The objective for this research is to improve methanol electro-oxidation in direct methanol fuel cells via fabricating core-shell PtRu nanoparticles and functionalizing carbon supports simultaneously. First, galvanostatic deposition in rectangular pulses is employed to prepare PtRu nanoparticles on carbon cloths in various sizes and compositions. By adjusting duty cycle, we are able to control the surface composition of PtRu effectively. Material characterizations including XRD, TEM, XPS, and ICP-MS, as well as electrochemical analysis such as cyclic voltammetry and hydrogen desorption are carried out. We found that in a displacement reaction which Ru atoms are alternately deposited and dissolved during Ton and Toff, while Pt atoms are continuously deposited. To further investigate the extent of displacement reaction, we adopt XAS to explore the oxidation state and neighboring atoms for Pt and Ru in samples produced by immersing carbon-supported Ru nanoparticles in hexachloroplatinic acid solutions with pH of 1, 2.2 and 8, respectively. Spectra from XAS confirm that the pH value of hexachloroplatinic acidic solution determines the type of ligands complexing the Pt cations, and consequently affects the extent of displacement reaction and alloying degree of core-shell (Ru@Pt) nanoparticles. As a result, the samples from pH=1 bath reveal a desirable core-shell structure that displays a reduced onset potential in CO stripping and stable catalytic performance for the H2 oxidation reaction, while the samples from pH=8 bath indicate formation of Pt clusters on the Ru surface that leads to poor CO stripping and lower H2 oxidation performance. Lastly, we develop a facile electrochemical route to generate functional groups on the carbon surface via engaging the degradation of Nafion ionomer by multiple CV sweeps in oxygen-saturated H2SO4 electrolyte. Ion chromatography confirms the dissolution of sulfate anions upon CV scans. Raman analysis suggests a minor modification to carbon structure. XPS indicates a significant increase of oxygenated functional groups in conjunction with notable reduction in the fluorine content. The amount of the oxygenated functional groups is determined by curve-fitting of C1s spectra with known constituents. The functionalized electrode allows a 170% increment of Pt ion adsorption compared to that without functionalization. After electrochemical reductions, the functionalized electrode reveals significant improvements in electrocatalytic performance in methanol oxidation, which is attributed to the oxygenated functional groups that facilitate the oxidation of CO on Pt.