1164 工程科学学报，第42卷.第9期 synthesis.Thermal and non-thermal microwave effects.Chem Soc powders by a microwave-assisted molten salt method.J Ceram Rem,2005,34(2:164 Soc Jpn,2016,124(5):593 [13]Tong Z F,Bi S W,Yang Y H.Present situation of study on [20]Zhang G Q,Zhang T A,Lu G Z,et al.Effects of microwave microwave heating application in metallurgy.J Mater Metall, roasting on the kinetics of extracting vanadium from vanadium 2004,3(2):117 slag.J0M2016,68(2):577 (佟志芳，毕诗文，杨毅宏.微波加热在治金领域中应用研究现 [21]Zhang X F,Liu F G,Xue XX,et al.Effects of microwave and 状.材料与治金学报，2004,3(2)：117) conventional blank roasting on oxidation behavior,microstructure [14]De Castro E R,Mourao M B.Jermolovicius L A,et al. and surface morphology of vanadium slag with high chromium Carbothermal reduction of iron ore applying microwave energy content.JAlloys Compd,2016,686:356 Steel Res Int,2012,83(2:131 [22]Starink M J.A new method for the derivation of activation [15]Al-Harahsheh M,Kingman S W.Microwave-assisted leaching-a energies from experiments performed at constant heating rate review.Hydrometallurgy,2004.73(3-4):189 Thermochim Acta,1996,288(1-2):97 [16]Kingman S W,Jackson K,Bradshaw S M,et al.An investigation into the influence of microwave treatment on mineral ore [23]Liu C.Peng J H,Ma A Y,et al.Study on non-isothermal kinetics comminution.Powder Technol,2004,146(3):176 of the thermal desorption of mercury from spent mercuric chloride [17]Sahoo B K,De S,Meikap B C.Improvement of grinding catalyst.J Hazard Mater,2017,322:325 characteristics of Indian coal by microwave pre-treatment.Fuel [24]Menendez J A,Arenillas A,Fidalgo B,et al.Microwave heating Process Technol,2011,92(10):1920 processes involving carbon materials.Fuel Process Technol,2010, [18]Hao H,Liu H X,Liu Y,et al.BiTijO12 template synthesised by 91(1):1 microwave assisted molten salt method.Mater Res Innovations, [25]Liu C,Peng J H,Liu J,et al.Catalytic removal of mercury from 2007,11(4):185 waste carbonaceous catalyst by microwave heating.J Hazard [19]Huang Z,Deng X G,Liu J H,et al.Preparation of CaZrO3 Mater,2018,358:198synthesis. Thermal and non-thermal microwave effects. Chem Soc Rev, 2005, 34（2）: 164 Tong  Z  F,  Bi  S  W,  Yang  Y  H.  Present  situation  of  study  on microwave  heating  application  in  metallurgy. J Mater Metall, 2004, 3（2）: 117 （佟志芳, 毕诗文, 杨毅宏. 微波加热在冶金领域中应用研究现 状. 材料与冶金学报, 2004, 3（2）：117） [13] De  Castro  E  R,  Mourao  M  B,  Jermolovicius  L  A,  et  al. Carbothermal  reduction  of  iron  ore  applying  microwave  energy. Steel Res Int, 2012, 83（2）: 131 [14] Al-Harahsheh M, Kingman S W. Microwave-assisted leaching—a review. Hydrometallurgy, 2004, 73（3-4）: 189 [15] Kingman S W, Jackson K, Bradshaw S M, et al. An investigation into  the  influence  of  microwave  treatment  on  mineral  ore comminution. Powder Technol, 2004, 146（3）: 176 [16] Sahoo  B  K,  De  S,  Meikap  B  C.  Improvement  of  grinding characteristics  of  Indian  coal  by  microwave  pre-treatment. Fuel Process Technol, 2011, 92（10）: 1920 [17] Hao H, Liu H X, Liu Y, et al. Bi4Ti3O12 template synthesised by microwave  assisted  molten  salt  method. Mater Res Innovations, 2007, 11（4）: 185 [18] [19] Huang  Z,  Deng  X  G,  Liu  J  H,  et  al.  Preparation  of  CaZrO3 powders  by  a  microwave-assisted  molten  salt  method. J Ceram Soc Jpn, 2016, 124（5）: 593 Zhang  G  Q,  Zhang  T  A,  Lü  G  Z,  et  al.  Effects  of  microwave roasting  on  the  kinetics  of  extracting  vanadium  from  vanadium slag. JOM, 2016, 68（2）: 577 [20] Zhang  X  F,  Liu  F  G,  Xue  X  X,  et  al.  Effects  of  microwave  and conventional blank roasting on oxidation behavior, microstructure and  surface  morphology  of  vanadium  slag  with  high  chromium content. J Alloys Compd, 2016, 686: 356 [21] Starink  M  J.  A  new  method  for  the  derivation  of  activation energies  from  experiments  performed  at  constant  heating  rate. Thermochim Acta, 1996, 288（1-2）: 97 [22] Liu C, Peng J H, Ma A Y, et al. Study on non-isothermal kinetics of the thermal desorption of mercury from spent mercuric chloride catalyst. J Hazard Mater, 2017, 322: 325 [23] Menéndez J A, Arenillas A, Fidalgo B, et al. Microwave heating processes involving carbon materials. Fuel Process Technol, 2010, 91（1）: 1 [24] Liu C, Peng J H, Liu J, et al. Catalytic removal of mercury from waste  carbonaceous  catalyst  by  microwave  heating. J Hazard Mater, 2018, 358: 198 [25] · 1164 · 工程科学学报，第 42 卷，第 9 期