Decolorization of Disperse Dyes Using Immobilized Laccase Enzyme on Nano Zinc Ferrite from Single and Binary Systems

In this paper, immobilized laccase enzyme on nano zinc ferrite was used in order to decolorize disperse dyes from single and binary systems. In this case, disperse dyes such as Disperse red 60 (DR60), Disperse blue 56 (DB56) and Disperse yellow 54 (DY54) were selected as model dyes. Several parameters such as enzyme concentration, pH and dye concentration and their effect on decolorization of dyes from single and binary systems were studied. According to the experimental results, the optimized immobilized laccase enzyme concentration, reaction time and pH for decolorization of DR60, DB56 and DY54 from single and binary systems were 500 mg/L (for DR60 and DY54) and 400 mg/L (for DB56), 20 min and 3, respectively. Moreover, Dye decolorization kinetics followed Michaelis-Menten Model. Finally, the results showed that enzymatic process using immobilized laccase enzyme on nano zinc ferrite was effective method to decolorize disperse dyes from single and binary systems.

抗菌PP/Rnano-ZnO复合材料的制备及性能研究

以棒状纳米氧化锌(Rnano-ZnO)为抗菌剂、聚丙烯(PP)为基材,采用熔融共混法在双螺杆挤出机中制备了抗菌PP/Rnano-ZnO复合材料。测试了复合材料的抗菌性能,通过DSC法研究了抗菌PP/Rnano-ZnO复合材料中Rnano-ZnO质量分数对结晶性能的影响,采用SEM分析了复合材料冲击断面的微观形貌,采用万能电子拉伸机测试了复合材料的力学性能。结果表明,抗菌PP/Rnano-ZnO复合材料中随着Rnano-ZnO的加入,结晶温度提高了1.81℃,相对结晶度提高了5.03%,冲击强度提高了47.83%,拉伸强度提高了20.96%和断裂伸长率提高了4790%;当抗菌PP/Rnano-ZnO复合材料中Rnano-ZnO质量分数为6.0%时,其力学性能、对大肠杆菌和金黄色葡萄球菌的抗菌效果最佳。

Incorporation of Nano-Zinc Oxide in Lamellar Zirconium Phosphate: Synthesis and Characterization

In order to provide ultraviolet barrier, antifungal and antibacterial properties, nano-zinc oxide (ZnO) was added to lamellar zirconium phosphate (ZrP). The phosphate was synthesized via reaction of zirconium oxychloride octahydrate and phosphoric acid following its chemical modification with Jeffamine and nano-ZnO. Diffractometric, morphological, thermal, structural and relaxometric evaluations were conducted. Fourier transform infrared spectroscopy (FTIR) revealed increase of the area between 4000 - 3000 cm-1 due to the formation of ionic specie PO? +NH3-[C-(H)(CH3)-CH2-O-(C-(H)(CH3)-CH2-O)8-(CH2-CH2-O-CH3)] and nano-ZnO particles. Wide-angle X-ray diffraction indicated that intercalation of Jeffamine was successful. Thermogravimetry confirmed that nano-ZnO particle forced the expulsion of Jeffamine outside ZrP galleries. Scanning electron microscopy evidenced the Jeffamine intercalation and sample heterogeneity. Hydrogen molecular relaxation indicated the increase of molecular rigidity owing to the formation of ionic specie and the addition of nano-ZnO particles. It was postulated that a multifunctional and miscellaneous material constituted by as prepared ZrP, some delaminated ZrP platelets and nano-ZnO particles was achieved. The material has potential for usage as filler in polymeric composites.

Nano zinc, an alternative to conventional zinc as animal feed supplement:A review

The uniqueness of Zn is that, it is the second most abundant trace element in the animal body but can't be stored in the body, thus regular dietary intake is required. Zinc oxide(ZnO) nanoparticles(NP) particles are being extensively used in paints, skin lotions pigments, food, electronics appliances, biological and pharmaceutical applications and many more. Zinc oxide nanoparticles are the specially prepared mineral salt having particle size of 1 to 100 nm. It promotes growth can act as antibacterial agent,modulates the immunity and reproduction of the animals. Both in lower and higher doses of specifications it has exhibited a variety of effects on animal performances. Apart from being highly bioavailable, reports have already pointed out the growth promoting, antibacterial, immuno-modulatory and many more effects of nano zinc(nZn). These can be used at lower doses and can provide better result than the conventional Zn sources and indirectly prevents environmental contamination also. The toxicological studies provide mixed results in animal models. Studies been undertaken in diversified animal species and encouraging effects have been reported with nZn supplementation. However, there is a need to optimize the dose and duration of ZnO NP supplementation for human and livestock,depending on its biological effects. Actual bioavailability of ZnO NP in livestock is still to be worked out.In this review we have attempted to summarize, conclude the beneficial effects of nZnO and its possible usage as mineral supplement to different categories of human and livestock.

Biomineralization of Zinc-Phosphate-Based Nano Needles by Living Microalgae

Up to now, chemical synthesis routes only provide restricted opportunities for the formation of structured nano particles. In contrast, living microorganisms generate nano materials of well defined shapes by the precise control of biomineralization. Here we reveal new principles for the generation of functional nano materials through the process of biomineralization. We used the detoxification mechanism of the unicellular alga Scenedesmus obliquus to generate a techno logically interesting zinc-phosphate-based nano material. The algae were incubated in media with a sublethal zinc concentration (6.53 mg Zn dm-3) for 4 weeks. Using BF-and ADF-STEM imaging combined with analytical XEDS we could show that nano needles containing phosphorus and zinc were formed inside the living cells. Further more, the cells incubated with zinc show a strong fluorescence. Our findings indicate that the algae used polyphosphate bodies for detoxification of the zinc ions, leading to the generation of intracellular zinc-phosphate-based nano needles. Beside the technological application of this material, the fluorescent cells can be used for labeling of e.g. biological probes. This new experimental protocol for the production of an inorganic functional material can be applied also for other substances.

推荐一个无机合成综合实验——基于废弃大豆油的微乳液法制备纳米氧化锌

纳米氧化锌是一类多功能纳米材料,由于其优秀的物理化学性质而被广泛应用于多个领域。传统的合成方法存在成本过高、过程复杂、产物不稳定等问题。微乳合成法具有操作简单,成本低廉,产物尺寸可控等优点,可以有效避免传统合成方法的缺陷。特别是将废弃大豆油合成的乳化剂应用在合成的过程中,可以实现废物的回收再利用,又能满足绿色化学和可持续发展的要求。使用X射线衍射(XRD)、扫描电镜(SEM)、化学分析等多种方法对产物纳米氧化锌的形貌和性质进行了表征,实现了无机合成-化学分析-仪器分析的综合偶联,从而达到提升大学生进行综合实验能力的目的。

Electrochemical and Photoelectrochemical Properties of Nano-Islands of Zinc and Niobium Oxides Deposited on Aluminum Thin Film by RF Magnetron Reactive Sputtering

Zinc oxide (ZnO) and niobium oxide (NbOx) with a nano-island structure were deposited by a sputtering method on Al-coated glass substrates. Cells with a (ZnO or NbOx)/Al/glass|KNO3aq.|Al/ glass structure were assembled, and electrochemical and photoelectrochemical properties were evaluated. The ZnO and NbOx electrodes had higher electrode potentials than the counter Al/glass electrode, and electron flows from the counter electrode to the ZnO and NbOx electrodes through the external circuit were commonly confirmed. In the ZnO-based cell, only faint photocurrent generation was seen, where Zn and Al elution from the ZnO electrode was found. In the NbOxbased cell, however, stable generation of electricity was successfully achieved, and electrode corrosion was not recognized even in microscopic observations. A photoelectrochemical conversion model was proposed based on potential-pH diagrams. In the case of nano-island structures formed at shorter NbOx deposition time, it was concluded that the photoelectrochemical reactions, which were proceeded in the immediate vicinity of the boundary among nano-islands, substrate, and electrolyte solution, were predominant for the photoelectrochemical conversion, and in the case of film structures with longer deposition time, the predominant reactions took place at the film surface.

一种车用纳米改性橡胶密封材料制备及性能研究

为提高橡胶密封材料的耐磨性能,以丁腈橡胶(NBR)为主要材料,纳米氧化锌为补强填料,制备一种密封材料,对其力学性能和摩擦磨损性能进行研究。结果表明,与普通氧化锌相比,含有纳米氧化锌的密封材料力学性能和耐磨性能更好,硬度为77.2 HA,压缩永久变形率为21.2%,拉伸强度和拉伸断裂伸长率分别是13.26 MPa、198.8%,撕裂强度为52.38 kN/m。在干摩擦磨损试验中,含有纳米氧化锌的密封材料平均摩擦系数为0.817,磨损量降低38.0%。在油润滑摩擦磨损试验中,含有纳米氧化锌的密封材料摩擦系数最后稳定在0.08。添加纳米氧化锌的密封材料综合性能良好,可作为汽车轴承等钢结构密封材料应用。

IN-SITU POLYMERIZED SYNTHESIS AND PROPERTIES OF NANO-ZnO/PEG/PET COMPOSITE

Nano-ZnO particle （nZnOp） reinforced polyethylene glycol （PEG）/polyethylene terephthalate （PET） （nZnOp/PEG/PET） copolymeric composites with different mass fractions and molecular weights of PEG are synthesized via in-situ polymerization. The dispersion of nZnOp in copolymer matrixes and the effects of PEG and nZnOp particles on the crystallization behavior of the composites are studied by TEM, differential scanning calorimetry（DSC）, XRD and Fourier thansform infrared spectroscopy （FTIR ）. The results reveal that nZnOp particles are dispersed in the matrixes with nano-scale, and the addition of PEG induces more homogeneous dispersion of nZnOp. Simultaneously, these nanoparticles become nucleating centers during the crystallization of the matrixes. PEG segments can improve the flexibility of the PET molecular chain, resulting in the drop of the cold crystallization temperature and the rise of the crystallization rate of the composites. Furthermore, PEG （4 000） with the mass fraction of 10% can promote the crystallization rate of the composites. The mechanical properties show that the nano-particles strengthen and toughen the PET matrix, whereas PEG weakens these improve- ments.

喷施纳米铁和纳米锌叶面肥对冬枣叶片及果实品质的影响

以七年生冬枣为试材,在果实发育期喷施不同浓度T1(2.5 mL·L^(-1))、T2(5.0 mL·L^(-1))、T3(10.0 mL·L^(-1))、T4(15.0 mL·L^(-1))的纳米铁和纳米锌混合液进行叶面施肥,以喷施清水作为对照,研究了纳米铁和纳米锌混合液对冬枣叶片及果实品质的影响,以期筛选出促进冬枣品质提升适宜的纳米铁和纳米锌混合液施用浓度。结果表明:叶面喷施10.0 mL·L^(-1)的纳米铁锌叶面肥显著改善了冬枣的果实品质,提高了单果质量、果实硬度、可溶性固形物含量、维生素C含量以及固酸比,降低了可滴定酸含量;提高了冬枣叶片的光合色素含量和光合作用;喷施浓度为15.0 mL·L^(-1)的纳米铁锌叶面肥对冬枣叶片及果实中的铁锌元素含量效果最佳。因此,叶面喷施纳米铁锌叶面肥能促进冬枣叶片铁和锌元素的积累,提高光合色素含量,促进光合作用,改善果实品质。

锌灰资源化回收及超临界水热合成纳米氧化锌系统工艺

为了对锌灰进行资源化回收及对其经济性进行分析,将湿法回收工艺和超临界水热合成技术相结合,将锌灰生成价值较高的纳米氧化锌产品,采用Aspen Plus软件平台,建立了完整的系统工艺,并分析了系统运行过程中的物料成本及能耗成本。在硫酸浓度为2 mol·L^(-1)、固液比为1∶8、浸出温度为50℃、浸出时间为2 h、搅拌器转速为300 r·min^(-1)的条件下,锌灰中锌的浸出率达到了95%以上。除杂过程除去了Fe、Al、Ni、Cu等杂质,除杂后的溶液中锌的质量分数达到了97%。利用锌灰浸出液在400℃和25 MPa的超临界条件下,合成了平均粒径为26 nm的纳米氧化锌,晶体结晶度良好,纯度较高。通过与纯物料所合成的纳米氧化锌进行对比,验证了该技术的可行性,显著提升了系统运行的经济性。

焦磷酸哌嗪/纳米阻燃剂协效阻燃PBS

以焦磷酸哌嗪(PAPP)为阻燃剂,选用氧化石墨烯(GO)、纳米蒙脱土(DK2)、硼酸锌(ZnB)作为协效剂与PAPP分别构成二元阻燃体系和三元阻燃体系。二元阻燃体系包括PAPP与DK2、PAPP与ZnB、PAPP与GO;三元阻燃体系包括PAPP、GO和ZnB及PAPP、DK2和ZnB。分别将上述二元阻燃体系及三元阻燃体系与聚丁二酸丁二醇酯(PBS)熔融共混制备PBS阻燃复合材料,研究不同复配体系阻燃剂的加入对PBS阻燃性能和力学性能的影响。结果表明,当PAPP含量为16.5%、DK2含量为1.5%、ZnB含量为2%时,PBS复合材料通过了UL94垂直燃烧测试,达到了V-0级,极限氧指数(LOI)达到32.4%,最大热释放速率峰值(PHRR)和总烟释放率(TSP)分别为227kW/m^(2)和3.4m^(2),与加入20%PAPP(FRPBS)相比,分别降低了50%和69%,残炭率达到13.8%,此外,拉伸强度为13.5 MPa,断裂伸长率为613.8%,冲击强度为8.0kJ/m^(2),与FRPBS相比,分别提升了9.1%、17.2%和40.3%。结果表明,三元阻燃体系能够同时提升PBS复合材料的阻燃性能力学性能。

载纳米氧化锌定向纤维膜促进肌腱细胞增殖分化的研究

目的为模拟肌腱组织的显微结构和力学性能,促进肌腱组织的再生修复,制备负载不同质量分数纳米氧化锌且同时具备取向结构的左旋聚乳酸(PLLA)纤维膜,对其进行理化表征和生物性能评价,探讨其对肌腱细胞增殖分化的影响。方法利用静电纺丝技术制备PLLA纤维支架及含不同质量分数纳米ZnO的PLLA/ZnO纤维支架。通过扫描电镜、力学拉伸、能谱仪(EDS)图谱表征支架的理化性能,并将支架与小鼠肌腱细胞共培养检测其生物相容性及对细胞增殖、分化的调控作用。结果纤维支架均呈取向性排列,锌元素在纤维中均匀分布,PLLA/0.1%ZnO纤维支架拉伸强度和杨氏模量均显著高于PLLA组。PLLA/0.1%ZnO纤维支架表面细胞数量显著高于PLLA组,且活性更好;小鼠肌腱细胞沿纤维排列方向呈定向性黏附和生长。结论取向PLLA/0.1%ZnO纤维支架具有优良的理化性能,并可显著促进肌腱细胞定向生长和增殖分化,未来有望用于肌腱组织的再生修复。

纳米氧化锌和SDS促进二氧化碳水合物生成特性实验研究

水合物法捕集和封存二氧化碳(CO_(2))具有储气量高和成本低等优点,但生成CO_(2)水合物(简称“水合物”)的诱导时间长、生成速率缓慢限制了该方法的应用。为促进水合物的生成,采用恒容法研究了纳米氧化锌(ZnO)和十二烷基硫酸钠(SDS)对水合物生成的影响。结果表明,在一定条件下增大初始压力和引入机械搅拌可以促进水合物生成,并且单独添加纳米ZnO或SDS均能显著缩短诱导时间。其中,在ZnO质量分数为0.06%和275.65 K的条件下,确定了初始压力和搅拌速率的最优值分别为4.5 MPa和500 r/min。在3.5 MPa、275.65 K和300 r/min的条件下,加入质量分数为0.10%、粒径为50 nm的纳米ZnO(ZnO-50)体系的诱导时间为41.6 min,较纯水体系的诱导时间(487.4 min)缩短了91.5%。体系中ZnO-50的质量分数为0.06%时,气体消耗总量为0.903 mol,较纯水体系的气体消耗总量(0.444 mol)提高了103.4%。提高SDS的质量分数对气体消耗总量的促进效果逐渐增强,当体系中SDS的质量分数为0.10%时,气体消耗总量达到最大(1.027 mol),比纯水体系的气体消耗总量提高了131.3%。以质量分数为0.10%的SDS与质量分数为0.02%的ZnO-50构建协同体系,其气体消耗总量(1.045 mol)受相平衡压力的影响变化不大,但可以显著加快水合物生成速率,实验半程(反应5 h)的气体消耗量可达0.924 mol,占实验全程(反应10 h)气体消耗总量的88.4%,明显高于单独使用质量分数为0.02%的ZnO-50和质量分数为0.10%的SDS体系的相应数据(分别为63.7%和48.5%)。相关研究结果可为应用水合物技术进行CO_(2)捕集和封存提供一定的理论指导。

包被纳米氧化锌对断奶仔猪生长性能、免疫功能和肠道屏障的影响

研究旨在比较不同形式纳米氧化锌对断奶仔猪生长性能、免疫功能和肠道屏障的影响。选取192头24日龄左右、体重(7.47±0.62)kg的断奶仔猪(公、母各半),随机分为4组,每组6个重复,每个重复8头仔猪。对照组饲喂基础饲粮,试验Ⅰ组、试验Ⅱ组、试验Ⅲ组分别在基础饲粮中添加2000 mg/kg纳米氧化锌、500 mg/kg包被纳米氧化锌、1000 mg/kg包被纳米氧化锌。试验期14 d。结果显示,纳米氧化锌的总有效率为7.12%,远低于包被纳米氧化锌的78.54%;不同形式纳米氧化锌均可以显著提高断奶仔猪的试验末重和平均日增重(P<0.05),显著降低料重比和腹泻率(P<0.05),试验Ⅲ组效果最佳;与对照组相比,各试验组断奶仔猪血清中免疫球蛋白M和免疫球蛋白A含量显著提高(P<0.05),试验Ⅰ组和试验Ⅲ组断奶仔猪空肠和回肠的分泌型免疫球蛋白水平显著提高(P<0.05);不同形式纳米氧化锌均显著降低了断奶仔猪血清中二胺氧化酶活性和内毒素含量(P<0.05)。研究表明,在饲粮中添加纳米氧化锌和包被纳米氧化锌均可促进断奶仔猪生长,降低腹泻率,增强免疫功能和肠道屏障功能,1000 mg/kg包被纳米氧化锌的作用效果较好。

纳米氧化锌-聚六亚甲基双胍复合水凝胶的制备与质量评价

为了制备一种以纳米氧化锌、聚六亚甲基双胍为主药的复合水凝胶,试验采用体外抑菌试验确定两药的最低抑菌浓度(MIC)及分级抑菌浓度指数(FIC),探究纳米氧化锌、聚六亚甲基双胍抗金黄色葡萄球菌的最佳比例,并进行单因素试验,筛选纳米氧化锌-聚六亚甲基双胍复合水凝胶的基质、基质用量、甘油添加量及聚六亚甲基双胍质量浓度,以单因素试验为基础进行正交试验设计,根据优化后配方制备纳米氧化锌-聚六亚甲基双胍复合水凝胶,从外观、稳定性、黏度和抗菌性能等方面对纳米氧化锌-聚六亚甲基双胍复合水凝胶进行质量评价。结果表明:纳米氧化锌、聚六亚甲基双胍对金黄色葡萄球菌的MIC分别为64,0.5μg/mL。纳米氧化锌-聚六亚甲基双胍复合水凝胶的最优处方为壳聚糖季铵盐6.50%、甘油8.00%、聚六亚甲基双胍2.00μg/mL、纳米氧化锌8.00μg/mL。纳米氧化锌-聚六亚甲基双胍复合水凝胶外观为淡黄色透明状,pH值为5.18±0.50,黏度为65.0 Pa·s,离心稳定性和高低温稳定性均良好;纳米氧化锌-聚六亚甲基双胍复合水凝胶对金黄色葡萄球菌的抑制效果明显,抑制率为98.32%。说明制得的纳米氧化锌-聚六亚甲基双胍复合水凝胶质量稳定,体外抑菌效果良好。

三维铈掺杂氧化锌的制备及其降解罗丹明B的性质研究

介绍了一种性能优异的半导体材料——三维氧化锌,在掺杂了Ce后对大分子污染物光催化降解处理方面表现出良好的性能,以硝酸锌和氢氧化钠为原料,同时加入Ce制备了花状的分级微纳米氧化锌,并对制备的氧化锌材料的微观形貌进行表征和X射线衍射分析,探究该复合氧化锌材料作为光催化剂的催化能力。通过实验数据表明,氧化锌在掺杂了质量分数为1.2%的Ce后参与光催化降解罗丹明B,经过120 min,罗丹明B的降解率达到最大值(98.5%),大于市面上商用氧化锌光催经降解罗丹明B(89.1%)的降解率,高于未掺杂Ce纳米氧化锌光催化降解罗丹明B(81.8%)的降解率,Ce掺杂的纳米氧化锌的催化降解罗丹明B的效果得到显著提高。Ce掺杂的氧化锌与未掺杂的相比,罗丹明B的降解率提高了20%左右,并且在光催化活性循环5次后罗丹明B的降解率依然没有明显衰减,说明添加元素Ce的氧化锌仍具有较高的稳定性,可以重复高效使用。

不同种类锌肥在农业生产上的应用效果评价

锌是作物不可或缺的微量营养元素之一,严重缺锌会影响作物的生长,进而导致人体锌营养摄入不足,危害人体健康。施用锌肥是改善土壤缺锌和补充作物锌营养的有效方式,对作物产量和品质的提升也有显著效果。概述了单质锌肥(无机锌肥、螯合锌肥、络合锌肥、纳米锌肥)和含锌复合肥等在农业生产中的应用效果,对影响锌肥大规模应用的原因进行了探讨。指出了锌肥在实际应用中存在的养分退化、利用率低、作用机制不明确等问题,并对锌肥未来的发展进行了展望。

降雨条件下叶面喷施纳米氧化锌改善作物锌营养的效果及机制

【目的】降雨条件下叶面喷施传统锌肥面临高损失率和有效性大幅降低的问题。基于纳米材料所具备的小尺寸、表面与界面效应以及强吸附效应等特性,探讨降雨条件下叶面喷施纳米锌肥的肥效及改善作物锌营养的机制,具有重要生产应用价值。【方法】试验设置5个处理:全营养液处理(CT_(1))、喷施0.1%吐温对照处理(CT_(2))、喷施ZnSO_(4)·7H_(2)O (CT_(3))、喷施EDTA-Zn (CT_(4))、喷施Nano-Zn (CT_(5))。采用室内水培试验方法,在模拟降雨条件下,比较叶面喷施纳米锌肥(ZnO-NPs)与传统锌肥(离子态锌肥ZnSO_(4)·7H_(2)O和螯合态锌肥EDTA-Zn)对花生的锌营养效果。测定3种锌肥处理对花生植株生长、生物量、净光合速率、抗氧化酶活性以及叶片中锌含量与分布的影响,探讨造成这些影响差异的生理机制。【结果】非降雨条件下,叶片喷施传统锌肥对花生生长的促进效果优于纳米锌肥,但在降雨条件下花生叶面喷施纳米态锌肥可以有效促进花生生长,花生株高较空白组CT_(2)和传统锌肥CT_(3)、CT_(4)分别显著提升16.80%、9.68%和12.85%;其地上部生物量和叶片锌含量分别达到2.48 g/株和0.078 mg/株,与对照组相比分别提高75.05%和466%,与离子态锌肥相比分别提高20.97%和19.54%,与螯合态锌肥相比分别提高24.37%和9.22%;此外,与非降雨条件下相比,降雨条件下喷施纳米锌肥的花生叶片锌含量提高77.36%,抗氧化酶活性有所上升,丙二醛含量有所下降。相反,离子态锌肥ZnSO_(4)·7H_(2)O和螯合态锌肥EDTA-Zn在降雨条件下花生地上部生物量较非降雨条件下分别降低了8.17%和23.70%,叶片锌含量分别降低了25.53%和34.28%,光合作用效率下降幅度大于纳米锌肥。利用同步辐射X射线荧光显微镜(XFM)分析表明,降雨条件下纳米态锌肥处理叶片中的信号强度显著高于其他锌肥处理。就抗淋洗能力而言,纳米锌肥的淋洗量仅为0.01 mg/株,是传统锌肥的45%~50%,而附着在叶片上的锌量为0.02 mg/株,是传统锌肥的4~5倍。这取决于肥料与叶片间的接触面积与表面张力的大小。纳米态锌肥接触角小于传统锌肥,表面张力大于传统锌肥,其粘附功(27.95 mN/m)较传统锌肥(CT_(3)和CT_(4)分别为20.33 mN/m和21.67 mN/m)分别显著增加37.48%和28.98%。【结论】在雨季及其他极端天气条件下,叶面喷施纳米锌肥可有效增强肥料与叶片之间的附着力,从而减少淋洗损失,促进花生叶片对锌的吸收,显著提高花生植株锌营养水平。

纳米氧化锌对钙钛矿薄膜本征性能和光谱性能的影响研究

有机-无机杂化钙钛矿太阳能电池因其优异的光电特性、低廉的制备成本、高效的转换效率等优越特性,成为光伏领域的研究热点。电子传输层作为钙钛矿电池的核心层,主要起到提取和传输光生载流子的作用,且能够作为空穴阻挡层,抑制钙钛矿活性层中电荷复合,所以优异性能的电子传输层对钙钛矿太阳能电池的发展至关重要。可目前钙钛矿光伏器件常用的刚性电子传输层(介孔层或致密层)均需要高温烧结,这限制了其在柔性钙钛矿器件方面的应用。因此,开发一种可应用于钙钛矿光伏领域的柔性电子传输层成为当前亟待解决的问题之一。纳米ZnO具有合适的能级和较高的电子迁移率,且可以通过低温制备,被广泛应用在光伏器件中作为电子传输层。因此,通过旋涂法和静电纺丝法分别制备了刚性纳米ZnO和柔性纳米ZnO电子传输层,确定了静电纺丝法制备柔性纳米ZnO的最佳制备工艺。利用扫描电子显微镜、X射线衍射仪、紫外可见分光光度计和稳态/瞬态荧光光谱系统研究了刚性和柔性纳米ZnO对钙钛矿薄膜形貌、结构和光谱性能的影响。结果表明,钙钛矿薄膜的形貌对基底纳米ZnO的形貌依赖性很强。而基于刚性和柔性纳米ZnO的钙钛矿薄膜几乎呈现相同的结构和光谱吸收范围,荧光发射峰均在770 nm附近,且柔性纳米ZnO的荧光猝灭效率为82%,几乎和刚性纳米ZnO的荧光猝灭效率(85%)相媲美。进一步,根据瞬态荧光动力学数据计算获得刚性和柔性纳米ZnO的界面电荷分离效率分别为61%和41%,这表明通过静电纺丝法制备的柔性纳米ZnO具备一定的界面电荷分离能力,有望成为新型的柔性电子传输层。这对柔性基底钙钛矿太阳能电池的设计具有重要参考价值,对促进钙钛矿光伏应用具有现实意义。