1)nanoparticles纳米微粒
1.Size and shape effects of lattice distortion and cohesive energy of Au nanoparticles;金纳米微粒晶格畸变和结合能的尺寸形状效应
2.Synthesis and characterization of styrene-maleic anhydride copolymer/silver nanoparticles;苯乙烯-马来酸酐无规共聚物/银纳米微粒的合成及表征
3.Microemulsion synthesis and characterization of Fe-Co-Ni alloy nanoparticles;微乳液法合成Fe-Co-Ni合金纳米微粒
英文短句/例句
1.chemical vapor coagulation method, CVC method化学蒸发凝聚法(制纳米微粒的方法)
2.It also involves the methods of nanometer particle's modification and characterization.提及纳米微粒的改性技术和表征方法。
3.Synthesis and Characterization of Gold-coated Magnetic Nanoparticles;金包覆的磁性纳米微粒的制备与表征
4.Preparing Polycarbosilane Nanoparticle Through GAS Annealing Crystallization;GAS重结晶制备聚碳硅烷纳米微粒
5.Spectral Properties of the Se and Au Nanoparticle Systems;金、硒纳米微粒体系的光谱特性研究
6.Researches on Preparation and Development of Nanometer Tin Dioxide Particles;SnO_2纳米微粒的制备方法及其进展
7.Preparation of Nanometer Tin Dioxide Particles by Sol-gel;溶胶-凝胶法制备SnO_2纳米微粒
8.The Preparation and Characterization of Nanometer γ-Fe_2O_3 and Fe;γ-Fe_2O_3和Fe纳米微粒的制备及相组成
9.EFFECTS OF NANOPARTICLES ON THERMODYNAMIC PARAMETER OF PVP CRYOPROTECTECTIVE AGENTSHA纳米微粒对PVP低温保护剂的影响
10.Preparation and Morphology and Particle Size Control of CdS Nanoparticles;CdS纳米微粒的制备及其形貌和粒度控制
11.Preparation of semiconductor CuS nanoparticles and Bi_2S_3 nanorods by microwave irradiation;微波合成半导体CuS纳米粒子和Bi_2S_3纳米棒
12.Preparation of Magnetic Transition Metal Nanoparticles in W/O Microemulsion;微乳液法制备过渡金属磁性纳米粒子
13.Study on Microwave absorbers based on Iron Nano-particles and Nanocomposite Particles;铁纳米(复合)粒子微波吸收剂的研究
14.Study on Layer Silicate Nanoparticles to Reduce the Retention of Lead in Finishing Pigs;纳米级硅酸盐微粒吸附饲料铅的研究
15.Preparation of semiconductor ZnS nanoparticles with microwave irradiation;微波辐射加热制备半导体ZnS纳米粒子
16.Catalyzed Synthesis of α-Fe_2O_3 Nanoparticles in the Microreactor微反应器中催化制备α-Fe_2O_3纳米颗粒
17.HRTEM investigation of gold nanoparticles金纳米颗粒的高分辨电子显微学研究
18.Effect of Nano-CuO particulate on performance of refrigeration oil纳米CuO微粒对冷冻机油性能的影响
相关短句/例句
nanoparticle纳米微粒
1.Synthesizing Metal Oxide and Chalcogenide Nanoparticles from Hydrothermal/Solvothermal Reactions;水热/溶剂热制备金属氧族化合物纳米微粒
2.Preparation and characterization of ternary Pb-Sn-Cd all oy nanoparticles;Pb-Sn-Cd三元合金纳米微粒的制备与表征
3.Discussions on the characteristics of particle size in the pedagogical experiments of nanoparticle preparation experiment;对纳米微粒制备教学实验中微粒尺寸表征的探讨
3)Nanometer particle纳米微粒
1.Properties,preparation and evaluation of nanometer particle;纳米微粒的特性、制备及评估综述
2.Preparation of ZnO nanometer particles by Sol-Gel method;ZnO纳米微粒的制备与表征
3.Reversal of antibiotic resistance methicillanin-resistant staphylococcus aureus by polyethyleneimine-phosphothioate oligodeoxynucleotide nanometer particle;反义寡核苷酸-聚乙烯亚胺纳米微粒逆转耐甲氧西林金黄色葡萄球菌耐药性的研究
4)Nano-particle纳米微粒
1.Nano-particle has surface effect,quantum dimension effect,and macro quantum effect and so on, which make nano-particle have particular physical and chemical properties.纳米微粒具有的表面效应、量子尺寸效应、宏观量子隧道效应等使纳米微粒具有特殊的物理和化学性质。
2.The composition of a new trivalent chromium passivating solution were introduced,and sealers with nano-particles were used in the solution.该钝化液采用含有纳米微粒的封孔剂。
5)nanometer particles纳米微粒
1.Effects of Quantum Confinement Effect on the Properties of Exciton in SnO_2 Nanometer Particles;量子限域效应对二氧化锡纳米微粒激子特性的影响
2.This thesis deals with the various kinds of production methods of the nanometer particles at present from a general point of view ,and tries to make comparison and comment on the characteristics of each method for the purpose of expecting to bring a further study and broader application to the new material.综述目前纳米微粒的各种制备方法 ,比较和评述了每种方法的特点 ,以期这一新材料能得以更为深入地研究和更广泛地应
3.The hydrosol and the organosol of SnO_2·ZnO nanometer particles were prepared by colloid chemistry method.应用L-B膜技术制备了SnO_2·Zno纳米微粒/硬脂酸交替L-B膜,用原子力显微镜观察了SnO_2·ZnO纳米微粒/硬脂酸交替L-B膜的形貌。
6)microparticle/nanoparticle微粒/纳米粒
延伸阅读
看纺织印染中应用纳米材料和纳米技术纺织印染中应用纳米材料和纳米技术时,除了要解决纳米材料的制备技术之外,重要的是要解决好纳米材料的应用技术,其中关键问题是使纳米粒子和纺织印染材料的基本成分(即聚合物材料)之间处于适当的结合状态。印染中,纳米粒子在聚合物基体中的分散和纳米粒子在聚合物表面的结合是主要的应用技术问题。 制备聚合物/无机纳米复合材料的直接分散法,适用于各种形态的纳米粒子。印染中纳米粒子的使用一般采用直接分散法。但是由于纳米粒子存在很大的界面自由能,粒子极易自发团聚,利用常规的共混方法不能消除无机纳米粒子与聚合物基体之间的高界面能差。因此,要将无机纳米粒子直接分散于有机基质中制备聚合物纳米复合材料,必须通过必要的化学预分散和物理机械分散打开纳米粒子团聚体,将其均匀分散到聚合物基体材料中并与基体材料有良好的亲和性。直接分散法可通过以下途径完成分散和复合过程: 高分子溶液(或乳液)共混:首先将聚合物基体溶解于适当的溶剂中制成溶液(或乳液),然后加入无机纳米粒子,利用超声波分散或其他方法将纳米粒子均匀分散在溶液(或乳液)中。有人将环氧树脂溶于丙酮后加入经偶联剂处理过的纳米TiO2,搅拌均匀,再加入 40wt%的聚酰胺后固化制得了环氧树脂/TiO2纳米复合材料。还有人将纳米SiO2粒子用硅烷偶联剂处理后,改性不饱和聚酯。 熔融共混:将纳米无机粒子与聚合物基体在密炼机、双螺杆等混炼机械上熔融共混。如将PMMA和纳米SiO2粒子熔融共混后,双螺杆造粒制得纳米复合材料。又如利用偶联剂超声作用下处理纳米载银无机抗菌剂粒子,分散制得PP/抗菌剂、PET/抗菌剂、PA/抗菌剂等复合树脂,然后经熔融纺丝工艺加工成抗菌纤维。研究表明,将经过表面处理的纳米抗菌剂粒子通过双螺杆挤出机熔融混炼,在聚合物中可以达到纳米尺度分散,获得了具有良好综合性能的纳米抗菌纤维,对大肠杆菌、金黄色葡萄球菌的抗菌率达到95%以上(美国AATCC-100标准)。 机械共混:将偶联剂稀释后与碳纳米管混合,再与超高分子量聚乙烯(UHMWPE)混合放入三头研磨机中研磨两小时以上。将研磨混合物放入模具,热压,制得功能型纳米复合材料。 聚合法:利用纳米SiO2粒子填充(Poly(HEMA))制备了纳米复合材料。纳米SiO2粒子首先被羟乙基甲基丙烯酸(HEMA)功能化,然后与HEMA单体在悬浮体系中聚合。还有利用SiO2胶体表面带酸性,加入碱性单体4-乙烯基吡咯进行自由基聚合制得包覆型纳米复合材料。
