溶剂热法

  • 网络Solvothermal synthesis;solvothermal
溶剂热法溶剂热法
  1. 溶剂热法合成YAG:Ce粉体及其表征

    Solvothermal Synthesis and Characterization of YAG : Ce Powders

  2. 溶剂热法合成CdSxSe(1-x)棒状纳米材料

    Solvothermal Synthesis of CdS_xSe_ ( 1-x ) Nanorods

  3. 溶剂热法合成YAG晶粒的形成过程

    Formation process of YAG grains synthesized by solvothermal method

  4. 利用溶剂热法合成了CdS纳米棒及球形纳米粒子。

    CdS nanorods and nano particles are prepared by solvothermal method .

  5. 溶剂热法Fe3O4纳米颗粒的制备及表征

    Synthesis and characterization of Fe_3O_4 nanoparticles by a solvothermal method

  6. 复合溶剂热法合成Bi2S3纳米棒的研究

    Research on Synthesizing Bi_2S_3 Nanorods by Complex Solvothermal Process

  7. 纳米磁性Mn3O4粉末的溶剂热法合成及表征

    Solvent-thermal Synthesis and Characterization of Magnetic Nanometer Mn_3O_4 Powder

  8. 溶剂热法实现ZnS晶体相变的反应条件研究

    Studies on the Reaction Conditions of Achieving ZnS Crystal Phase Transition by Solvothermal Route

  9. 本论文采用溶剂热法和溶胶-凝胶法合成Mn,Co,Ni掺杂的ZnO稀磁半导体材料。

    This work focuses on synthesis of Mn , Co or Ni doped ZnO diluted magnetic semiconductors ( DMS ) through a solvothermal method and a sol-gel method .

  10. 一种新型磷酸钛的溶剂热法合成与表征溶剂热合成法制备顺丁烯二酸二丁酯接枝POE

    Solvothermal synthesis and characterization of a new titanium phosphate ; Solvothermal Process for Grafting Dibutyl Maleate onto Ethylene 1-Octene Copolymers

  11. 设计了一种通过溶剂热法合成CoO实心纳米球的新方法。

    A new solvothermal method has been designed to synthesize solid CoO nanospheres by esterification reaction .

  12. 采用溶剂热法,在多元醇体系中,实现了对镍基金属(Ni和FeNi合金)纳米结构形貌的控制合成。

    The Ni-based metals , such as Ni , and FeNi alloy nanostructures with different shapes were synthesized by solvothermal method in polyol system .

  13. 用混合溶剂热法合成了金属有机物前驱体,然后使其热解,可以得到一种新颖的晶态材料&骨状MgO纳米晶。

    The material with novel morphology & bone-like MgO nanocrystals has been achieved by the thermal decomposition of an organic metal precursor , which was pre-prepared by a solvothermal process .

  14. 低温溶剂热法合成的多元金属硫族化合物常具有低维结构(即0-D,1-D,2-D),热力学上多处于介稳态。

    Low-temperatur Solvothermal technique growth often produce compounds which have low-demension structures ( i.e.0-D , 1-D , 2-D ) which is metastable state in thermodynamics .

  15. 采用直流电化学沉积、热分解法、溶剂热法,在阳极氧化铝(AAO)模板孔洞内分别制备多种新型SERS基底。

    Direct current electrochemistry deposition method , solvothermal method and pyrolytic process were used to fabricate SERS substrates inside the hole of anodic aluminum oxide ( AAO ) template .

  16. 首先,通过DMF-水混合溶剂热法,获得了平均尺寸约为100纳米的均一Ni纳米球;然后,通过适量Ni纳米球的葡萄糖的水热碳化,制备了蜂窝状Ni@C复合纳米结构。

    Homogeneous Ni nanospheres with the average diameter of 100 nm were firstly obtained via a DMF-water mixed solvothermal route ; then honeycomb-like Ni @ C composite nanostructures were prepared through the hydrothermal carbonization of glucose solutions with suitable amounts of Ni nanospheres .

  17. 选用溶剂热法在基底上原位合成SnO薄膜,然后通过煅烧制备出SnO2/SnO杂化薄膜。

    Use the solvothermal method to synthesize SnO film on the substrate , then the SnO2 / SnO hybrid thin film is obtained via calcining the SnO thin film .

  18. 选用金属单质锡和硫粉作为反应物,不需任何表面活性剂,利用溶剂热法180℃反应24h,在ITO基底上一步合成了SnS纳米薄膜。

    We selected the metallic simple substance of tin and sulfur powder as reactants , without any surfactant , utilized a hydrothermal method at180 ℃ for24h to synthesize the SnS films on ITO glass substrates directly .

  19. 采用溶剂热法、聚合反应和后期的高温煅烧制备了Li3V2(PO4)3/C纳米复合材料。

    Li3V2 ( PO4 ) 3 / carbon nanocomposites have been synthesized by a solvothermal method and polymerization reaction , followed by post-heat treatment .

  20. 采用溶剂热法,以丙酮-水为混合溶剂,过硫酸钾(KPS)为引发剂引发甲基丙烯酸甲酯(MMA)和苯乙烯(St)共聚,制得了粒径约为31nm的共聚无皂纳米粒子。

    Emulsifier-free poly ( styrene-methylmethacrylate )( P ( St-MMA )) copolymer nanoparticles with an average diameter of about 31 nm were synthesized in an acetone-water medium with potassium persulfate ( KPS ) as the initiator by solvothermal method .

  21. 用水热法和溶剂热法合成LiSrAlF6

    Hydrothermal and Solvothermal Synthesis of LiSrAlF_6

  22. 首先,通过溶剂热法合成了纳米ZnS粒子,并制备了不同ZnS含量的环氧/ZnS纳米复合材料。

    The preparation , morphology and properties of these nanocomposites have been studied in detail . First , epoxy coated ZnS nano-particles were synthesized through hydrothermal process , and then epoxy / ZnS nanocomposites with different ZnS contents were prepared .

  23. 目前EuS的合成方法主要有高温固相法、高温固气法、高温溶剂热法等,这些方法存在合成温度高、成本高的缺点。

    The current synthesis methods of EuS including high temperature solid reaction process , high temperature gas solid method and high temperature hydrothermal method , which all need high synthesis temperature , or high cost .

  24. 实验结果表明,磁粉含量为50g时,所制备的磁性膜层各方面性能比较平衡。(3)结合溶剂热法和水热反应合成了具有超顺磁性Fe3O4@葡聚糖@SnO2多层磁性微球。

    The experimental results indicated that the optimal content of magnetic powder is about 50g . ( 3 ) Fe3O4 @ dextran @ SnO2 multilayer magnetic microspheres were successfully synthesized by solvothermal and hydrothermal reactions .

  25. 针对这一弊端,本文提出了采用溶剂热法低温合成EuS晶体的方案,实验表明采用乙腈溶剂热法可显著地降低EuS晶体合成温度,且采用该法首次合成了EuS中空微球。

    In this paper , we proposes a solvothermal method of synthesizing EuS crystal at low temperature , and the results show that the solvent thermal method using acetonitrile as solvent can reduce the synthesis temperature of EuS crystal obviously .

  26. 采用溶剂热法和表面修饰工艺,制备出纳米LaF3微粒。

    In this paper , LaF_ ( 3 ) nanoparticles is prepared by using the method of heat solvent and surface modification technique .

  27. 第一性原理计算表明所激发的黄光发射来自于锡空位(Vsn)。溶剂热法中有机溶剂处于临界状态下,能够发生通常条件下无法实现的反应,并能生成具有介稳态结构的材料。

    First-principle Calculation ( by VASP ) indicates that the yellow luminescence derives from the Sn vacancy ( VSn ) . Solvent-thermal method is in a critical condition , can occur under the normal conditions the reaction can not be achieved , and can generate metastable state structure of materials .

  28. 溶剂热法合成CuInS2-ZnS固溶体及其光催化分解水制氢性能

    Photocatalytic Hydrogen Production on CuInS_2-ZnS Solid Solution Prepared by Solvothermal Method

  29. 溶剂热法合成六方氮化硼纳米晶的影响因素研究

    Study on Influence Factors of h-BN Nanocrystals Prepared by Solvothermal Method

  30. 采用溶剂热法一步合成了ZnFe2O4/石墨烯复合纳米材料。

    ZnFe2O4 / graphene composites were synthesized by one-step solvothermal method .