particles, Pt alloy particles, Pt on carbon particles, precious metal particles, precious metal on carbon particles, precious metal based alloys, previous metal based alloys on carbon particles, Ag particles, Ni particles, Ag alloy particles, Ni alloy particles, Fe particles, Fe alloy particles, Pd particles, Pd alloy particles, core-shell catalyst particles, non-platinum group metal (PGM) fuel cell catalysts, or a combination thereof. 31 . A membrane-electrode-assembly (MEA) for an electrochemical device, the MEA comprising: (a) a membrane having a first surface and an opposite, second surface; (b) an anode disposed on the first surface of the membrane, the anode formed by the steps of: (i) mixing at least a first amount of a catalyst and a second amount of an ionomer or an uncharged polymer to form a liquid mixture; (ii) delivering the liquid mixture into a metallic needle having a needle tip; (iii) applying a voltage between the needle tip and a collector substrate positioned at a distance from the needle tip; (iv) extruding the liquid mixture from the needle tip at a flow rate such as to generate electrospun fibers and deposit the generated fibers on the collector substrate to form a mat comprising a porous network of fibers, wherein each fiber has a plurality of particles of the catalyst distributed thereon; and (v) pressing the mat onto the first surface of the membrane or pressing the mat and carbon paper onto the first surface of the membrane; and (c) a cathode disposed on the second surface of the membrane. 32 . The MEA of claim 31 , wherein the catalyst comprises platinum-supported carbon (Pt/C). 33 . The MEA of claim 31 , wherein the ionomer comprises Nafion®. 34 .