Effects of Phosphate Fertilizer on Cold Tolerance and Its Related Physiological Parameters in Rice Under Low Temperature Stress

The study was designated to explore the physiological mechanism of cold tolerance enhanced by phosphate in rice. An experiment was conducted to investigate the effects of different levels of phosphate fertilizer on cold tolerance and its related physiological parameters in rice seedings （chilling-sensitive cv. Changbai 9 and chilling-tolerant cv. Jijing 81） under low temperature stress. At the same time, the identification of cold tolerance was conducted. Compared with the normal temperature treatment, the relative chlorophyll content, photosynthesis rate, Fv/Fm and qP decreased and index of unsaturated fatty acid increased in rice under low temperature stress. The effect of chilling-sensitive cultivars was more than that of chilling-tolerant cultivars, more phosphorus fertilizer properly improved seedling quality of rice, slowed relative chlorophyll content dropping degree of rice seeding, increased photosynthesis rate, Fv/Fm, qP and index of unsaturated fatty acids, and enhanced the ability to chilling-tolerant cultivars under low temperature. The effect on chilling-tolerant cultivars was significantly higher than that on chilling sensitive cultivars by applying more phosphorus fertilizer. Phosphate regulated photosynthetic physiology and membrane fluidity to reduce injury by low temperature, and increasd the cold tolerance capacity of rice.

Stability of K-struvite in High Temperature and Acid-base Environment

K-struvite was prepared by precipitation method,and the stability of K-struvite in high temperature and acid-base environment were investigated by X-ray diffraction(XRD),thermogravimetric analysis(TG/DSC),and infrared spectroscopy(FT-IR).The results show that K-struvite decomposes from 50 to 110℃,and the mass loss begins at 50℃before being completely destroyed at 110℃,then further heating at temperature above 500℃leading to complete loss of the binding water in K-struvite.Moreover,K-struvite is more stable in alkaline environments than acidic environment.

Effects of Calcination Temperature of Boron-Containing Magnesium Oxide Raw Materials on Properties of Magnesium Phosphate Cement as a Biomaterial

A new magnesium phosphate bone cement （MPBC） was prepared as a byproduct of boroncontaining magnesium oxide （B-MgO） after extracting Li2CO3 from salt lakes. We analyzed the elementary composition of the B-MgO raw materials and the effects of calcination temperature on the performance of MPBC. The phase composition and microstructure of the B-MgO raw materials and the hydration products （KMgPO4.6H2O） of MPBC were analyzed by X-ray diffraction and scanning electron microscopy. The results showed that ionic impurities and the levels of toxic elements were sufficiently low in B-MgO raw materials to meet the medical requirements for MgO （Chinese Pharmacopeia, 2O10 Edition） and for hydroxyapatite surgical implants （GB23101.1-2O08）. The temperature of B-MgO calcination had a marked influence on the hydration and hardening of MPBC pastes. Increasing calcination temperature prolonged the time required for the MPBC slurry to set, significantly decreased the hydration temperature, and prolonged the time required to reach the highest hydration temperature. However, the compressive strength of hardened MPBC did not increase with higher calcination temperatures. In the 900-1 000 ~C temperature range, the hardened MPBC had a higher compressive strength. Imaging analysis suggested that the setting time and the highest hydration temperature of MPBC pastes were dependent on the size and crystal morphology of the B-MgO materials. The production and microstructure compactness of KMgPOa＇6H2O, the main hydration product, determined the compressive strength.

Synthesis and characterization of CePO_4 nanowires via microemulsion method at room temperature

Uniform CeVO4 nanowires with diameter of about 25 nm were synthesized by the water-in-oil microemulsion method at room temperature from cerous chloride, sodium orthophosphate, sodium chloride, cyclohexane, Triton X-100 and cetyltrimethyl ammonium bromide （CTAB）. The crystal structure and morphology of the nanowires were characterized by XRD and TEM, respectively. The UV-vis absorption was detected by UV-vis spectrophotometer techniques. The results showed that as-prepared nanowires with the hexagonal phase have obvious quantum confinement effect and semiconductor characteristics. Little sodium chloride could play a positive role on the formation of CePO4 nanowires at room temperature. The size of the nanowires can be controlled through the joining of sodium chloride. C 2009 Yi Bin Yin. Published by Elsevier B.V. on behalf of Chinese Chemical Society. All rights reserved.

THE EFFECT OF MELTING TEMPERATURE ON THE PROPERTIES OF PbBr _2-PbCl_2-P_2O_5 GLASSES

A series of PbBr 2 PbCl 2 P 2O 5 glasses have been prepared and characterized to research the effect of melting temperature on the properties of glasses. The glass forming regions have been explored and the stability of the glasses against crystallization studied. The density, characteristic temperatures, chemical analysis compositions, and infrared absorption spectra of the glasses were measured. Results show that the PbBr 2 PbCl 2 P 2O 5 ternary system melted at 530～540℃ has a broader glass forming region which extended to the side of PbBr2 than that melted at 450～470℃. The glass transition temperature is more than 200℃ and the density is more than 5 5 g·cm 3 . Both the chemical analysis composition and the infrared absorption spectra of some glasses melted at 530～540℃ show that the decomposition of NH 4H 2PO 4 is more complete than that of glasses melted at 450～470℃.

Al_(2)O_(3)基材作载体制备MoP加氢脱硫催化剂的研究

采用低温燃烧法和溶剂热法分别合成了富含五配位Al^(3+)物种的氧化铈改性Al_(2)O_(3)(Ce-Al_(2)O_(3))和介孔-大孔Al_(2)O_(3)(M-Al_(2)O_(3));通过程序升温还原浸渍法负载的Mo的磷酸盐前驱体制备了MoP催化剂。以二苯并噻吩(DBT)为模型含硫化合物评价了其加氢脱硫(HDS)性能。结果表明,M-Al_(2)O_(3)上制备纯相MoP所需磷酸盐前驱体的P/Mo摩尔比在1~1.2之间。DBT在MoP催化剂上转化率大小为MoP(1)/SiO_(2)>MoP(1)/Ce-Al_(2)O_(3)>MoP(1.2)/M-Al_(2)O_(3)。动力学研究表明,DBT在MoP(1)/Ce-Al_(2)O_(3)和MoP(1.2)/M-Al_(2)O_(3)上的HDS反应活化能几乎相同,显著小于MoP(1)/SiO_(2)上的活化能。在MoP催化剂上,直接脱硫(DDS)路径选择性随温度的增加而增加。在较低的温度下(如280℃),DBT主要通过加氢(HYD)反应路径脱硫;在较高的温度下(如360℃),DDS和HYD两条反应路径并重。

磷酸盐陶瓷涂层耐高温冲蚀磨损性能研究

[目的]垃圾焚烧炉锅炉管道面临严重的高温冲蚀磨损问题,本文研究了磷酸盐陶瓷涂层的耐高温冲蚀磨损性能,以期实现对垃圾焚烧炉锅炉管道的长寿命保护。[方法]以浓磷酸、氢氧化铝、氧化镁和氧化锌为原料,在12Cr1MoV钢表面制备了磷酸盐陶瓷涂层。在不同冲蚀颗粒质量和冲蚀角下对涂层进行高温冲蚀磨损试验,利用X射线衍射(XRD)和扫描电子显微镜(SEM)研究了磷酸盐陶瓷涂层的微观组织结构和冲蚀磨损形貌,探究了涂层的高温冲蚀磨损机理。[结果]磷酸盐陶瓷涂层的冲蚀质量损失随着单位时间内冲蚀颗粒质量的增加而线性增大,涂层磨损率最大时的冲蚀角是90°,随着冲蚀角减小,冲蚀率逐渐减小,冲蚀区域由圆形变为椭圆形。涂层表面在冲蚀后出现许多凹坑,冲蚀角越大则凹坑越深、越明显。[结论]磷酸盐陶瓷涂层在高温冲蚀磨损试验中符合脆性材料的冲蚀磨损规律,它适用于垃圾焚烧炉锅炉管道防护领域。

高温固相修复再生磷酸铁锂正极材料研究进展

磷酸铁锂电池作为广泛应用的锂离子电池之一,其关键电极材料的高效回收循环利用在资源、环境、经济等方面具有重要的战略意义。高温固相修复技术能够实现磷酸铁锂正极材料短流程、低成本、高效率、绿色环保的循环利用,获得了广泛的关注和研究。针对高温固相修复再生磷酸铁锂正极材料,介绍了此类材料的电化学性能失效机理,从锂补充、缺陷修复和强化锂的迁移等方面对磷酸铁锂正极材料的修复机理进行了分析;阐述了焙烧温度、保温时间、补锂量等修复再生工艺参数对高温固相法修复磷酸铁锂正极材料的影响;分析了表面包覆和离子掺杂对提升磷酸铁锂正极材料电化学性能的影响和机理;并对高温固相修复法修复磷酸铁锂正极材料的可控制备、杂质控制和材料改性等方面的未来前景进行了展望。

磷酸基地聚合物抗硫酸盐侵蚀及耐高温性研究

为制得一种高耐久、低p H值且能够对裂隙和碎岩有效支护的密封/加固材料,以偏高岭土为前驱体原材料,磷酸和磷酸二氢铝(ADP)为激发剂制备了磷酸基地质聚合物。分析了地质聚合物试样的抗硫酸盐侵蚀性能,并检测不同温度煅烧后试样的抗压强度及相应物相和微观形貌的变化,以评价其耐高温性能。结果表明,磷酸基地质聚合物具有较好的抗硫酸盐侵蚀性,在10%硫酸钠溶液中浸泡不同龄期后抗压抗蚀系数均高于1.0。此外,地质聚合物具有良好的耐高温性能,经150℃煅烧1 h后,A100试样的抗压强度较煅烧前增加30.4%,经1 050℃煅烧1 h后不同组别试样的抗压强度仍保持在15 MPa以上。

磷化时间对常温锌系磷化膜防腐蚀性能的影响

针对碳钢材料采用某常温锌系磷化工艺进行磷化加工的优化问题,文章分析了磷化时间对磷化膜形貌(表面形貌和横截面形貌),磷化膜化学状态(元素含量和分布,结晶情况和亲水性),耐腐蚀特性(盐水浸泡实验和Tafel曲线实验)的影响。发现15~20 min该工艺磷化膜生长速度较快,而20~30 min磷化膜生长速度显著下降。该研究为碳钢材料在该工艺中磷化时间的选择提供了参考。

磷酸铁锂电池热失控传播特性的影响因素研究

以试验方式探究影响磷酸铁锂电池热失控传播的主要因素,设计了不同荷电状态、电池间距以及电气连接方式的电池模组开展热失控传播试验,根据温度、电压以及质量等参数,分析了不同因素对热失控传播的影响程度。结果表明,3种因素对热失控传播的影响程度依次为:荷电状态、电池间距、电气连接方式。同时得到导致热失控传播的主要传热路径是向下游电池传热。

促进剂对锌镍系磷化膜表面形貌及耐蚀性的影响

通过对钢铁件进行磷化处理,可以有效改善钢铁件表面的物理化学性能,为了获得耐蚀性能优异的磷化膜,需要选择合适的促进剂。在一定的条件下,通过向磷化液中加入硝基胍、亚硝酸钠、钼酸钠3种物质作为磷化促进剂,在30CrMnSi钢表面制备磷化膜。采用扫描电子显微镜、腐蚀电化学测试,硫酸铜点滴试验,中性盐雾实验,接触角试验等手段对磷化膜的性能进行了表征,对比了促进剂添加前后的效果以及促进剂种类对中温锌镍系的膜层耐蚀性能的影响。结果表明:在磷化液中添加促进剂时,磷化膜的微观结构变得更加致密,硫酸铜点滴时间都有所延长,自腐蚀电位更正,自腐蚀电流密度较小,在盐雾环境中都有一定的耐腐蚀性,都能起到增强磷化膜的耐腐蚀性能。通过比较得出当硝基胍为促进剂时,磷化膜的耐腐蚀性能最佳。

γ-TiAl基合金用Al_(2)O_(3)-SiC-AlPO_(4)复合涂层抗高温氧化性能研究

目的通过表面涂层提高γ-TiAl基合金的抗高温氧化性能。方法采用常规喷涂涂料法在γ-TiAl合金基体上制备Al_(2)O_(3)-SiC-AlPO_(4)磷酸盐复合抗高温氧化涂层。研究γ-TiAl合金和涂层样品在900℃、静态空气条件下的准等温氧化动力学行为。用XRD和SEM/EDS分别对涂层样品氧化前后的物相组成、组织形貌和微区成分进行表征分析;用电子探针(EPMA)分析涂层样品的元素分布情况。结果900℃恒温氧化动力学研究结果表明,γ-TiAl基合金初期氧化速率常数为32.501×10^(-2)mg/(cm^(2)·h^(1/2)),与后期氧化速率常数28.113×10^(-2)mg/(cm^(2)·h^(1/2))基本接近,呈直线规律,不具有抗氧化性能;而Al_(2)O_(3)-SiC-AlPO_(4)磷酸盐复合涂层样品氧化后期氧化速率常数为5.967×10^(-2) mg/(cm^(2)·h^(1/2)),与氧化初期8 h内氧化速率常数23.941×10^(-2) mg/(cm^(2)·h^(1/2))相比,明显降低,遵循典型抛物线规律,具有抗氧化性能。微观分析结果表明,原始涂层与γ-TiAl合金基体结合紧密,涂层主要相组成为Al_(2)O_(3)、SiC、SiO_(2);AlPO_(4)以无定形状态构成涂层连续相。氧化后,AlPO_(4)演变成晶态,形成涂层致密的网络结构;部分基体钛元素扩散进入涂层中疏松部位,氧化后形成TiO_(2)弥散分布在涂层中,填补了涂层疏松部位,使涂层更加致密;在涂层与基体界面2μm区域内形成连续致密Al_(2)O_(3)膜,阻挡了空气中的氧进一步扩散进入基体。结论Al_(2)O_(3)-SiC-AlPO_(4)复合涂层有效降低了γ-TiAl基合金氧化速率,有助于形成保护性Al_(2)O_(3)膜,明显改善了900℃γ-TiAl基合金抗高温氧化性能。

GdPO_(4)∶Tb^(3+)荧光粉的制备及发光性能研究

稀土Tb^(3+)掺杂磷酸钆(GdPO_(4))绿色荧光粉是实现白光LED的潜在荧光粉,其常规水热法的制备存在反应时间较长、Tb^(3+)的掺杂量偏低等问题。本文采用水热法结合高温烧结制备了一系列Gd_(1-x)PO_(4)∶xTb^(3+)(x=0、1%、5%、11%、13%、15%、17%、19%)样品,通过X射线衍射仪(XRD)、扫描电子显微镜(SEM)-能谱仪(EDS)、红外光谱仪(FT-IR)和荧光分光光度计对所得样品的相结构、形貌、元素组成、光学吸收和发光性能进行了表征。研究结果表明,所合成样品均为GdPO_(4)的纯相,属于单斜晶系独居石结构,且Tb^(3+)均匀分布在GdPO_(4)基质中引起晶格收缩。在274 nm的光激发下,GdPO_(4)∶Tb^(3+)荧光粉的最强发射峰位于545 nm处,属于Tb^(3+)的^(5)D_(4)→^(7)F_(5)跃迁,且其荧光猝灭摩尔分数高达15%,此样品(GdPO_(4)∶15%Tb^(3+))表现出优异的绿光发射和良好的热稳定性。

MoS_(2)/Ti_(3)C_(2)T_(x)对磷酸盐涂层宽温域摩擦学性能的影响

目的以MoS_(2)/Ti_(3)C_(2)T_(x)为固体润滑剂,在25(室温)~400℃下制备具有优异摩擦学性能的MoS_(2)/Ti_(3)C_(2)T_(x)磷酸盐涂层,并研究它在不同温度下的减摩抗磨机制。方法以氢氟酸为MAX相(Ti_(3)AlC_(2))粉体的蚀刻剂,制备具有“手风琴”形貌的Ti3C2TxMXene。以硫脲、钼酸铵、MXene为原料,制备MoS_(2)/Ti_(3)C_(2)T_(x)复合材料。以Al(H2PO4)3为黏结剂,以Cu O为固化剂,分别以Ti_(3)C_(2)T_(x)和MoS_(2)/Ti_(3)C_(2)T_(x)为固体润滑剂,制备Ti3C2Tx磷酸盐涂层和MoS_(2)/Ti_(3)C_(2)T_(x)磷酸盐涂层。通过高温摩擦磨损试验机和光学数码显微镜测试涂层在25~400℃时的摩擦因数和磨损率,采用扫描电子显微镜和显微共焦激光拉曼光谱仪分析磨痕表面形貌、物相,进而探讨磨损机理。结果当Ti_(3)C_(2)T_(x)与Al(H_(2)PO_(4))_(3)的质量比为2∶1时,Ti3C2Tx磷酸盐涂层在室温(25℃)下的摩擦因数和磨损率均最低,分别为0.38和2.75×10-4mm3/(N·m)。在Ti_(3)C_(2)T_(x)表面负载MoS2,将MoS_(2)/Ti_(3)C_(2)T_(x)作为固体润滑剂,能够显著降低磷酸盐涂层在25~400℃下的摩擦因数,同时磨损率也有所降低。MoS_(2)/Ti_(3)C_(2)T_(x)磷酸盐涂层在室温下的摩擦因数低至0.11,相较于Ti3C2Tx磷酸盐涂层降低了71.1%,其磨损率相较于Ti3C2Tx磷酸盐涂层降低了1个数量级。在25~400℃范围内,MoS_(2)/Ti_(3)C_(2)T_(x)磷酸盐涂层的摩擦因数均低于0.21。随着温度的升高,摩擦因数呈先减小后增大的趋势,磨损率整体上呈增大趋势。结论相较于Ti_(3)C_(2)T_(x)磷酸盐涂层,MoS_(2)/Ti_(3)C_(2)T_(x)磷酸盐涂层在25~400℃下的摩擦学性能均得到显著提升。

磷渣酸高温活化低品位磷矿制备聚合态磷肥

以低品位磷矿和磷渣酸为主要原料,采用高温煅烧方法对其进行活化,制备了一种聚合态磷肥,通过单因素试验对反应条件进行了探索,得到的适宜反应条件为:聚合反应温度600℃、聚合反应时间40 min、原料配比m(酸P_(2)O_(5))/m(矿P_(2)O_(5))为2.5。在此条件下制备得到的聚合态磷肥为疏松多孔的块状结构,其中聚合磷质量分数为35.70%、聚合率为86.47%,有效磷质量分数为36.40%、占总磷的88%,钙、镁的有效占比分别为60.3%和75.6%,溶解试验结果显示该聚合态磷肥主要以枸溶性为主。

利用ICP-OES测定磷酸铁锂中复杂金属杂质的方法实践

随着锂离子电池产业的蓬勃发展,废旧锂离子电池及锂离子电池生产过程中的报废体量剧增,锂离子电池相关的回收产业发展迅猛,其中磷酸铁锂电池的市场最大。无论哪种回收路径,回料中的金属杂质成分都比较复杂,而金属杂质的准确测定,对锂离子电池回收产业至关重要。文中通过高温热解法对样品进行前处理,建立了一种用ICP-OES测量复杂基体中多种金属元素的分析方法。将高温热解得到的磷酸铁锂回料进行高温下的酸消解,然后在ICP-OES中对不同的观测位进行比较。将得到的数据进行测量系统分析,通过计算精度/容差(%P/T)评估最佳的检验能力组合。经过对比,发现270℃的高温消解更利于金属异物的充分溶出,Al(径向)、Na(径向)、Ni(径向)、Mn(径向)、Cr(轴向)、Zn(径向)的ICP-OES观测方位组合能更准确、稳定地分析复杂基体的金属杂质元素组分。该分析方法简单、高效、计算量小,便于快速评估检验能力。在利用ICP-OES进行复杂基体的金属异物分析方面,此方法具有很好的借鉴意义。

磷酸铁锂锂离子电池电芯注液量相关试验验证与探讨

通过详细的理论计算,推导出LFP/230 Ah锂离子电池电芯孔隙率和极限饱和吸液量,并且通过试验设计进行验证。通过调整LFP/230 Ah锂离子电池电芯的一次注液量与不同高温下的静置时间来验证随后高温负压化成后电芯各项电性能参数受到的影响。测试及验证结果表明:随着一次注液后高温静置时间的延长,LFP/230 Ah锂离子电池电芯中游离态电解液量逐渐减少,而且在24 h后基本达到稳定状态;一次注液后随着高温静置时间的延长,电芯在化成过程中的温度逐渐降低,而且化成结束后的开路电压越来越高,分容容量有升高趋势,DCR有降低趋势,电芯满充后黑斑析锂位置点的数量减少,而且黑斑面积也逐渐缩小,但在SoC为0.6%下的K值筛选没有受到显著影响。

Al_(2)O_(3)-MWCNTs增强无机磷酸铝陶瓷涂层摩擦学性能的研究

为提高无机磷酸铝涂层的高温耐磨性,降低高温下的摩擦系数,制备了氧化铝包覆多壁碳纳米管(MWCNTs)杂化型填料,将其加入到无机磷酸铝涂料中,采用X射线衍射分析仪(XRD)、傅立叶变换红外光谱仪(FT-IR)、拉曼光谱仪(Raman)、热重分析仪(TG)和扫描电子显微镜(SEM)等表征了填料结构,并研究了填料含量对复合涂层的力学性能和耐磨性能的影响规律。结果表明:纳米α-Al_(2)O_(3)成功接枝于多壁碳纳米管(MWCNTs)表面。经表面改性后的MWCNTs的氧化分解温度提升近100℃,杂化材料在涂层中的分散程度更佳。随着Al_(2)O_(3)-MWCNTs用量的增加,涂层硬度、附着力呈现先增加后降低的趋势,当Al_(2)O_(3)-MWCNTs用量为0.4%时,涂层力学性能最优,硬度提升至近2倍,附着力提升至近2.6倍。600℃高温摩擦磨损耦合试验结果表明,添加0.4%的Al_(2)O_(3)-MWCNTs涂层的摩擦系数最低为0.659,磨损率最小为2.73×10^(-4 )mm^(3)/(N·m),说明添加Al_(2)O_(3)-MWCNTs杂化填料确可有助于提高无机磷酸盐涂层的摩擦学性能。