反应器内流场分布对球形氢氧化镍生长结晶的影响

在相同停留时间、不同搅拌桨线速度条件下,利用化学沉淀法制备球形氢氧化镍样品并运用SEM技术考察制得样品的形貌。研究表明:在相同的停留时间和化学条件下,随着搅拌桨线速度的提高样品的微观形貌由无定型状晶体变为大颗粒类球状晶体再变为较规则的球状晶体。利用PIV物理模拟技术模拟反应器内流场分布情况并结合XRD表征结果分析得出:在相同的停留时间和化学条件下,反应器内流场分布越均匀、速度矢量越大氢氧化镍晶体的生长越完整,结晶性、球形度和相对结晶度越高,并从流场分布的角度描述了球形氢氧化镍生长结晶的过程。     

反应器内流场分布对球形氢氧化镍生长结晶的影响（英文）

在相同停留时间、不同搅拌桨线速度条件下,利用化学沉淀法制备球形氢氧化镍样品并运用SEM技术考察制得样品的形貌。研究表明:在相同的停留时间和化学条件下,随着搅拌桨线速度的提高样品的微观形貌由无定型状晶体变为大颗粒类球状晶体再变为较规则的球状晶体。利用PIV物理模拟技术模拟反应器内流场分布情况并结合XRD表征结果分析得出:在相同的停留时间和化学条件下,反应器内流场分布越均匀、速度矢量越大氢氧化镍晶体的生长越完整,结晶性、球形度和相对结晶度越高,并从流场分布的角度描述了球形氢氧化镍生长结晶的过程。     

晶面选择性生长对球形氢氧化镍形貌及电化学活性的影响

在相同的物理化学条件、不同晶化时间的条件下,采用化学沉淀法制备球形氢氧化镍晶体并应用SEM技术分别考察制得样品的形貌。研究表明：在相同的物理化学条件下,随着晶化时间的增加,样品的微观形貌由不规则状晶体变为完整的球状晶体。结合XRD表征结果分析得出：（001）晶面在晶化时间达到3 h时生长到了一个稳定的状态,并不随着晶化时间的增加而有明显的变化,但（100）与（101）晶面随晶化时间的增加继续生长,当晶化时间达到12 h时氢氧化镍的相对结晶度最大,（100）与（101）衍射峰强度高且峰形尖锐,说明氢氧化镍晶体的结构规整性增强。本文还讨论了氢氧化镍生长结晶过程中晶面选择性生长对晶体形貌及电化学性能的影响。     

晶面选择性生长对球形氢氧化镍形貌及电化学活性的影响

在相同的物理化学条件、不同晶化时间的条件下,采用化学沉淀法制备球形氢氧化镍晶体并应用SEM技术分别考察制得样品的形貌。研究表明：在相同的物理化学条件下,随着晶化时间的增加,样品的微观形貌由不规则状晶体变为完整的球状晶体。结合XRD表征结果分析得出：（001）晶面在晶化时间达到3 h时生长到了一个稳定的状态,并不随着晶化时间的增加而有明显的变化,但（100）与（101）晶面随晶化时间的增加继续生长,当晶化时间达到12 h时氢氧化镍的相对结晶度最大,（100）与（101）衍射峰强度高且峰形尖锐,说明氢氧化镍晶体的结构规整性增强。本文还讨论了氢氧化镍生长结晶过程中晶面选择性生长对晶体形貌及电化学性能的影响。     

晶面选择性生长对球形氢氧化镍形貌及电化学活性的影响（英文）

在相同的物理化学条件、不同晶化时间的条件下,采用化学沉淀法制备球形氢氧化镍晶体并应用SEM技术分别考察制得样品的形貌。研究表明:在相同的物理化学条件下,随着晶化时间的增加,样品的微观形貌由不规则状晶体变为完整的球状晶体。结合XRD表征结果分析得出:(001)晶面在晶化时间达到3 h时生长到了一个稳定的状态,并不随着晶化时间的增加而有明显的变化,但(100)与(101)晶面随晶化时间的增加继续生长,当晶化时间达到12 h时氢氧化镍的相对结晶度最大,(100)与(101)衍射峰强度高且峰形尖锐,说明氢氧化镍晶体的结构规整性增强。本文还讨论了氢氧化镍生长结晶过程中晶面选择性生长对晶体形貌及电化学性能的影响。     

不同形貌氧化锌的微波水热法制备及其光催化性能

采用微波水热法在乙二醇的辅助下,制备出一系列不同形貌的氧化锌(Zn O)纳米/微米颗粒。扫描电子显微镜测试结果表明,乙二醇的加入量对样品的形貌有着非常显著的影响,通过控制乙二醇的加入量,可以得到不规则片状、六方棱柱孪晶、梭子形和球形等形貌的Zn O纳米/微米颗粒。从微波反应器检测压力结果可以看出,乙二醇的加入量对反应体系的压力影响非常显著,这起到了调控纳米晶生长速度的效果进而得到不同形貌的样品。在此基础上,系统测试了样品在氙灯照射下光催化降解罗丹明B的能力,结果表明,乙二醇加入量大于12 m L时的球状样品光催化效率要远高于其他样品,在50 min内能完成对罗丹明B的降解。     

基于不同还原剂体系银粉的可控制备

以硝酸银为原料,在不同温度条件下,分别以无机和有机还原剂,制备了不同形貌的银粉颗粒,采用扫描电子显微镜以及X射线衍射对其形貌与结构进行了表征。在此基础上,重点研究了不同还原体系对银粉颗粒形貌的影响,并提出了相应的机理。研究结果表明,以七水合硫酸亚铁作为还原剂时,银颗粒形貌由铁离子浓度控制,在高浓度,低反应速度条件下可得到花状银颗粒。随着体系浓度的下降,表面由粗糙花状变为光滑球状,导电性能并随之升高。以抗坏血酸作为还原剂,硫酸根为保护剂时,硫酸根浓度对银粉形貌有着很大的影响,随着硫酸根浓度的增加,银颗粒由球形变为枝片状。导电性能有所升高。     

基于不同还原剂体系银粉的可控制备

以硝酸银为原料,在不同温度条件下,分别以无机和有机还原剂,制备了不同形貌的银粉颗粒,采用扫描电子显微镜以及X射线衍射对其形貌与结构进行了表征。在此基础上,重点研究了不同还原体系对银粉颗粒形貌的影响,并提出了相应的机理。研究结果表明,以七水合硫酸亚铁作为还原剂时,银颗粒形貌由铁离子浓度控制,在高浓度,低反应速度条件下可得到花状银颗粒。随着体系浓度的下降,表面由粗糙花状变为光滑球状,导电性能并随之升高。以抗坏血酸作为还原剂,硫酸根为保护剂时,硫酸根浓度对银粉形貌有着很大的影响,随着硫酸根浓度的增加,银颗粒由球形变为枝片状。导电性能有所升高。     

同向啮合双螺杆挤出机挤出过程的计算机模拟

计算机模拟研究了聚苯乙烯在TSE-35A型同向啮合双螺杆挤出机的挤出过程.计算得到不同喂料速率与不同转速下的停留时间分布,并与在线荧光法测量值对比,二者基本相符.确定了停留时间与螺杆转速及喂料速率之间的函数关系式.模拟结果还预测了喂料速率、螺杆转速等工艺参数对双螺杆内流场变量,如温度、填充率、压力及粘度等的影响.模拟计算有助于了解双螺杆挤出机内部聚合物材料流动状态及停留时间长短,从而指导实际聚合物生产.     

纳米磷灰石晶体的制备

在人体骨中,不同的年龄段,不同部位的生物磷灰石晶体的尺寸和形貌有差异[1-3],人们已经制备出纳米级类骨磷灰石晶体模拟天然骨磷灰石。合成方法、条件、反应的前驱物等不一样,得到晶体的形貌、尺寸也不一样[3,4]。本文用硝酸钙的二甲基甲酰胺溶液和磷酸钠水熔液反应制备纳米磷灰石晶体并研究其形貌和尺寸。1　材料和方法30克分析纯硝酸钙在搅拌下加入45克分析纯二甲基甲酰胺中(A)。18克分析纯磷酸纳溶解于1500ml去离子水中(B)。B加热到25℃,不断搅拌下,缓缓将溶液A滴入其中,滴定完后继续搅拌2h,温度控制在70℃。室温陈化24h、离心分离…     

The relationship of spherical nano-Ni(OH)2 microstructure with its voltammetric behavior

The spherical nano-Ni(OH)₂ has been characterized by a series of spectra methods such as the scanning electron microscope (SEM), the transmission electron microscope (TEM) and the X-ray diffraction (XRD). The electrochemical behavior of spherical nano-Ni(OH)₂, attached to a graphite electrode and adjacent to an aqueous KOH-KCl electrolyte solution, has been studied by cyclic voltammetry. Spherical nano-Ni(OH)₂ exhibits a pair of quasi-reversible redox peaks. The relationship of the granularity and the potential was investigated, as well as the effect of different pH conditions. Moreover, the cycling experiments have been set up using spherical nano-Ni(OH)₂ and traditional analytical grade Ni(OH)₂, respectively, and their cycling performances were evaluated as well. The capacity of spherical nano-Ni(OH)₂ is ca. ten times higher than the one with the traditional material under the same conditions, which shows its better electrochemical properties.     

Three-dimensional roselike α-Ni(OH)2 assembled from nanosheet building blocks for non-enzymatic glucose detection

Glucose detection plays very important roles in diagnostics and management of diabetes. The search for novel catalytic materials with appropriate architectures is the key step in the fabrication of highly sensitive glucose sensors. In this work, α-Ni(OH)₂ roselike structures (Ni(OH)₂-RS) assembled from nanosheet building blocks were successfully synthesized by a hydrothermal method through the hydrolysis of nickel chloride in the mixed solvents of water and ethanol with the assistance of polyethylene glycol (PEG). The structure and morphology of the roselike α-Ni(OH)₂ were characterized by transmission electron microscopy (TEM), field emission scanning electron microscopy (FE-SEM), X-ray photoelectron spectroscopy (XPS), X-ray powder diffraction (XRD) and N₂ adsorption–desorption isotherm measurement. TEM and FE-SEM images showed that the synthesized Ni(OH)₂ was roselike and the size of the leaf-shaped nanosheet was about 5 nm in thickness, which leads to larger active surface areas and faster electron transfer for the detection of glucose. Compared with the bare GCE and bulk Ni(OH)₂/GCE, the Ni(OH)₂-RS/GCE had higher catalytic activity toward the oxidation of glucose. Under the optimal conditions, the Ni(OH)₂-RS/GCE offers a variety of merits, such as a wide linear response window for glucose concentrations ranging from 0.87 μM to 10.53 mM, short response time (3 s), a lower detection limit of 0.08 μM (S/N = 3), as well as long term stability and repeatability.     

Nanocrystalline nickel cobalt hydroxides/ultrastable Y zeolite composite for electrochemical capacitors

A novel nanocomposite of Co(OH)₂−Ni(OH)₂ and ultrastable Y molecular sieves was synthesized by an improved chemical precipitation method for electrochemical capacitors. The Co(OH)₂−Ni(OH)₂/ultrastable Y zeolite (USY) composite and its microstructure were characterized by scanning electron microscopy, transmission electron microscopy, and X-ray diffraction. Electrochemical characterization was performed by cyclic voltammetry and galvanostatic charge–discharge measurements. The results show that Co(OH)₂−Ni(OH)₂/USY microstructure applied for the electrochemical energy storage has displayed superior capacitive performance. The effect of heat treatment conditions on specific capacitance properties was also systemically explored. Upon annealing at 250 °C, the maximum specific capacitance was up to 479 F/g (or 1,710 F/g after correcting for the weight percent of Co(OH)₂−Ni(OH)₂ phase). Annealing temperatures higher than 250 °C may cause the hydroxide to form oxide phase and decrease the surface activity of the oxide, thereby leading to a decline of the specific capacitance.     

前驱体Ni(OH)2对LiCo0.3Ni0.7O2正极材料的影响研究

研究了两种不同前驱体Ni(OH)₂对LiCo_0.3Ni_0.7O₂锂离子电池正极材料的结构与电化学性能的影响，并用XRD、SEM及电性能测试考察了材料的结构、形貌与电化学性能。结果表明，前驱体Ni(OH)₂的形貌、结晶形态对LiCo_0.3Ni_0.7O₂正极材料的性能有极大的影响。与目前镍酸锂合成需高密度球形镍前驱体Ni(OH)₂认识不同，本文发现呈枝晶网络状结构、表面蓬松、比表面积高和振实密度低的前驱体Ni(OH)₂具有较高的化学活性，可有效抑制产物LiCo_0.3Ni_0.7O₂正极材料中阳离子混排产物的生成。由其制备的目标正极材料LiCo_0.3Ni_0.7O₂显示出较优的电化学性能，首次放电容量为175 mAh·g^-1，首次放电效率为93.9%，40次循环容量保持率为94.8%，显示较好的循环稳定性。     

矿化剂对水热法改性氢氧化镁晶体的影响

近几年来,氢氧化镁作为一种无机阻燃剂由于其具有制备条件相对温和,生产工艺简单且产品与自然环境友好等特点,在研究及生产活动方面备受关注且得到了长足的发展[1～4].目前采用氢氧化钠法进行反应一水热制备高分散阻燃级氢氧化镁的工艺路线已经比较成熟[5～8].然而,不利的是,氢氧化钠偏高的价格导致了产品的制造成本较高.而采用石灰法制备氢氧化镁阻燃剂具有价格低廉的特点,引起了人们的关注.     

3D nanostructured Ni(OH)2 microspheres as an efficient immobilization matrix of Ru(bpy)3 for high-performance electrochemiluminescence sensor

The electrochemistry and electrochemiluminescence (ECL) of novel three-dimensional nanostructured Ru(bpy)₃²⁺/Ni(OH)₂ microspheres were investigated for the first time. The negatively charged porous Ni(OH)₂ microspheres composed of Ni(OH)₂ nanowires were specifically designed to interact with Ru(bpy)₃²⁺. The large surface area and porous structure of Ni(OH)₂ microspheres enhance loading of Ru(bpy)₃²⁺ and mass transport of the model analyte, tripropylamine (TPA). Excellent ECL performance of the presented sensor was achieved including good stability and wide linear range from 7.7 × 10⁻¹⁰ to 3.8 × 10⁻³ M with the detection limit of 2.6 × 10⁻¹⁰ M to TPA.     

高密度非球形和球形LiNi1/3Mn1/3Co1/3O2的合成和性能比较

利用二次干燥法和共沉淀法分别制备出了非球形的Ni_1/3Co_1/3Mn_1/3OOH前驱体和球形Ni_1/3Co_1/3Mn_1/3(OH)₂前驱体, 并分别和LiNO₃混合烧结合成高密度非球形和球形的锂离子正极材料Li(Ni_1/3Co_1/3Mn_1/3)O₂. XPS分析表明, 二次干燥法制备的非球形Ni_1/3Co_1/3Mn_1/3OOH前驱体其过渡金属Ni, Co和Mn的价态分别是＋2, ＋3和＋4, 而共沉淀法制备的球形Ni_1/3Co_1/3Mn_1/3(OH)₂前驱体其各金属价态为＋2; X射线衍射分析表明, 非球形的Ni_1/3Co_1/3Mn_1/3OOH前驱体比球形的前驱体具有较高的活性, 能够在低温下合成出Li(Ni_1/3Co_1/3Mn_1/3)O₂, 而且制备的产物结晶度高, 具有规整的层状α-NaFeO₂结构, 扫描电镜显示制备的非球形产物颗粒均匀, 颗粒间隙小, 振实密度高达2.95 g•cm^－3, 远高于球形的振实密度2.35 g•cm^－3; 充放电实验表明, 由非球形前驱体制备的Li(Ni_1/3Co_1/3Mn_1/3)O₂其充放电性能和循环性能以及体积比容量均高于球形正极材料.     

球型Ni(OH)2表面包覆Y(OH)3及其高温充放电性能

应用共沉淀的方法在球型Ni(OH)₂的表面包覆了一层Y(OH)₃,并研究了包覆不同含钇量后的球型Ni(OH)₂的高温充放电性能。研究结果表明:包覆Y(OH)₃的球型Ni(OH)₂具有良好的高温充放电性能。其中1C充放电条件下,包覆量为0.3%的Ni(OH)₂较好,0.2C充放电条件下,包覆量为1%的Ni(OH)₂较好。     

Ball-milling processing of nanocrystalline nickel hydroxide and its effects in pasted nickel electrodes for rechargeable nickel batteries

Nanocrystalline Ni(OH)₂ powder synthesized by a chemical precipitation method was processed using the planetary ball milling (PBM), and the physical properties of both the ball-milled and unmilled Ni(OH)₂ were characterized by scanning electron microscopy (SEM), specific surface area, particle size distribution, and X-ray diffraction. It was found that the PBM processing could significantly break up the agglomeration, uniformize the particle size distribution, increase the surface area, decrease the crystallite size, and reduce the crystallinity of nanocrystalline β-Ni(OH)₂, which were advantageous to the improvement of the electrochemical activity of Ni(OH)₂. The ball-milled nanocrystalline (BMN) Ni(OH)₂ was then used to alter the microstructure of pasted nickel electrodes and improve the distribution of the active material in the porous electrode substrate. Electrochemical performances of pasted nickel electrodes with a mixture of BMN and spherical Ni(OH)₂ as the active material were investigated, and were compared with those of pure spherical Ni(OH)₂ electrodes. Charge/discharge tests showed that BMN Ni(OH)₂ addition could enhance the charging efficiency, specific discharge capacity, discharge voltage, and high-rate capability of pasted nickel electrodes. This performance improvement could be attributed to a more compact electrode microstructure, better reaction reversibility, and lower electrochemical impedance, as indicated by SEM, cyclic voltammetry, and electrochemical impedance spectroscopy. Thus, it was an effective method to modify the microstructure and improve the electrochemical properties of pasted nickel electrodes by adding an appropriate amount of BMN Ni(OH)₂ to spherical Ni(OH)₂ as the active material.