Unitized electrode assembly with high equivalent weight ionomer

The invention claimed is: 1. A catalyst layer for use in a fuel cell, the catalyst layer comprising: catalysts comprising: electrically conductive catalyst supports; and core-shell catalytic nanoparticles distributed on the catalyst supports, the core-shell catalytic nanoparticles having a palladium core and an atomically thin layer of platinum coating an outer surface of the palladium core, at least one of the core-shell catalytic nanoparticles having a hole in the layer of platinum exposing the palladium core; and a scaffolding structure of a perfluorosulfonic acid (PFSA) ionomer, the scaffolding structure positioned between and contacting the catalysts, the PFSA ionomer having ionic conductor properties that are reduced in response to exposing the palladium core, the PFSA ionomer having an equivalent weight ranging from 830 to 900, the equivalent weight minimizing the reduction of the ionic conductor properties. 2. The catalyst layer of claim 1 , wherein the atomically thin layer is a monolayer, a bilayer, or a trilayer of platinum metal atoms. 3. The catalyst layer of claim 1 , wherein the core-shell catalytic nanoparticles have a diameter between about 2 nanometers and about 50 nanometers. 4. A unitized electrode assembly (UEA) comprising: an electrolyte; and a catalyst layer on a first side of the electrolyte, the catalyst layer comprising: catalysts comprising: electrically conductive catalyst supports; and core-shell catalytic nanoparticles distributed on the catalyst supports, the core-shell catalytic nanoparticles having a palladium core and a platinum shell generally encapsulating the palladium core, at least one of the core-shell catalytic nanoparticles having a hole in the platinum shell exposing the palladium core; and a scaffolding structure of a perfluorosulfonic acid (PFSA) ionomer, the scaffolding structure positioned between and contacting the catalysts, the PFSA ionomer having ionic conductor properties that are reduced in response to exposing the palladium core, the PFSA ionomer having an equivalent weight ranging from 830 to 900, the equivalent weight minimizing the reduction of the ionic conductor properties. 5. The UEA of claim 4 , wherein the platinum shell is an atomically thin layer on an outer surface of the palladium core. 6. The UEA of claim 5 , wherein the atomically thin layer is a monolayer, a bilayer, or a trilayer of platinum metal atoms. 7. The UEA of claim 4 , wherein the core-shell catalytic nanoparticles have a diameter between about 2 nanometers and about 50 nanometers. 8. The UEA of claim 4 , wherein the core-shell catalytic nanoparticles have a cubo-octahedral shape. 9. The UEA of claim 4 , wherein the catalyst layer is a cathode catalyst layer. 10. The catalyst layer of claim 1 , wherein the core-shell catalytic nanoparticles have a cubo-octahedral shape. 11. A method comprising: improving a rate of oxygen reduction in a fuel cell having palladium contamination, the fuel cell including an electrolyte and a catalyst layer on the electrolyte, the catalyst layer including catalysts and a perfluorosulfonic acid (PFSA) ionomer having an equivalent weight ranging from 830 to 900, the catalysts including electrically conductive catalyst supports and core-shell catalytic nanoparticles distributed on the catalyst supports, the nanoparticles having a palladium core and a platinum shell generally encapsulating the palladium core, the palladium contamination caused by at least one of the core-shell catalytic nanoparticles having a hole in the platinum shell exposing the palladium core, the improving including: contacting the catalyst layer of the fuel cell with oxygen gas; and minimizing effects of the palladium contamination on the rate of oxygen reduction, based on the equivalent weight of the PFSA ionomer. 12. The method of claim 11 , the improving further comprising: conducting protons from the electrolyte to the core-shell catalytic nanoparticles, the PFSA ionomer acting as a proton conductor, wherein the improving the rate of oxygen reduction includes minimizing effects of the palladium contamination on the conducting protons from the electrolyte to the core-shell catalytic nanoparticles, based on the equivalent weight of the PFSA ionomer.