Research Progress on Supported Ultrafine Nano-catalysts for Hydrolytic Dehydrogenation of Ammonia Borane

doi:10.19894/j.issn.1000-0518.210137

Chinese Journal of Applied Chemistry ›› 2021, Vol. 38 ›› Issue (11): 1405-1422.DOI: 10.19894/j.issn.1000-0518.210137

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Research Progress on Supported Ultrafine Nano-catalysts for Hydrolytic Dehydrogenation of Ammonia Borane

LIU Lin-Chang, GUO Ya-Jun, ZHU Hong-Lin, MA Jing-Jing, LI Zhong-Yi, SHUI Miao, ZHENG Yue-Qing^*

Institute for Chemical Synthesis and Green Application, College of Materials Science and Chemical Engineering, Ningbo University, Ningbo 315211, China

Received:2021-03-22 Accepted:2021-06-08 Published:2021-11-01 Online:2022-01-01
Supported by:
Public Projects of Zhejiang Province (No.2017C33008)

Abstract

Abstract: Hydrogen (H₂), as a renewable, zero-carbon emission and earth-abundant energy carrier, is considered to be one of the effective solutions to the energy crisis and environmental problems. Since H₂ is highly flammable and explosive, it is hard for storage and transportation and its application is severely restricted. Therefore, the safe and efficient storage and controllable release of hydrogen is urgently crucial. It is well-known that ammonia borane (NH₃BH₃, AB for short) has a high hydrogen content, and is stable at room temperature, non-pollutant, non-toxic and soluble in water, and it can not react with water at room temperature. In presence of a suitable catalyst, AB can easily hydrolyze in aqueous media to liberate H₂, so that AB is recognized to be an ideal candidate of hydrogen energy materials. However, the lack of low-cost, stable, environmentally friendly, easily separable and recyclable high-performance catalysts seriously hinders the development and applications of AB-based hydrolytic hydrogenation technology. Therefore, rational design and controllable construction of low-cost and high-performance catalysts for AB hydrolytic hydrogenation is greatly challenging for applications of AB-based hydrogen energy. At present, investigation on high performance catalysts for hydrolytic hydrogenation of ammonia borane is very active, and has become one of the hot topics in the field of hydrogen energy research. Hitherto now, the heterogeneous catalysts used in the hydrolytic hydrogenation of ammonia borane can be classified into two categories: non-supported and supported. In particular, the supported ultrafine nanocatalysts have attracted wide attention and extensive interests, and their research shows a rapid development trend. In this contribution, preparations of the ultrafine nanocatalysts supported on carbon based materials, layered double hydroxides (LDHs), oxides, metal-organic frameworks (MOFs), organic polymer materials, as well as the catalytic performances and mechanisms in hydrolytic hydrogenation of ammonia borane are reviewed, and then, the problems to be solved in this research are summarized, and prospects about further researches are presented.

Key words: Hydrogen, Ammonia borane, Hydrogen storage materials, Hydrogen production, Catalyst supports, Nanomaterials, Ultra-fine nanos

CLC Number:

O643.3

LIU Lin-Chang, GUO Ya-Jun, ZHU Hong-Lin, MA Jing-Jing, LI Zhong-Yi, SHUI Miao, ZHENG Yue-Qing. Research Progress on Supported Ultrafine Nano-catalysts for Hydrolytic Dehydrogenation of Ammonia Borane[J]. Chinese Journal of Applied Chemistry, 2021, 38(11): 1405-1422.

References

[1] ORLY L, JORGE D, GAL H, et al. Diatoms: a fossil fuel of the future[J]. Trends Biotechnol, 2014, 32(3): 117-124.
[2] SCOTT V, HASZELDINE R S, TETT S F B, et al. Fossil fuels in a trillion tonne world[J]. Nat Clim Change, 2015, 5: 419-423.
[3] TURNER J A. Sustainable hydrogen production[J]. Science, 2004, 305(5686): 972-974.
[4] ZHOU Q Q, WANG J Y, GUO F Y, et al. Self-supported bimetallic phosphide-carbon nanostructures derived from metal-organic frameworks as bifunctional catalysts for highly efficient water splitting[J]. Electrochim Acta, 2019, 318: 244-251.
[5] ZHANG M Y, XU W, LI T T, et al. In situ growth of tetrametallic FeCoMnNi-MOF-74 on nickel foam as efficient bifunctional electrocatalysts for the evolution reaction of oxygen and hydrogen[J]. Inorg Chem, 2020, 59(20): 15467-15477.
[6] WANG Y R, CHEN X W, ZHANG H Y, et al. Heterostructures built in metal hydrides for advanced hydrogen storage reversibility[J]. Adv Mater, 2020, 32: 2002647.
[7] LUO Y M, SUN L X, XU F, et al. Improved hydrogen storage of LiBH₄ and NH₃BH₃ by catalysts[J]. J Mater Chem A, 2018, 6: 7293-7309.
[8] WANG W, HONG X L, YAO Q L, et al. Bimetallic Ni-Pt nanoparticles immobilized on mesoporous N doped carbon as highly efficient catalysts for complete hydrogen evolution from hydrazine borane[J]. J Mater Chem A, 2020, 8: 13694-13701.
[9] SEVIM M, KAPLAN F. Ketjen black supported monodisperse nickel-platinum alloy nanoparticles for the efficient catalyst in the hydrolytic dehydrogenation of ammonia borane[J]. Appl Organomet Chem, 2021, 35: e6095.
[10] YAO Q, YANG K K, NIE W D, et al. Highly efficient hydrogen generation from hydrazine borane via a MoO_x-promoted NiPd nanocatalyst[J]. Renew Energy, 2020, 147: 2024-2031.
[11] WANG Y T, SHEN G Q, ZHANG Y X, et al. Visible-light-induced unbalanced charge on NiCoP/TiO₂ sensitized system for rapid H₂ generation from hydrolysis of ammonia borane[J]. Appl Catal B, Environ, 2020, 260: 118183.
[12] DEKA J R, SAIKIA D, LU N F, et al. Space confined synthesis of highly dispersed bimetallic CoCu nanoparticles as effective catalysts for ammonia borane dehydrogenation and 4-nitrophenol reduction[J]. Appl Surf Sci, 2021, 538: 148091.
[13] SHEN J L, CHEN W F, LV G, et al. Hydrolysis of NH₃BH₃ and NaBH₄ by graphene quantum dots-transition metal nanoparticles for highly effective hydrogen evolution[J]. Int J Hydrogen Energy, 2021, 46: 796-805.
[14] 刘军辉, 郭旭明, 宋亚坤, 等. 催化氨硼烷水解制氢研究进展[J]. 应用化学, 2021, 38(2): 157-169.
LIU J H, GUO X M, SONG Y K, et al. Progress in research for hydrolytic dehydrogenation of ammonia borane[J]. Chinese J Appl Chem, 2021, 38(2): 157-169.
[15] CHANDRA M, XU Q. A high-performance hydrogen generation system: transition metal-catalyzed dissociation and hydrolysis of ammonia-borane[J]. J Power Sources, 2006, 156: 190-194.
[16] 姚淇露, 杜红霞, 卢章辉. 氨硼烷催化水解制氢[J]. 化学进展, 2020, 32(12): 1930-1951.
YAO Q L, DU H X, LU Z H. Catalytic hydrolysis of ammonia borane to hydrogen[J]. Chem Prog, 2020, 32(12): 1930-1951.
[17] WANG Q, FU F Y, YANG S, et al. Dramatic synergy in CoPt nanocatalysts stabilized by “Click” dendrimers for evolution of hydrogen from hydrolysis of ammonia borane[J]. ACS Catal, 2019, 9(2):1110-1119.
[18] SONG Q, WANG W W, HU X W, et al. Ru nanoclusters confined in porous organic cages for catalytic hydrolysis of ammonia borane and tandem hydrogenation reaction[J]. Nanoscale, 2019, 11: 21513-21521.
[19] TONBUL Y, AKBAYRAK S, ÖZKAR S. Ceria supported rhodium nanoparticles: superb catalytic activity in hydrogen generation from the hydrolysis of ammonia borane[J]. Appl Catal B, Environ, 2016, 198: 162-170.
[20] GUO L T, CAI Y Y, GE J M, et al. Multifunctional Au-Co@CN nanocatalyst for highly efficient hydrolysis of ammonia borane[J]. ACS Catal, 2015, 5(1): 388-392.
[21] YANG L, LUO W, CHENG G Z. Graphene-supported Ag-based core-shell nanoparticles for hydrogen generation in hydrolysis of ammonia borane and methylamine borane[J]. ACS Appl Mater Interfaces, 2013, 5(16): 8231-8240.
[22] GAO M Y, YANG W W, YU Y S. Monodisperse PtCu alloy nanoparticles as highly efficient catalysts for the hydrolytic dehydrogenation of ammonia borane[J]. Int J Hydrogen Energy, 2018, 43: 14293-14300.
[23] MIAO H, MA K L, ZHU H R, et al. Ammonia borane dehydrogenation and selectivehydrogenation of functionalized nitroarene over a porous nickel-cobalt bimetallic catalyst[J]. RSC Adv, 2019, 9: 14580-14585.
[24] YANG K K,YAO Q L, HUANG W, et al. Enhanced catalytic activity of NiM (M=Cr, Mo, W) nanoparticles for hydrogen evolution from ammonia borane and hydrazine borane[J]. Int J Hydrogen Energy, 2017, 42: 6840-6850.
[25] FILIZ B C, FIGEN A K, PIŞKIN S. The remarkable role of metal promoters on the catalytic activity of Co-Cu based nanoparticles for boosting hydrogen evolution: ammonia borane hydrolysis[J]. Appl Catal B, Environ, 2018, 238: 365-380.
[26] LIAO J Y, LV F, FENG Y F, et al. Electromagnetic-field-assisted synthesis of Ni foam film-supported CoCu alloy microspheres composed of nanosheets: a high performance catalyst for the hydrolysis of ammonia borane[J]. Catal Commun, 2019, 122: 16-19.
[27] EL-HAFIZD R A, ESHAQ G, ELMETWALLY A E. Recent enhancement of ammonia borane hydrolysis using spinel-type metal ferrites nano-catalysts[J]. Mater Chem Phys, 2018, 217: 562-569.
[28] LIAO J Y, FENG Y F, WU S Q, et al. Hexagonal CuCo₂O₄ nanoplatelets, a highly active catalyst for the hydrolysis of ammonia borane for hydrogen production[J]. Nanomaterials, 2019, 9: 360.
[29] LIAO J Y, LU D S, DIAO G Q, et al. Co_0.8Cu_0.2MoO₄ microspheres composed of nanoplatelets as a robust catalyst for the hydrolysis of ammonia borane[J]. ACS Sustainable Chem Eng, 2018, 6(5): 5843-5851.
[30] LI Y T, ULLAH S, HAN Z, et al. Hierarchical porous CuNi-based bimetal-organic frameworks as efficient catalysts for ammonia borane hydrolysis[J]. Catal Commun, 2020, 143: 106057.
[31] HASHIMIA S, NOHAN M A N M, XIAN C S, et al. Copper nanowires as highly efficient and recyclable catalyst for rapid hydrogen generation from hydrolysis of sodium borohydride[J]. Nanomaterials, 2020, 10(6): 1153.
[32] WU H, WU M, WANG B Y, et al. Interface electron collaborative migration of Co-Co₃O₄/carbon dots: boosting the hydrolytic dehydrogenation of ammonia borane[J]. J Energy Chem, 2020, 48: 43-53.
[33] CUI C C, LIU Y Y, MEHDI S, et al. Enhancing effect of Fe-doping on the activity of nano Ni catalyst towards hydrogen evolution from NH₃BH₃[J]. Appl Catal B, Environ, 2020, 265: 118612.
[34] ZHANG X L, ZHANG D X, CHANG G G, et al. Bimetallic (Zn/Co) MOFs-derived highly dispersed metallic Co/HPC for completely hydrolytic dehydrogenation of ammonia-borane[J]. Ind Eng Chem Res, 2019, 58(17): 7209-7216.
[35] MA X C, HE Y Y, ZHANG D X, et al. Cobalt-based MOF-derived CoP/hierarchical porous carbon (HPC) composites as robust catalyst for efficient dehydrogenation of ammonia-borane[J]. ChemistrySelect, 2020, 5: 2190-2196.
[36] AKBAYRAK S, ÖZÇIFÇI Z, TABAK A. Noble metal nanoparticles supported on activated carbon: highly recyclable catalysts in hydrogen generation from the hydrolysis of ammonia borane[J]. J Colloid Interface Sci, 2019, 546: 324-332.
[37] KAZICI H C, YILDIZ F, IZGI M S, et al. Novel activated carbon supported trimetallic PdCoAg nanoparticles as efficient catalysts for the hydrolytic dehydrogenation of ammonia borane[J]. Int J Hydrogen Energy, 2019, 44: 10561-10572.
[38] BROOKS R M, MAAFA I M, AL-ENIZI A M, et al. Electrospun bimetallic NiCr nanoparticles@carbon nanofibers as an efficient catalyst for hydrogen generation from ammonia borane[J]. Nanomaterials 2019, 9(8): 1082.
[39] ZHANG J K, CHEN W Y, GE H B, et al. Synergistic effects in atomic-layer-deposited PtCo_x/CNTs catalysts enhancing hydrolytic dehydrogenation of ammonia borane[J]. Appl Catal B, Environ, 2018, 235: 256-263.
[40] AKBAYRAK S, CAKMAK G, ÖZTURK T, et al. Rhodium(0), Ruthenium(0) and Palladium(0) nanoparticles supported on carbon-coated iron: magnetically isolable and reusable catalysts for hydrolytic dehydrogenation of ammonia borane[J]. Int J Hydrogen Energy, 2021, 46(25): 13548-13560.
[41] YANG L, CAO N, DU C, et al. Graphene supported cobalt(0) nanoparticles for hydrolysis of ammonia borane[J]. Mater Lett, 2014, 115: 113-116.
[42] CUI C C, LIU Y Y, MEHDI S, et al. Enhancing effect of Fe-doping on the activity of nano Ni catalyst towards hydrogen evolution from NH₃BH₃[J]. Appl Catal B, Environ, 2020, 265: 118612.
[43] YAO Q L, LU Z H, YANG Y W, et al. Facile synthesis of graphene-supported Ni-CeO_x nanocomposites as highly efficient catalysts for hydrolytic dehydrogenation of ammonia borane[J]. Nano Res, 2018, 11: 4412-4422.
[44] YAO Q L, LU Z H, HUANG W, et al. Highly Pt-like activity of Ni-Mo/graphene catalyst for hydrogen evolution from hydrolysis of ammonia borane[J]. J Mater Chem A, 2016, 4: 8579.
[45] ZHAO X, KE D D, HAN S M, et al. Reduced graphene oxide sheets supported waxberry-like Co catalysts for improved hydrolytic dehydrogenation of ammonia borane[J]. ChemistrySelect, 2019, 4: 2513-2518.
[46] DU X G, TAI Y P, LIU H Y, et al. One-step synthesis of reduced graphene oxide supported CoW nanoparticles as efficient catalysts for hydrogen generation from NH₃BH₃[J]. React Kinet Mech Catal, 2018, 125: 171-181.
[47] XU M, HUAI X L, ZHANG H. Highly dispersed CuCo nanoparticles supported on reduced graphene oxide as high-activity catalysts for hydrogen evolution from ammonia borane hydrolysis[J]. J Nanopart Res, 2018, 20: 329.
[48] ZHOU Y H, ZHANG Z Y, WANG S Q, et al. RGO supported PdNi-CeO₂ nanocomposite as an efficient catalyst for hydrogen evolution from the hydrolysis of NH₃BH₃[J]. Int J Hydrogen Energy, 2018, 43: 18745-18753.
[49] ZHENG H C, FENG K, SHANG Y P, et al. Cube-like CuCoO nanostructures on reduced graphene oxide for H₂ generation from ammonia borane[J]. Inorg Chem Front, 2018, 5: 1180-1187.
[50] ZHANG R Z, ZHENG J L, CHEN T W, et al. RGO-wrapped Ni-P hollow octahedrons as noble-metal-free catalysts to boost the hydrolysis of ammonia borane toward hydrogen generation[J]. J Alloy Compd, 2018, 763: 538-545.
[51] ZACHO S L, MIELBY J, KEGNÆS S. Hydrolytic dehydrogenation of ammonia borane over ZIF-67 derived Co nanoparticle catalysts[J]. Catal Sci Technol, 2018, 8:4741-4746.
[52] ZHONG F Y, WANG Q, XU C L. Ultrafine and highly dispersed Ru nanoparticles supported on nitrogen-doped carbon nanosheets: efficient catalysts for ammonia borane hydrolysis[J]. Appl Surf Sci, 2018, 455:326-332.
[53] WEI Z H, LIU Y, PENG Z K, et al. Cobalt-ruthenium nanoalloys parceled in porous nitrogen-doped graphene as highly efficient difunctional catalysts for hydrogen evolution reaction and hydrolysis of ammonia borane[J]. ACS Sustainable Chem Eng, 2019, 7(7): 7014-7023.
[54] YUAN Y S, SUN L M, WU G Z, et al. Engineering nickel/palladium heterojunctions for dehydrogenation of ammonia borane: improving the catalytic performance with 3D mesoporous structures and external nitrogen-doped carbon layers[J]. Inorg Chem, 2020, 59(3): 2104-2110.
[55] WANG W, Lu Z H, LUP Y, et al. Mesoporous carbon nitride supported Pd and Pd-Ni nanoparticles as highly efficient catalyst for catalytic hydrolysis of NH₃BH₃[J]. ChemCatChem, 2018, 10: 1620.
[56] WEI R, CHEN Z C, LV H, et al. Ultrafine RhNi nanocatalysts confined in hollow mesoporous carbons for a highly efficient hydrogen production from ammonia borane[J]. Inorg Chem, 2021, 60(9): 6820-6828.
[57] FAN Y R, LI X J, HE X C, et al. Effective hydrolysis of ammonia borane catalyzed by ruthenium nanoparticles immobilized on graphic carbon nitride[J]. Int J Hydrogen Energy, 2014, 39: 19982-19989.
[58] LI Y T, ZHANG S H, ZHENG G P, et al. Ultrafine Ru nanoparticles anchored to porous g-C₃N₄ as efficient catalysts for ammonia borane hydrolysis[J]. Appl Catal A, Gen, 2020, 595: 117511.
[59] LU R, HU M, XU C L, et al. Hydrogen evolution from hydrolysis of ammonia borane catalyzed by Rh/g-C₃N₄ under mild conditions[J]. Int J Hydrogen Energy, 2018, 43: 7038-7045.
[60] LI Y T, ZHANG X L, PENG Z K, et al. Hierarchical porous g-C₃N₄ coupled ultrafine RuNi alloys as extremely active catalysts for the hydrolytic dehydrogenation of ammonia borane[J]. ACS Sustainable Chem Eng, 2020, 8(22): 8458-8468.
[61] LI Y T, ZHANG X L, PENG Z K, et al. Highly efficient hydrolysis of ammonia borane using ultrafine bimetallic RuPd nanoalloys encapsulated in porous g-C₃N₄[J]. Fuel, 2020, 277: 118243.
[62] WANGQ, XU C L, MING M, et al. In situ formation of AgCo stabilized on graphitic carbon nitride and concomitant hydrolysis of ammonia borane to hydrogen[J]. Nanomaterials, 2018, 8(5): 280.
[63] GUO L L, GU X J, KANG K, et al. Porous nitrogen-doped carbon-immobilized bimetallic nanoparticles as highly efficient catalysts for hydrogen generation from hydrolysis of ammonia borane[J]. J Mater Chem A, 2015, 3: 22807-22815.
[64] LI J H, LI F Y, LIAO J Y, et al. Cu_0.4Co_0.6MoO₄ nanorods supported on graphitic carbon nitride as a highly active catalyst for the hydrolytic dehydrogenation of ammonia borane[J]. Catalysts, 2019, 9: 714.
[65] LU R, XU C L, WANG Q, et al. Ruthenium nanoclusters distributed on phosphorus-doped carbon derived from hypercrosslinked polymer networks for highly efficient hydrolysis of ammonia-borane[J]. Int J Hydrogen Energy, 2018, 43: 18253-18260.
[66] ZHOU Y H, WANG S Q, ZHANG Z, et al. Hollow nickel-cobalt layered double hydroxide supported palladium catalysts with superior hydrogen evolution activity for hydrolysis of ammonia borane[J]. ChemCatChem, 2018, 10: 3206-3213.
[67] ZHAO W, WANG R Y, WANG Y, et al. Effect of LDH composition on the catalytic activity of Ru/LDH for the hydrolytic dehydrogenation of ammonia borane[J]. Int J Hydrogen Energy, 2019, 44: 14820-14830.
[68] GUO K, DING Y, LUO J, et al. NiCu bimetallic nanoparticles on silica support for catalytic hydrolysis of ammonia borane: composition-dependent activity and support size effect[J]. ACS Appl Energy Mater, 2019, 2(8): 5851-5861.
[69] UMEGAKI T, YABUUCHI K, YOSHIDA N, et al. In situ synthesized hollow spheres of a silica-ruthenium-nickel composite catalyst for the hydrolytic dehydrogenation of ammonia borane[J]. New J Chem, 2020, 44: 450-455.
[70] ZHANG J P, LI J, YANG L J, et al. Efficient hydrogen production from ammonia borane hydrolysis catalyzed by TiO₂-supported RuCo catalysts[J]. Int J Hydrogen Energy, 2021, 46: 3964-3973.
[71] AKBAYRAK S, TONBUL Y, ÖZKAR S. Magnetically separable Rh⁰/Co₃O₄ nanocatalyst provides over a million turnovers in hydrogen release from ammonia borane[J]. ACS Sustainable Chem Eng, 2020, 8(10): 4216-4224.
[72] LI J J, GUAN Q Q, WU H, et al. Highly active and stable metal single-atom catalysts achieved by strong electronic metal-support interactions[J]. J Am Chem Soc, 2019, 141(37): 14515-14519.
[73]TONBUL Y, AKBAYRAK S, ÖZKAR S. Magnetically separable rhodium nanoparticles as catalysts for releasing hydrogen from the hydrolysis of ammonia borane[J]. J Colloid Interface Sci, 2019, 553: 581-587.
[74] AKBAYRAK S, ÖZKAR S. Cobalt ferrite supported platinum nanoparticles: superb catalytic activity and outstanding reusability in hydrogen generation from the hydrolysis of ammonia borane[J]. J Colloid Interface Sci, 2021, 596: 100-107.
[75] TONBUL Y, AKBAYRAK S, ÖZKAR S. Group 4 oxides supported Rhodium(0) catalysts in hydrolytic dehydrogenation of ammonia borane[J]. Int J Hydrogen Energy, 2019, 44: 14164-14174.
[76] LIX, YAN Y C, JIANG Y, et al. Ultra-small Rh nanoparticles supported on WO_3-x nanowires as efficient catalysts for visible-light-enhanced hydrogen evolution from ammonia borane[J]. Nanoscale Adv, 2019, 1: 3941-3947.
[77] TONBULY, AKBAYRAK S, ÖZKAR S. Palladium(0) nanoparticles supported on ceria: highly active and reusable catalyst in hydrogen generation from the hydrolysis of ammonia borane[J]. Int J Hydrogen Energy, 2016, 41: 11154-11162.
[78] LU D S, LIAO J Y, LI H, et al. Co₃O₄/CuMoO₄ hybrid microflowers composed of nanorods with rich particle boundaries as a highly active catalyst for ammonia borane hydrolysis[J]. ACS Sustainable Chem Eng, 2019, 7(19): 16474-16482.
[79] LIAO J Y, FENG Y F, LIN W M, et al. CuO-NiO/Co₃O₄ hybrid nanoplates as highly active catalyst for ammonia borane hydrolysis[J]. Int J Hydrogen Energy, 2020, 45: 8168-8176.
[80] HE J H, YAO Z D, XIAO X Z, et al. Heterostructured Ni/NiO nanoparticles on 1D porous MoO_x for hydrolysis of ammonia borane[J]. ACS Appl Energy Mater, 2021, 4(2): 1208-1217.
[81] LU D S, Li J H, LIN C H, et al. A simple and scalable route to synthesize Co_xCu_1-xCo₂O₄@Co_yCu_1-yCo₂O₄ yolk-shell microspheres, a high-performance catalyst to hydrolyze ammonia borane for hydrogen production[J]. Small, 2019, 15: 1805460.
[82] AIJAZ A, KARKAMKAR A, CHOI Y J, et al. Immobilizing highly catalytically active Pt nanoparticles inside the pores of metal-organic framework: a double solvents approach[J]. J Am Chem Soc, 2012, 134(34): 13926-13929.
[83] DAI H M, SU J, HU K, et al. Pd nanoparticles supported on MIL-101 as high-performance catalysts for catalytic hydrolysis of ammonia borane[J]. Int J Hydrogen Energy, 2014, 39: 4947-4953.
[84] CAO N, SU J, LUO W, et al. Ni-Pt nanoparticles supported on MIL-101 as highly efficient catalysts for hydrogen generation from aqueous alkaline solution of hydrazine for chemical hydrogen storage[J]. Int J Hydrogen Energy, 2014, 39: 9726-9734.
[85] ZHANG L, ZHOU L Q, YANG K Z, et al. Pd-Ni nanoparticles supported on MIL-101 as high-performance catalysts for hydrogen generation from ammonia borane[J]. J Alloy Compd, 2016, 677: 87-95.
[86] YANG K Z, ZHOU L Q, XIONG X, et al. RuCuCo nanoparticles supported on MIL-101 as a novel highly efficient catalysts for the hydrolysis of ammonia borane[J]. Micropor Mesopor Mater, 2016, 225: 1-8.
[87] WEN L, SU J, WU X J, et al. Ruthenium supported on MIL-96: an efficient catalyst for hydrolytic dehydrogenation of ammonia borane for chemical hydrogen storage[J]. Int J Hydrogen Energy, 2014, 39: 17129-17135.
[88] YANG K Z, ZHOU L Q, YU G F, et al. Ru nanoparticles supported on MIL-53(Cr, Al) as efficient catalysts for hydrogen generation from hydrolysis of ammonia borane[J]. Int J Hydrogen Energy, 2016, 41: 6300-6309.
[89] CHEN M H, ZHOU L Q, LU D, et al. RuCo bimetallic alloy nanoparticles immobilized on multi-porous MIL-53(Al) as a highly efficient catalyst for the hydrolytic reaction of ammonia borane[J]. Int J Hydrogen Energy, 2018, 43: 1439-1450.
[90] FU F Y, WANG C L, WANG Q, et al. Highly selective and sharp volcano-type synergistic Ni₂Pt@ZIF-8-catalyzed hydrogen evolution from ammonia borane hydrolysis[J]. J Am Chem Soc, 2018, 140(31): 10034-10042.
[91] WANG W J, LIANG M W, JIANG Y, et al. Nano-Co embedded in porous ZIF-67 polyhedron to catalyze hydrolysis of ammonia borane[J]. Mater Lett, 2021, 293(31): 129702.
[92] 翊青, 刘梨, 张淑娟, 等. NH₂-UIO-66 负载 RuCuMo 纳米催化剂的制备及其催化产氢[J]. 无机材料学报, 2019, 34(12): 1316-1324.
Yi Q, LIU L, ZHANG S J, et al. Preparation and catalytic hydrogen production of RuCuMo nano-catalyst supported by NH₂-UIO-66[J]. Chinese J Inorg Mater, 2019, 34(12): 1316-1324.
[93] XU C L, HU M, WANG Q, et al. Hyper-cross-linked polymer supported rhodium: an effective catalyst for hydrogen evolution from ammonia borane[J]. Dalton Trans, 2018, 47: 2561-2567.
[94] CHEN X, XU X J, ZHENG X C, et al. Chitosan supported palladium nanoparticles: the novel catalysts for hydrogen generation from hydrolysis of ammonia borane[J]. Mater Res Bull, 2018, 103: 89-95.
[95] YANG X Y, HE Y J, LI L Y, et al. One-pot fabrication of Pd nanoparticles@covalent-organic-framework-derived hollow polyamine spheres as a synergistic catalyst for tandem catalysis[J]. Chem Eur J, 2020, 26: 1864-1870.
[96] LI Y T, ULLAH S, HAN Z, et al. Hierarchical porous CuNi-based bimetal-organic frameworks as efficient catalysts for ammonia borane hydrolysis[J]. Catal Commun, 2020, 143: 106057.
[97] GENIS D, COS B, FILIZ K, et al. Reusable hybrid foam catalyst for hydrolytic dehydrogenation of amine adducts of borane: porous PVA-immobilized Co-Ru nanoparticles[J]. Micropor Mesopor Mater, 2020, 305: 110363.
[98] HUANG H, WANG J, XU Y F, et al. Thermo-controllable dehydrogenation of ammonia borane by luminescent and thermo-responsive catalysts based on SiO₂@Pt@PABI-Tb@PNIPAM[J]. Appl Catal A, 2020, 594: 117463.
[99] JIA H, CHEN X, LIU C Y, et al. Ultrafine palladium nanoparticles anchoring graphene oxide-ionic liquid grafted chitosan self-assembled materials: the novel organic-inorganic hybrid catalysts for hydrogen generation in hydrolysis of ammonia borane[J]. Int J Hydrogen Energy, 2018, 43: 12081-12090.
[100] LIU S, CHEN X, WU Z J, et al. Chitosan-reduced graphene oxide hybrids encapsulated Pd(0) nanocatalysts for H₂ generation from ammonia borane[J]. Int J Hydrogen Energy, 2019, 44: 23610-23619.
[101] KE D D, WANG J, ZHANG H M, et al. Hydrolytic dehydrogenation of ammonia borane catalyzed by poly(amidoamine) dendrimers-modified reduced graphene oxide nanosheets supported Ag_0.3Co_0.7 nanoparticles[J]. J Mater Sci Tech, 2018, 34: 2350-2358.
[102] WEI J, ZHAO J B, CAI D, et al. Synthesis of micro/meso porous carbon for ultrahigh hydrogen adsorption using cross-linked polyaspartic acid[J]. Front Chem Sci Eng, 2020, 14: 857-867.
[103] VEERAKUMAR P, LIN K. An overview of palladium supported on carbon-based materials: synthesis, characterization, and its catalytic activity for reduction of hexavalent chromium[J]. Chemosphere, 2020, 253: 126750.
[104] YUAN Y S, SUN L M, WU G Z, et al. Engineering nickel/palladium heterojunctions for dehydrogenation of ammonia borane: improving the catalytic performance with 3D mesoporous structures and external nitrogen-doped carbon layers[J]. Inorg Chem, 2020, 59(3): 2104-2110.
[105] LU R, XU C L, WANG Q, et al. Ruthenium nanoclusters distributed on phosphorus-doped carbon derived from hypercrosslinked polymer networks for highly efficient hydrolysis of ammonia-borane[J]. Int J Hydrogen Energy, 2018, 43: 18253-18260.
[106] SONG F, HU X L. Exfoliation of layered double hydroxides for enhanced oxygen evolution catalysis[J]. Nat Commun, 2014, 5: 4477-4486.
[107] CHEN H, HU L F, CHEN M, et al. Nickel-cobalt layered double hydroxide nanosheets for high-performance supercapacitor electrode materials[J]. Adv Funct Mater, 2014, 24: 934-942.
[108] WANG B Q, SHANG J, GUO C, et al. A general method to ultrathin bimetal-MOF nanosheets arrays via in situ transformation of layered double hydroxides arrays[J]. Small, 2019, 15: 1804761.
[109] ZHOU A W, DOU Y B, ZHOU J, et al. Rational localization of metal nanoparticles in yolk-shell MOFs for enhancing catalytic performance in selective hydrogenation of cinnamaldehyde[J]. ChemSusChem, 2020, 13: 205-211.
[110] WU H, LUO Q Q, ZHANG R Q, et al. Single Pt atoms supported on oxidized graphene as a promising catalyst for hydrolysis of ammonia borane[J]. Chinese J Chem Phys, 2018, 31: 641.
[111] WEI L, YANG Y M, YU Y N, et al. Visible-light-enhanced catalytic hydrolysis of ammonia borane using RuP₂ quantum dots supported by graphitic carbon nitride[J]. Int J Hydrogen Energy, 2021, 46: 3811-3820.
[112] FENG Y F, LIAO J Y, CHEN X D, et al. Synthesis of rattle-structured CuCo₂O₄ nanospheres with tunable sizes based on heterogeneous contraction and their ultrahigh performance toward ammonia borane hydrolysis[J]. J Alloy Compd, 2021, 863: 158089.

Research Progress on Supported Ultrafine Nano-catalysts for Hydrolytic Dehydrogenation of Ammonia Borane

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