These Pd-based catalysts are synthesized in different structures such as bimetallic alloys [20–23], nanodendrites [23], core-shell [24, 25], and nanoneedle [26] through the geometric and electronic effects, the most well-known factors [27] that affect the catalytic reactions and usually work www.selleckchem.com/products/ink128.html jointly. Among the developed structures, the core-shell structures of Pd-based materials [28–31] not only demonstrate high catalytic activity, stability, and durability but also provide a suitable platform to understand the interaction between the core and Pd shell. Particularly, Au/Pd core-shell nanoparticles (NPs) are reported to show excellent
electrochemical properties in FAO [28, 29, 31] and oxygen reduction reaction [32]. The catalytic ability dictated by both the geometric and electronic effects in the core-shell structures can be easily tuned by controlling the composition [33], this website structure, or even particle size of the Au core and Pd layers. Despite extensive development, however, reports on
the impact of porous and hollow Au cores in the Au/Pd core-shell structure are rare. We have developed a unique electrodeposition method to synthesize the Au/Pd core-shell NPs by coating Pd on the surface of hollow 3Methyladenine Au nanospheres [24]. In this paper, we aim to investigate the impact of the Au support, whose structure has been tuned systemically by adjusting the concentration of the Au solution, on the catalytic ability of the Pd layer toward FAO. Methods The hollow Au/Pd core-shell NPs were fabricated from hollow Au
spheres via an electrodeposition method. The electrochemically evolved hydrogen nanobubbles reduced Au+ ions at the boundary into metallic hollow Au clusters. The process has been reported in our previous studies [34, 35], and the size of the hollow Au nanospheres is between 120 and 180 nm with individual grain size ranging from 2 to 8 nm. To adjust the concentration of the Au solution, a buffer solution, containing sodium sulfite (10%), ethylenediamine (5%), and distilled water (85%), was chosen to dilute the Au solution and keep the Au complex (Na3Au(SO3)2) stable. In this study, we prepared three different AZD9291 hollow Au nanospheres denoted as Au100, Au50, and Au25, in which the number stands for the percentage of the Au concentration relative to the received Au solution (7.775 g L-1 from Technic, Woonsocket, RI, USA). To form the Pd shell onto the hollow Au nanosphere substrates, the Au layers were first coated with Cu in a Cu electroless electrolyte, which consisted of 0.4 M CuSO4, 0.17 M ethylenediaminetetraacetic acid disodium salt dehydrate as complexant, and formaldehyde as reducing agent at pH = 10.3 for 10 min. Then an aqueous solution of 2.53 mM PdCl2 was used to replace of the Cu layer through a galvanic reaction for 30 min: Cu(s) + Pd2+(aq) → Pd(s) + Cu2+(aq). The structures of the NPs were determined using powder X-ray diffraction (XRD) with Cu-Kα source (Siemens D500, Munich, Germany).