Developing of both effective and stable noble metal nanoparticle (NPs) catalysts with easy catalyst-produce recovery is still challenging in the liquid-phase catalytic processes. Here, we report on the synthesis of a hier archical structured catalyst that consisted of oxygen functionalized graphite felt (OGF) support for liquid-phase processes. The monolith palladium-based catalyst was used as catalytic stirrer and displays excellent stability a; well as complete recyclability for liquid-phase hydrogenation of alpha, beta-unsaturated cinnamaldehyde. The surface defects decorated with abundant oxygenated groups as well as highly accessible porous structure generated from the acid treatment of carbon support, construct a bridge between Pd and support providing the charge transfer tc alter the metal-support interactions. The electron-deficient high-valent Pd delta delta+ species, formed on the metal NPs and defects on the support help to enhance the Pd dispersion and resistance to sintering and/or aggregation during both catalyst preparation and cycling tests, leading to the high and stable hydrogen dissociative ad. sorption for hydrogenation process.