Mn、Cu共掺ZnO磁性的研究

本文采用水热法,分别以ZnO、Zn(OH)2为前驱物,添加一定量的MnCl4.4H2O和CuSO4.2H2O, 3mol/LKOH作矿化剂,温度430℃,填充度35%,反应24h,制备了Mn、Cu共掺ZnO晶体。当前驱物为Zn(OH)2时,所得晶体大部分为短柱状晶体,显露正负极面{0001}、{0001-}、负锥面-p{101-1-}和柱面m{1-010},长度约为30 ～50μm。少部分晶体为单锥六棱柱状,显露正锥面p{101-1},柱面m{1-010},负极面-c{0001-},晶体的长度约为100μm,长径比为5:1。当ZnO用作前驱物时,短柱状晶体长度大约为10 ～30μm,晶体的六棱对称性都出现较大的偏差。X射线荧光能谱分析表明,前驱物为ZnO、Zn(OH)2时,Mn离子含量在分别为3.19%和1.62%原子分数,没有检测到Cu离子。虽然Mn、Cu离子的掺入会明显影响晶体形态,磁性测量显示掺杂Mn、Cu的ZnO仍为反铁磁。     

水热法合成Zn1-xMnxO稀磁半导体

本文采用水热法在430℃,以3mol%.L-1KOH作矿化剂,填充度为35%,反应时间24h,合成了Zn1-xMnxO稀磁半导体晶体。所合成晶体具有ZnO纤锌矿结构,晶面显露正极面{0001}、负极面{0001}、菱面{1011}及负菱面{1011}晶体高度为5~30μm,径高比约为2:1。X荧光能谱(EDS)显示Mn原子百分浓度为2.6%(x=0.026)。晶体呈现低温铁磁性,居里温度50K。     

水热法合成Zn1-xMnxO：Sn和Zn1-x-yMnxCoyO：Cu晶体的磁性

本文采用水热法,以ZnO为前驱物,添加适量的MnCl2·4H2O、SnCl2·2H2O和MnCl2·4H2O、CoCl2·6H2O、CuCl2·2H2O,3 mol/L KOH作矿化剂,430℃反应24 h,分别合成了Zn1-xMnxO:Sn晶体和Zn1-x-yMnxCoyO:Cu晶体.用扫描电镜(SEM)对合成物形貌进行分析,结果表明,Zn1-MnxO:Sn晶体为六棱柱状晶体,直径约为10 μm,较大面积显露正极面c{0001},同时也显露负极面-c{0001}、正锥面p{1011}、负锥面-p{1011}和柱面m{1010}.Zn1-x-yMnxCoyO:Cu晶体也显露负极面-c{0001}、正锥面p{1011}、负锥面-p{1011}和柱面m{1010},{0001}显露面小于{0001}.X射线能谱(EDS)分析表明晶体主要成分为ZnO,Mn2 、Co2 离子掺杂量超过2%;SQUID磁性测量显示所合成晶体在25 K具有反铁磁特征,高温为顺磁性.     

In掺杂对水热法合成ZnO晶体形貌的影响

本文采用水热法,在ZnO中添加In2O3为前驱物,3mol/L KOH作矿化剂,温度430℃,填充度35;,反应24h,制备了掺In的ZnO晶体.未掺杂In2O3合成的纯ZnO晶体呈六棱锥状,显露负极面-c{0001}、六棱锥面+p{1011}和-p{1011},一般不显露{0001}面.前驱物中掺杂In2O3所合成的ZnO晶体呈六角片状,直径约为5～20 μm,大面积显露{0001}面,另外还显露正锥面+p{1011}、负锥面-p{1011}和负极面-c{0001}.由此可见In掺杂可以明显的改变晶体的形态,使c轴极性快速生长趋向得到明显改善,有利于降低晶体生长缺陷.当采用ZnO晶片为籽晶时,通过水热反应在晶片上生长了一层掺In的ZnO薄膜,通过Hall参数测量得到晶体膜层的电子迁移率约为22cm2/(V·s),载流子浓度约为2×1020 cm-3,具有良好的导电性,同时也说明In可以微量掺入氧化锌晶体.     

LiOH矿化剂对水热合成ZnO晶体形貌的影响

本文研究了在430℃,填充度为35用了3mol/L,5mol/L LiOH做矿化剂,所获得晶体均为10μm以下的微晶.当矿化剂为1mol/L LiOH和1mol/L KBr时,所获得晶体同样为几微米的微晶,显露完整的正极面{0001}、负极面{0001}、锥面{1011}和柱面{1010}.矿化剂为3M LiOH和3M KBr时,出现个体较大的晶体,直径超过100μm,显露正极面{0001}、正锥面{1011}和柱面{1010},负极面出现缺损现象.由此说明和K+相比溶液中的Li+不利于生成大尺寸ZnO晶体.     

常压化学水解反应生长氧化锌晶体

采用ZnCl2·2H2O在常压下高温水解反应生长ZnO晶体,反应温度为500℃.当以SiC为衬底时,可以获得六棱柱形氧化锌晶体,直径约为10μm,长为30～100 μm.当衬底为蓝宝石时,氧化锌沿[0001]呈定向柱状生长,柱的直径为5～10 μm,柱之间具有较多的内部缺陷.当以ZnO为衬底时,在{0001}面,形成连续膜,表面扫描电镜分析表明,晶体具有明显的极性生长特征,[0001]方向呈螺旋柱状生长.在{0001}面,晶体的平整性较好,呈现台阶性生长.     

Sn掺杂对ZnO晶体形貌和磁性的影响

采用水热法,在ZnO中添加SnCl2.2H2O作前驱物,3M KOH作矿化剂,温度430℃,填充度35%,反应24h,合成了掺杂Sn的ZnO晶体。当前驱物中添加SnCl2.2H2O可以明显影响部分晶体形态,使正极面c轴方向的生长速度受到抑制,较大面积显露正极面c{0001},同时也显露负极面-c{000 1}、正锥面p{10 10}、负锥面-p{101 1}和柱面m{10 10}。磁性测量结果显示Sn可微量掺入ZnO晶格中,且呈现顺磁性特征。X射线衍射和X光荧光能谱分析表明,SnCl2.2H2O的添加量较大时,还伴随生成金红相SnO2棒状晶体。     

不同矿化剂对水热法生长的ZnO晶体发光的影响

采用水热法,以3 mol/L KOH为矿化剂,填充度35%,温度430℃,前驱物Zn(OH)2,比较研究了三种矿化剂条件下合成晶体的形貌和发光性能。三种矿化剂条件分别为样品1,3 mol/L KOH;样品2,3 mol/L KOH,1 mol/LLiOH;样品3,3 mol/L KOH,CaO∶Zn(OH)2=2%(物质的量百分比)。添加适量比例的LiOH或CaO,合成了非极性生长的ZnO晶体,晶体c轴方向生长速度明显减小,所合成的晶体大面积显露正极面c{0001},同时显露负极面-c{0001}、正锥面p{101}、负锥面-p{10}和柱面m{100}。只添加KOH或辅助添加LiOH时,合成晶体的发光光谱中只有可见光谱,无紫外线带边跃迁发光谱,说明晶体缺陷发光中心较多。添加CaO时合成晶体的发光光谱中有较强的紫外带边跃迁发光,说明晶体缺陷发光中心减少。     

In和过渡金属离子共掺杂对ZnO晶体形貌的影响

采用水热法,KOH作矿化剂,在ZnO前驱物中添加适量的CoCl2·6H2O,FeCl2·4 H2O,NiCl2·6H2O,In2O3,其中Co:In:Zn,Fe:In:Zn,Ni:In:Zn 分别为5:1:100,5:1:100,3:1:100.3 mol/L KOH作矿化剂,温度430 ℃,填充度35;,反应24 h,制备了In和过渡族金属离子共掺的ZnO晶体.结果表明,掺杂In2O3时,所合成的过渡族金属离子掺杂的ZnO晶体均呈现六角片状晶体,晶体形貌规则,表面光滑,直径为5～10 μm.和未掺杂In的晶体相比,掺杂In后,晶体c轴极性生长速度得到明显的控制,a、b轴方向生长速度提高,大面积显露+c{0001}、负极面-c{0001}面,另外还显露正锥面+p{1011}、负锥面-p{101-1-}.     

Co、Sn共掺杂ZnO晶体的制备及其磁性

采用6 mol/L KOH作为矿化剂,SnO2、CoCl2和ZnO按物质的量比为0.02∶0.5∶1的比例混合作为前驱物,填充度70;,温度430℃,时间24h,采用水热法制备出Co、Sn元素掺杂的ZnO晶体.Sn元素掺杂明显改变了晶体的极性生长特征,较大面积的显露正极面c｛0001｝面,还显露柱面m{l0l0｝、正锥面p{1011｝、负锥面｛1011｝和负极面｛0001｝以及正锥面{1012｝和负锥面{1012｝,晶体长度约为50 μm.经过EDS测量表征,发现制备的ZnO单晶中Co元素的含量达到10.89at;,生成物中出现少量Co氧化物,SQUID测量表明样品主要表现为顺磁性.     

氧化锌单晶的水热生长与结晶习性

本文应用水热生长法,采用双温区高压反应釜,黄金内衬(φ35mm ×2mm),碱性溶液矿化剂,生长出了毫米级的透明氧化锌单晶,最大单晶可达2mm ×3mm ×6mm.所生长氧化锌晶体为纤锌矿型的六方晶体,晶体呈上部锥形的六棱柱体,{10(1-)1}、{10(1-)0}和{000(1-)}面有较大的显露平面.本文中从温差和填充度方面研究了实验条件对ZnO晶体的生长及其形貌的影响,使用黄金内衬前后的结果表明,用贵金属内衬可以有效阻止釜内壁杂质的进入,使晶体完整透明.     

Morphology of gallium orthophosphate crystals grown under hydrothermal conditions

Gallium orthophosphate crystals with sizes of 5 mm and more have been obtained by spontaneous nucleation from hydrothermal 5.6 – 15 M orthophosphoric acid solutions. Preferable concentrations of solvent were found in the range of 11 – 12 M, the temperature difference should not be over 6–10°C at the heating rate of 4 – 5 °C/day. Morphological investigations are carried out using optical and polarizing microscopies. GaPO₄ crystals, like quartz and berlinite, tends to grow with well developed {1 1}, {0 1}, {1 0}, {1 2}, and {0 2} faces, and they were divided into three habit types. Effect of orthophosphoric acid concentration on the crystal habit has been studied.     

热电池MnO2/石墨烯正极制备及电性能研究

采用水热法合成了MnO2/石墨烯复合材料,通过扫描电子显微镜( SEM)分析了材料的表面形貌,通过X射线衍射(XRD)和X射线光电子能谱(XPS)表征了材料的晶相结构和组成,采用恒流放电的方式对LiSi/LiCl-KCl/( MnO2/G)单体电池进行了电性能的测试。测试结果表明反应体系中加入GO后获得的材料由大量的纳米花球式和纳米棒式结构无规则的交织排列在一起,α-MnO2纳米簇结构依附在石墨烯纳米片上;产物在2θ为22°~27°时出现了较宽的无序堆叠的石墨烯的衍射峰;Mn元素氧化后离子状态为Mn4+;LiSi/LiCl-KCl/( MnO2/G)单体电池有两个放电平台,分别为2.58 V、1.96 V,放电电压截止到1.0 V时,对应的放电比容量达到1150.2 mAh/g。     

Analysis of growth habits of polar organic crystal N-4-nitrophenyl-(L)-prolinol (NPP) based on the incorporation of growth units

The growth habits of the polar organic crystal N-4-nitrophenyl-(L)-prolinol (NPP) in organic solvents have been studied from the standpoint of the incorporation of growth units. Qualitative explanations of the observed growth forms are based on (1) the interaction between the solvent molecules and the growth units, and (2) the influence of the solvent molecules on growth interfaces, particularly on two polar faces of the polar organic crystal. Since the incorporation rates of the growth units are different on positive and negative polar faces, a variety of growth habits appear. The surface structures of the grown crystal have been investigated through ex-situ observations of atomic force microscopy (AFM).     

水热法BSO晶体腐蚀像及与晶体对称的关系

对水热法生长的两种不同结晶习性的 BSO晶体进行了腐蚀像的观察研究,得到了{100}、{110}、{211}、{111}晶面的腐蚀形貌特征,建立了BSO晶体腐蚀像在三维空间分布的立体模型。研究发现不同单形晶面的蚀坑形态不同,但都体现了晶体的对称性。不同晶面腐蚀难易程度与晶体结构有关。     

Optical imaging of the growth kinetics and polar morphology of zinc tris(thiourea) sulphate single crystals

Growth kinetics of zinc tris(thiourea) sulphate (ZTS) single crystals was imaged in two different growth geometries using laser shadowgraphy technique. Growth rates of the {010} and {001} faces were computed as a function of supersaturation. The time evolution of polar morphology of ZTS crystal based on the growth rates is presented. Except (00 ) face, all the other three faces are found to have a dead zone resulting in large induction period of growth. The anisotropy in the growth rates of the (001) and (00 ) faces was very high, resulting in polar morphology. Different chemical environments on two sides of the (001) slice are suggested as the possible cause for the polar morphology of the crystals. (© 2010 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Compaction of adsorbed alkali metal submonolayers on the {111} and {0001} surfaces of metal crystals

The structural mechanism has been suggested of formation of the ordered surface hexagonal structures with an increase of the coverage during adsorption of alkali metal atoms on the {111} surfaces of face-centered cubic and {0001} surfaces of a hexagonal metal crystal. The coverage θ_s providing the formation of close-packed hexagonal adsorbed layers in adsorption systems is determined for alkali metals. The theoretically calculated and the experimentally obtained θ_s values are in good agreement.     

Kinetic Investigations within the Transition Region from Polyhedral to Skeletal Growth Mode (V). Growth Kinetics of the Pyramidal Face of Zinc Single Crystals under Diffusion Conditions

The growth kinetics of the pyramidal face of zinc single crystals is studied in the presence of argon. The curves size vs. time provide evidence that smaller crystals grow in a kinetic regime and after reaching a certain critical size their growth continues in a diffusion regime. The growth kinetics of faces {101 } and {0001} are compared. It is established that the growth of both faces simultaneously changes from a kinetic to a diffusion growth mode. During the transition between the two regimes, however, loss of the morphological stability only of the smooth {0001} face is observed, while the {101 } face with macro steps formed on the surface acquires a skeletal shape after prolonged growth. It is shown that the appearance of morphological instability depends on the surface structure of the crystal faces.