[1] L S Liu, X A Shi, W Wang et al. Carbon nitride/positive carbon black anchoring PtNPs assembled by γ-rays as ORR catalyst with excellent stability. Nanotechnology, 32, 345601(2021).
[2] Y Shi, S K Yin, Y R Ma et al. Oleylamine-functionalized palladium nanoparticles with enhanced electrocatalytic activity for the oxygen reduction reaction. Journal of Power Sources, 246, 356-360(2014).
[3] J J Jia, Z Chen, Y J Liu et al. RuN2 monolayer: a highly efficient electrocatalyst for oxygen reduction reaction. ACS Applied Materials & Interfaces, 12, 54517-54523(2020).
[4] X A Shi, W Wang, X R Miao et al. Constructing conductive channels between platinum nanoparticles and graphitic carbon nitride by gamma irradiation for an enhanced oxygen reduction reaction. ACS Applied Materials & Interfaces, 12, 46095-46106(2020).
[5] S S Liu, W Wang, Y L Hu et al. Hetero-shaped coral-like catalysts through metal-support interaction between nitrogen-doped graphene quantum dots and PtPd alloy for oxygen reduction reaction. Electrochimica Acta, 364, 137314(2020).
[6] X M Zhao, N Li, M L Jing et al. Monodispersed and spherical silver nanoparticles/graphene nanocomposites from gamma-ray assisted in situ synthesis for nitrite electrochemical sensing. Electrochimica Acta, 295, 434-443(2019).
[7] H Wang, C Sun, Y J Cao et al. Molybdenum carbide nanoparticles embedded in nitrogen-doped porous carbon nanofibers as a dual catalyst for hydrogen evolution and oxygen reduction reactions. Carbon, 114, 628-634(2017).
[8] M X Li, H Y Wang, W D Zhu et al. RuNi nanoparticles embedded in N-doped carbon nanofibers as a robust bifunctional catalyst for efficient overall water splitting. Advanced Science, 7, 1901833(2020).
[9] Y B Yan, J W Miao, Z H Yang et al. Carbon nanotube catalysts: recent advances in synthesis, characterization and applications. Chemical Society Reviews, 44, 3295-3346(2015).
[10] X L Pan, Z L Fan, W Chen et al. Enhanced ethanol production inside carbon-nanotube reactors containing catalytic particles. Nature Materials, 6, 507-511(2007).
[11] C C Huang, C Li, G Q Shi. Graphene based catalysts. Energy & Environmental Science, 5, 8848-8868(2012).
[12] K Hareesh, R P Joshi, S S Dahiwale et al. Synthesis of Ag-reduced graphene oxide nanocomposite by gamma radiation assisted method and its photocatalytic activity. Vacuum, 124, 40-45(2016).
[13] Y Zheng, Y Jiao, Y H Zhu et al. Molecule-level g-C3N4 coordinated transition metals as a new class of electrocatalysts for oxygen electrode reactions. Journal of the American Chemical Society, 139, 3336-3339(2017).
[14] Y Zheng, Y Jiao, J Chen et al. Nanoporous graphitic-C3N4@Carbon metal-free electrocatalysts for highly efficient oxygen reduction. Journal of the American Chemical Society, 133, 20116-20119(2011).
[15] J Lee, K H Kim, E E Kwon. Biochar as a catalyst. Renewable and Sustainable Energy Reviews, 77, 70-79(2017).
[16] Changshui HUANG, Yuliang LI. Structure of 2D graphdiyne and its application in energy fields. Acta Physico-Chimica Sinica, 32, 1314-1329(2016).
[17] X Gao, H B Liu, D Wang et al. Graphdiyne: synthesis, properties, and applications. Chemical Society Reviews, 48, 908-936(2019).
[18] J M Chen, J Y Xi, D Wang et al. Carrier mobility in graphyne should be even larger than that in graphene: a theoretical prediction. The Journal of Physical Chemistry Letters, 4, 1443-1448(2013).
[19] W Y Si, Z Yang, X Wang et al. Fe, N-codoped graphdiyne displaying efficient oxygen reduction reaction activity. ChemSusChem, 12, 173-178(2019).
[20] Y Z Dong, Y M Zhao, Y H Chen et al. Graphdiyne-hybridized N-doped TiO2 nanosheets for enhanced visible light photocatalytic activity. Journal of Materials Science, 53, 8921-8932(2018).
[21] J X Lyu, Z M Zhang, J A Wang et al. In situ synthesis of CdS/graphdiyne heterojunction for enhanced photocatalytic activity of hydrogen production. ACS Applied Materials & Interfaces, 11, 2655-2661(2019).
[22] H Shi, M Xia, L T Jia et al. First-principles study on the adsorption and diffusion properties of non-noble (Fe, Co, Ni and Cu) and noble (Ru, Rh, Pt and Pd) metal single atom on graphyne. Chemical Physics, 536, 110783(2020).
[23] B T Kang, J Y Lee. Graphynes as promising cathode material of fuel cell: improvement of oxygen reduction efficiency. The Journal of Physical Chemistry C, 118, 12035-12040(2014).
[24] S Y Lu, M Jin, Y Zhang et al. Chemically exfoliating biomass into a graphene-like porous active carbon with rational pore structure, good conductivity, and large surface area for high-performance supercapacitors. Advanced Energy Materials, 8, 1702545(2018).
[25] Z S Wu, G M Zhou, L C Yin et al. Graphene/metal oxide composite electrode materials for energy storage. Nano Energy, 1, 107-131(2012).
[26] B Song, M Chen, G M Zeng et al. Using graphdiyne (GDY) as a catalyst support for enhanced performance in organic pollutant degradation and hydrogen production: a review. Journal of Hazardous Materials, 398, 122957(2020).
[27] K Srinivasu, S K Ghosh. Graphyne and graphdiyne: promising materials for nanoelectronics and energy storage applications. The Journal of Physical Chemistry C, 116, 5951-5956(2012).
[28] B T Kang, H G Liu, J Y Lee. Oxygen adsorption on single layer graphyne: a DFT study. Physical Chemistry Chemical Physics, 16, 974-980(2014).
[29] W Wang, S S Liu, C Y Min et al. A cathode material of fuel cells: F-doped γ-graphyne/PtPd nanocomposite from plasma activation and gamma irradiation. ACS Applied Energy Materials, 5, 2036-2044(2022).
[30] W Wang, F T Yao, M Zeng et al. Sp-nitrogen and γ-ray modulating multiply γ-graphyne for anchoring Pt nanoparticles to boost oxygen reduction activity and stability. Applied Materials Today, 29, 101626(2022).