[1] H LI, Y ZHOU, M ZHAO et al. Suppressed shuttle via inhibiting the formation of long-chain lithium polysulfides and functional separator for greatly improved lithium-organosulfur batteries performance. Advanced Energy Materials, 10, 1902695(2019).

[2] H LI, M ZHAO, B JIN. Mesoporous nitrogen-doped carbon nanospheres as sulfur matrix and a novel chelate-modified separator for high-performance room-temperature Na-S batteries. Small, 16, 1907464(2020).

[3] P WANG, Y LI X, L SHI Z et al. Synergistic effect of Ag and Ag₂O on photocatalytic H₂-evolution performance of TiO₂. Journal of Inorganic Materials, 35, 781-788(2020).

[4] Q ZHANG Y, J ZHANG S, R WAN Z. RuFe nanoparticles modified sheet-like BiVO₄: high-efficient synergistic catalyst for ammonia borane hydrolytic dehydrogenation. Journal of Inorganic Materials, 35, 809-816(2020).

[5] J LI, W CHEN, H ZHAO et al. Size-dependent catalytic activity over carbon-supported palladium nanoparticles in dehydrogenation of formic acid. Journal of Catalysis, 352, 371-381(2017).

[6] L WANG Z, M YAN J, L WANG H et al. Au@Pd core-shell nanoclusters growing on nitrogen-doped mildly reduced graphene oxide with enhanced catalytic performance for hydrogen generation from formic acid. Journal of Materials Chemistry A, 1, 12721-12725(2013).

[7] Y CUI C, J TANG Y, A ZIAEE M et al. Highly dispersed ultrafine palladium nanoparticles enabled by functionalized porous organic polymer for additive-free dehydrogenation of formic acid. ChemCatChem, 10, 1431-1437(2018).

[8] L GUO S. Ge nanoparticles in MXene sheets: one-step synthesis and highly improved electrochemical property in lithium-ion batteries. Journal of Inorganic Materials, 35, 105-111(2020).

[9] Q ZHANG Y. Preparation and dehydrogenation property of NH₂- UIO-66 supported RuCuMo nanocatalyst. Journal of Inorganic Materials, 34, 1316-1324(2019).

[10] M YAN J, J LI S, S YI S et al. Anchoring and upgrading ultrafine NiPd on room-temperature-synthesized bifunctional NH₂-N-rGO toward low-cost and highly efficient catalysts for selective formic acid dehydrogenation. Advanced Materials, 30, 1703038(2018).

[11] M LIN Q, G CUI J, X YAN et al. First-principles study on electronic structure and optical properties of single point defect graphene oxide. Journal of Inorganic Materials, 35, 1117-1122(2020).

[12] F ZHANG. A new polyethylene composite material based on nano silver particels loaded graphene oxide. Journal of Inorganic Materials, 34, 633-640(2019).

[13] M DUAN J, Q XIANG Z, S ZHANG H et al. Pd-Co₂P nanoparticles supported on N-doped biomass-based carbon microsheet with excellent catalytic performance for hydrogen evolution from formic acid. Applied Surface Science, 530, 147191(2020).

[14] S RANA, B JONNALAGADDA S. A facile synthesis of Cu-Ni bimetallic nanoparticle supported organo functionalized graphene oxide as a catalyst for selective hydrogenation of p-nitrophenol and cinnamaldehyde. RSC Advances, 7, 2869-2879(2017).

[15] R IMANI, H EMAMI S, S FAGHIHI. Synthesis and characterization of an octaarginine functionalized graphene oxide nano-carrier for gene delivery applications. Physical Chemistry Chemical Physics, 17, 6328-6339(2015).

[16] D SHU, F FENG, L HAN H et al. Prominent adsorption performance of amino-functionalized ultra-light graphene aerogel for methyl orange and amaranth. Chemical Engineering Journal, 324, 1-9(2017).

[17] J FAN Z, W KAI, J YAN et al. Facile synthesis of graphene nanosheets via Fe reduction of exfoliated graphite oxide. ACS Nano, 5, 191-198(2011).

[18] Y HOU, W ZHANG B, G XING R et al. One-step synthesis and electrochemical properties of reduced graphene oxide/MnO₂ composites. Journal of Inorganic Materials, 30, 855-860(2015).

[19] Y KANNANGARA Y, A RATHNAYAKE U, K SONG J. Hybrid supercapacitors based on metal organic frameworks using p- phenylenediamine building block. Chemical Engineering Journal, 361, 1235-1244(2019).

[20] L ZHANG, W ZHANG J, Q KUANG et al. Cu²+-assisted synthesis of hexoctahedral Au-Pd alloy nanocrystals with high-index facets. Journal of the American Chemistry Society, 133, 17114-17117(2011).

[21] F LAI L, W CHEN L, Z ZHAN D et al. One-step synthesis of NH₂-graphene from in situ graphene-oxide reduction and its improved electrochemical properties. Carbon, 49, 3250-3257(2011).

[22] N NOURUZI, M DINARI, N MOKHTARI et al. Selective catalytic generation of hydrogen over covalent organic polymer supported Pd nanoparticles (CoP-Pd). Molecular Catalysis, 493, 111057(2020).

[23] H ALAMGHOLILOO, S ROSTAMNIA, A HASSANKHANI et al. Formation and stabilization of colloidal ultra-small palladium nanoparticles on diamine-modified Cr-MIL-101: synergic boost to hydrogen production from formic acid. Journal of Colloid and Interface Science, 567, 126-135(2020).

[24] B YIN, F ZHAO E, L HUA X et al. Ultrafine PdAg nanoparticles immobilized on nitrogen-doped carbon/cerium oxide for superior dehydrogenation of formic acid. New Journal of Chemistry, 44, 2011-2015(2020).

[25] A ZIAEE M, H ZHONG, Y CUI C et al. Additive-free hydrogen generation from formic acid boosted by amine-functionalized imidazolium-based ionic polymers. ACS Sustainable Chemistry & Engineering, 6, 10421-10428(2018).

[26] Q JIANG Y, L FAN X, M CHEN et al. AuPd nanoparticles anchored on nitrogen-decorated carbon nanosheets with highly efficient and selective catalysis for the dehydrogenation of formic acid. The Journal of Physical Chemistry C, 122, 4792-4801(2018).

[27] J ZHANG Z, X LUO Y, W LIU S et al. A PdAg-CeO₂ nanocomposite anchored on mesoporous carbon: a highly efficient catalyst for hydrogen production from formic acid at room temperature. Journal of Materials Chemistry A, 7, 21438-21446(2019).

[28] P LI Z, Q XU. Metal-nanoparticle-catalyzed hydrogen generation from formic acid. Accounts of Chemical Research, 50, 1449-1458(2017).

[29] Y BI Q, D LIN J, M LIU Y et al. Dehydrogenation of formic acid at room temperature: boosting palladium nanoparticle efficiency by coupling with pyridinic-nitrogen-doped carbon. Angewandte Chemie International Edition, 55, 11849-11853(2016).

[30] J LI S, T ZHOU Y, X KANG et al. A simple and effective principle for a rational design of heterogeneous catalysts for dehydrogenation of formic acid. Advanced Materials, 31, 1806781(2019).

[31] K MORI, K NAKA, S MASUDA et al. Palladium copper chromium ternary nanoparticles constructed inβsitu within a basic resin: enhanced activity in the dehydrogenation of formic acid. ChemCatChem, 9, 3456-3462(2017).