Gim, Gundu Haider, Zeeshan Suh, Sae-In Ahn, Yong-Yoon Kim, Kitae Kim, Eun Ju Lee, Hongshin Kim, Hyoung-il Lee, Jaesang 2024-01-12T02:36:13Z 2024-01-12T02:36:13Z 2022-06-17 2022-11 0926-3373 https://pubs.kist.re.kr/handle/201004/75974 This study presents the first instance of the application of hydrogenated nanodiamonds (H-NDs) for persulfate activation and the associated organic degradation. Surface hydrogenation at 600 degrees C, confirmed by the increased surface density of the C-H moiety in XPS and FT-IR spectra, produced H-NDs that outperformed graphitized NDs (prepared via annealing at 1000 degrees C) in terms of organic degradation and persulfate utilization efficiency. Hydrogenation improved the electrical conductivity of NDs; however, it was not accompanied by an increase in the sp(2) carbon content - in contrast to energy-intensive ND graphitization - resulting from sp(3)-to-sp(2) carbon transformation. In addition to the enhanced electron-transfer mediating activity, evidenced by the negative shift of the open circuit potential and current generation, isothermal titration calorimetry measurements indicated a significantly higher binding affinity of H-ND toward persulfate compared with that of graphitized ND. Multiple empirical results confirmed the progress of electron-transfer mediation as a major activation pathway. English Elsevier BV Low-temperature hydrogenation of nanodiamond as a strategy to fabricate sp3-hybridized nanocarbon as a high-performance persulfate activator Article 10.1016/j.apcatb.2022.121589 1 Applied Catalysis B: Environmental, v.316 Applied Catalysis B: Environmental 316 N scie scopus 000815964800006 Chemistry, Physical Engineering, Environmental Engineering, Chemical Chemistry Engineering Article SINGLET OXYGEN HETEROGENEOUS CATALYSIS ORGANIC CONTAMINANTS RATE CONSTANTS OXIDATION GENERATION REMOVAL DIAMOND Surface hydrogenation Nanodiamond Non-radical persulfate activation Electron-transfer mediation Surface binding affinity