Page 26 - 《精细化工》2022年第1期
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·16·                              精细化工   FINE CHEMICALS                                 第 39 卷

                 263-268.                                          on the catalytic activity of Ru/LDH for the hydrolytic
            [27]  ZHANG  T,  ZHOU Y M, FU X Q,  et al.  Facile fabrication of   dehydrogenation of ammonia borane[J]. International Journal of
                 hierarchical flower-like BSA/layered double hydroxide hybrids[J].   Hydrogen Energy, 2019, 44(29): 14820-14830.
                 Synthesis and Reactivity in Inorganic, Metal-Organic, and   [44]  QIU X Y, LIU J X, HUANG P R, et al. Hydrolytic dehydrogenation
                 Nano-Metal Chemistry, 2016, 46(10): 1485-1488.     of NH 3BH 3 catalyzed by ruthenium nanoparticles supported on
            [28]  CHATTERJEE A, BHARADIYA P, HANSORA D. Layered double   magnesium-aluminum layered double-hydroxides[J]. RSC Advances,
                 hydroxide based bionanocomposites[J]. Applied Clay Science, 2019,   2020, 10(17): 9996-10005.
                 177: 19-36.                                   [45]  CHENG S H,  LIU Y  C, ZAHO  Y  N,  et al.  Superfine CoNi alloy
            [29]  GUO W Y, ZHAO  Y, ZHOU F,  et al.  Silylated layered double   embedded in Al 2O 3 nanosheets for efficient tandem catalytic
                 hydroxide nanosheets prepared by a large-scale synthesis method as   reduction of nitroaromatic compounds by ammonia borane[J]. Dalton
                 hosts for intercalation of metal  complexes[J]. Applied Catalysis A:   Trans, 2019, 48(47): 17499-17506.
                 General, 2016, 522: 101-108.                  [46]  CUI C C, LIU Y Y, MEHDI S, et al. Enhancing effect of Fe-doping
            [30]  YU J (余俊), YANG Y S (杨宇森), WEI M (卫敏). Preparation and   on the activity of nano Ni catalyst towards hydrogen evolution from
                 catalytic performance of supported catalysts derived from layered   NH 3BH 3[J]. Applied Catalysis B: Environmental, 2020, 265:
                 double hydroxides[J]. Acta Chimica  Sinica (化学学报), 2019,   118612-118621.
                 77(11): 1129-1139.                            [47]  ZHOU Y H, WANG S Q, ZHANG Z Y, et al. Hollow nickel-cobalt
            [31]  DRAGOI B, UNGUREANU A, CHIRIEAC A, et al. Structural and   layered double hydroxide supported palladium catalysts with superior
                 catalytic properties of mono- and bimetallic nickel-copper   hydrogen evolution activity for hydrolysis of ammonia  borane[J].
                 nanoparticles derived from MgNi(Cu)Al-LDHs under reductive   ChemCatChem, 2018, 10(15): 3206-3213.
                 conditions[J]. Applied Catalysis A: General, 2015, 504: 92-102.     [48]  REN F M,  WANG Z, LUO  L F,  et al.  Utilization of active Ni to
            [32]  CONTEROSITO  E, GIANOTTI V, PALIN L,  et al.  Facile   fabricate Pt-Ni nanoframe/NiAl layered double hydroxide
                 preparation methods of hydrotalcite layered  materials and their   multifunctional catalyst through in  situ precipitation[J]. Chemistry,
                 structural characterization by combined techniques[J]. Inorganica   2015, 21(38): 13181-13185.
                 Chimica Acta, 2018, 470: 36-50.               [49]  TOLEK W, SURIYE K, PRASERTHDAM P,  et al.  Effect of
            [33]  LI Y P (李云鹏).  Controllable preparation of Pd based metal-acid-   preparation method on the Pt-In modified Mg(Al)O catalysts over
                 alkali multifunctional catalysts for one-pot syntesis of  MIBK[D].   dehydrogenation of propane[J]. Catalysis Today, 2020, 358: 100-108.
                                                                                                  3+
                 Beijing: Beijing University of Chemical Technology (北京化工大  [50]  ZHANG Q, ZAHNG K T, ZHANG S H, et al. Ga -stabilized Pt in
                 学), 2017.                                         PtSn-Mg(Ga)(Al)O  catalyst  for  promoting  ethane
            [34]  MASCOLO G, MASCOLO M C. On the synthesis of layered double   dehydrogenation[J]. Journal of Catalysis, 2018, 368: 79-88.
                 hydroxides (LDHs) by reconstruction method based on the “memory   [51]  WU X P,  ZHANG Q, CHEN  L  G,  et al.  Enhanced catalytic
                 effect”[J]. Microporous and Mesoporous Materials, 2015, 214:   performance of PtSn catalysts for propane dehydrogenation by a
                 246-248.                                          Zn-modified Mg(Al)O support[J]. Fuel Processing Technology, 2020,
            [35]  WANG  Q,  O'HARE D.  Recent advances in the synthesis and   198: 106222-106230
                 application of layered double  hydroxide (LDH) nanosheets[J].   [52]  CARJA G, NAKAMURA R, AIDA T, et al. Mg-V-Al mixed oxides
                 Chemical Reviews, 2012, 112(7): 4124-4155.        with mesoporous  properties  using  layered double hydroxides as
            [36]  QU J, ZHANG Q W, LI X W, et al. Mechanochemical approaches to   precursors: Catalytic behavior for the process  of ethylbenzene
                 synthesize layered  double hydroxides: A review[J]. Applied Clay   dehydrogenation to styrene under a carbon dioxide flow[J]. Journal
                 Science, 2016, 119: 185-192.                      of Catalysis, 2003, 218(1): 104-110.
            [37]  MITRAN G, MIERITZ D G, SEO D K. Hydrotalcites with vanadium,   [53]  ROSSET M, PEREZ-LOPEZ O W. Catalytic properties of Cu-Mg-Al
                 effective catalysts for  steam reforming of  toluene[J]. International   hydrotalcites, their oxides and  reduced phases for ethanol
                 Journal of Hydrogen Energy, 2017, 42(34): 21732-21740.     dehydrogenation[J]. Reaction Kinetics, Mechanisms and Catalysis,
            [38]  YU J F, WANG Q, O'HARE D, et al. Preparation of two dimensional   2017, 123(2): 689-705.
                 layered double hydroxide nanosheets and their applications[J].   [54]  BELSKAYA O B, STEPANOVA L N, GULYAEVA T I, et al. Zinc
                 Chemical Society Reviews, 2017, 46(19): 5950-5974.     influence on the formation and properties of Pt/Mg(Zn)AlO x catalysts
            [39]  JAYAPRAKASH  S, DEWANGAN N, JANGAM  A,  et al.   synthesized from layered hydroxides[J]. Journal of Catalysis, 2016,
                 LDH-derived Ni-MgO-Al 2O 3 catalysts for  hydrogen-rich syngas   341: 13-23.
                 production  via steam reforming of biomass tar  model: Effect of   [55]  HU Q, YANG L,  FAN G L,  et al.  Greatly enhanced stability of
                 catalyst synthesis methods[J]. International Journal of Hydrogen   supported copper  nanocatalyst with  a thin nitrogen-doped carbon
                 Energy, 2021, 46(35): 18338-18352.                overlayer for transfer dehydrogenation[J]. ChemNanoMat, 2016,
            [40]  FERREIRA R A R, ÁVILA-NETO C N, NORONHA F B,  et al.   2(9): 888-896.
                 Study of LPG steam reform using Ni/Mg/Al hydrotalcite-type   [56]  STEPANOVA L N, BELSKAYA O B, LIKHOLOBOV V A. Effect of
                 precursors[J]. International Journal of Hydrogen Energy, 2019,   the nature of the active-component precursor on the properties of
                 44(45): 24471-24484.                              Pt/MgAlO x catalysts in  propane and  n-decane dehydrogenation[J].
            [41]  HE J P, YANG Z X, ZAHNG L, et al. Cu supported on ZnAl-LDHs   Kinetics and Catalysis, 2017, 58(4): 383-391.
                 precursor prepared by  in-situ synthesis method on  γ-Al 2O 3 as   [57]  TSYGANOK A,  GREEN R G, GIORGI J B,  et al.  Non-oxidative
                 catalytic  material  with high catalytic activity for methanol  steam   dehydrogenation  of ethane to ethylene over chromium catalysts
                 reforming[J]. International Journal of Hydrogen Energy, 2017,   prepared from layered double hydroxide precursors[J]. Catalysis
                 42(15): 9930-9937.                                Communications, 2007, 8(12): 2186-2193.
            [42]  ZHANG Y  Y, YONG C, YAN Z,  et al. Influence of hydrothermal   [58]  PINTHONG P, PRASERTHDAM P,  JONGSOMJIT B.  Oxidative
                 treatment on structural property of NiZrAl mixed-metal oxides and   dehydrogenation of ethanol over Cu/Mg-Al catalyst derived from
                 on catalytic steam reforming of glycerol for hydrogen production[J].   hydrotalcite: Effect of ethanol concentration and reduction
                 International Journal of Hydrogen Energy, 2020, 45(43): 22448-   conditions[J]. Journal of Zhejiang University-Science A, 2020, 21(3):
                 22458.                                            218-228.
            [43]  ZHAO W, WANG R Y, WANG Y, et al. Effect of LDH composition                   (下转第 55 页)
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