Chinese Journal of Applied Chemistry ›› 2021, Vol. 38 ›› Issue (11): 1405-1422.DOI: 10.19894/j.issn.1000-0518.210137
• Review • Previous Articles Next Articles
LIU Lin-Chang, GUO Ya-Jun, ZHU Hong-Lin, MA Jing-Jing, LI Zhong-Yi, SHUI Miao, ZHENG Yue-Qing*
Received:
2021-03-22
Accepted:
2021-06-08
Published:
2021-11-01
Online:
2022-01-01
Supported by:
CLC Number:
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.
Add to citation manager EndNote|Ris|BibTeX
URL: http://yyhx.ciac.jl.cn/EN/10.19894/j.issn.1000-0518.210137
[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 MoOx-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. Co0.8Cu0.2MoO4 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 PtCox/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-CeOx 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. Cu0.4Co0.6MoO4 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 WO3-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 MoOx 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 CoxCu1-xCo2O4@CoyCu1-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 Ag0.3Co0.7 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. |
[1] | Yi-Chen YU, Yu-Chen ZHANG, Yao-Yuan ZHANG, Qin WU, Da-Xin SHI, Kang-Cheng CHEN, Han-Sheng LI. Research Progress of Bulk Metal Oxides for Non-oxidative Propane Dehydrogenation [J]. Chinese Journal of Applied Chemistry, 2023, 40(6): 789-805. |
[2] | Hai-Xiang XIU, Wan-Qiang LIU, Dong-Ming YIN, Yong CHENG, Chun-Li WANG, Li-Min WANG. Research Progress of AB2 Laves Phase Hydrogen Storage Alloys [J]. Chinese Journal of Applied Chemistry, 2023, 40(5): 640-652. |
[3] | Feng ZHU, Xiao-Lian PENG, Wen-Bin ZHANG. Research Progress in the Effects of Proton Acceptor/Donor on Electrocatalytic Reactions [J]. Chinese Journal of Applied Chemistry, 2023, 40(5): 666-680. |
[4] | Hui-Hui LI, Kai-Sheng YAO, Ya-Nan ZHAO, Li-Na FAN, Yu-Lin TIAN, Wei-Wei LU. Ionic Liquid-Modulated Synthesis of Pt-Pd Bimetallic Nanomaterials and Their Catalytic Performance for Ammonia Borane Hydrolysis to Generate Hydrogen [J]. Chinese Journal of Applied Chemistry, 2023, 40(4): 597-609. |
[5] | Bing LI, Jun-Hui LIU, Ya-Kun SONG, Xiang LI, Xu-Ming GUO, Jian XIONG. Recent Advances in Application of Metal-Organic Frameworks for Hydrogen Generation by Catalytic Hydrolysis of Ammonia Borane [J]. Chinese Journal of Applied Chemistry, 2023, 40(3): 329-340. |
[6] | Jin LIN, Fang-Zhu WANG, Ling-Ling LYU. Preparation of Pseudo-boehamite from Industrial Materials and Its Application in Selective Hydrogenation of Isophorone [J]. Chinese Journal of Applied Chemistry, 2023, 40(1): 79-90. |
[7] | Xiao-Hu LIU, Xiao-Juan LAI, Hong-Yan CAO, Ting-Ting WANG, Zhi-Qiang DANG. Synergistic Performance of Foaming Agent/Stabilizer/SiO2 Composite Foam Retarded Acid System [J]. Chinese Journal of Applied Chemistry, 2023, 40(1): 91-99. |
[8] | Wei-Qiang ZHANG, Chen WANG, Yu-Rong ZHAO, Dong WANG, Ji-Qian WANG, Hai XU. Research Progress of Regulation of Driving Forces in Short Peptide Supramolecular Self‑Assembly [J]. Chinese Journal of Applied Chemistry, 2022, 39(8): 1190-1201. |
[9] | Wei-Min DU, Xin LIU, Lin ZHU, Jia-Min FU, Wen-Shan GUO, Xiao-Qing YANG, Pei-Shuo SHUANG. Facile Synthesis and High⁃Efficiency Electrocatalytic Oxygen Evolution Performance of Ternary Nickel⁃Based Chalcogenide Nanorod Arrays [J]. Chinese Journal of Applied Chemistry, 2022, 39(8): 1252-1261. |
[10] | Xing-Guo LI. Development Opportunities and Challenges of Hydrogen Energy [J]. Chinese Journal of Applied Chemistry, 2022, 39(7): 1157-1166. |
[11] | Yan WANG, Shu-Cong ZHANG, Xing-Kun WANG, Zhi-Cheng LIU, Huan-Lei WANG, Ming-Hua HUANG. Research Progress on Transition Metal⁃Based Catalysts for Hydrogen Evolution Reaction via Seawater Electrolysis [J]. Chinese Journal of Applied Chemistry, 2022, 39(6): 927-940. |
[12] | Ren MU, Shun NA, Natsagdorj NARANTSOGT, Chong-Jiu LI. Effect of Dimethyl Sulfoxide on the Retention Time of Acetic Acid in Gas Chromatography and Its Mechanism [J]. Chinese Journal of Applied Chemistry, 2022, 39(5): 852-854. |
[13] | Xue-Ting WU, Yang YU, Shu-Yan SONG, Hong-Jie ZHANG. Artificial Carbon Sequestration Technology—Research Progress on the Catalysts for Thermal Catalytic Reduction of CO2 [J]. Chinese Journal of Applied Chemistry, 2022, 39(4): 599-615. |
[14] | Ao YU, Guo-Ming MA, Long-Tao ZHU, Ping PENG, Fang-Fang LI. Electrochemical Reduction of Carbon Dioxide to Carbon Materials for Two⁃Electron Oxygen Reduction Reaction [J]. Chinese Journal of Applied Chemistry, 2022, 39(4): 657-665. |
[15] | Hui DU, Chen-Yang YAO, Hao PENG, Bo JIANG, Shun-Xiang LI, Jun-Lie YAO, Fang ZHENG, Fang YANG, Ai-Guo WU. Applications of Transition Metal⁃doped Iron⁃based Nanoparticles in Biomedicine [J]. Chinese Journal of Applied Chemistry, 2022, 39(3): 391-406. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||