微信公众号：黑龙江农业科学编辑部

PDF下载 +分享

[1]高义霞,周向军,王亮亮,等.纳米硒微肥的形貌分析及对豌豆幼苗生长的影响[J].黑龙江农业科学,2023,(04):24-30.[doi:10.11942/j.issn1002-2767.2023.04.0024]
　GAO Yixia,ZHOU Xiangjun,WANG Liangliang,et al.Morphology Analysis of Nano-Selenium Microfertilizer and Its Effects on Seedling Growth of Pisum sativum L.[J].HEILONGJIANG AGRICULTURAL SCIENCES,2023,(04):24-30.[doi:10.11942/j.issn1002-2767.2023.04.0024]

点击复制

纳米硒微肥的形貌分析及对豌豆幼苗生长的影响

《黑龙江农业科学》[ISSN:1002-2767/CN:23-1204/S] 卷: 期数: 2023年04 页码: 24-30 栏目: 出版日期: 2023-04-10

Title:: Morphology Analysis of Nano-Selenium Microfertilizer and Its Effects on Seedling Growth of Pisum sativum L.

文章编号:: 6

作者:: 高义霞1; 2; 周向军1; 2; 王亮亮1; 马丽媛1; 1.天水师范学院生物工程与技术学院/甘肃省农业固体废弃物资源化利用重点实验室，甘肃天水 741001； 2.甘肃省大樱桃工程技术研究中心，甘肃天水 741001

Author(s):: GAO Yixia1; 2; ZHOU Xiangjun1; 2; WANG Liangliang1; MA Liyuan1; 1.Key Laboratory of Utilization of Agriculture Solid Waste Resources/College of Bioengineering and Biotechnology， Tianshui Normal University， Tianshui 741001，China； 2.Gansu Engineering Technology Research Center for Sweet Cherry， Tianshui 741001，China

关键词:: 纳米硒; 微肥; 形貌分析; 豌豆; 植株生长

Keywords:: nano-selenium; microfertilizer; morphology analysis; Pisum sativum L.; plant growth

DOI:: 10.11942/j.issn1002-2767.2023.04.0024

文献标志码:: A

摘要:: 为制备筛选易于吸收的纳米硒微肥，利用化学还原法制备纳米硒，通过不同干燥处理和扫描电镜技术研究纳米硒的形貌特征、尺寸及稳定性。将纳米硒与豌豆种子拌种后进行盆栽试验，测定豌豆幼苗的硒吸收量和硒转化率。结果表明，透射电镜和扫描电镜下，冷冻干燥制备的纳米硒为分散均匀、尺寸均一的球状颗粒，平均粒径约为28 nm。当拌种剂量（纳米硒/豌豆种子）在0.25～2.50 mg·g-1范围内，纳米硒微肥对豌豆幼苗生理指标的影响较小。豌豆幼苗根系硒含量均达到极显著水平，地上部分硒含量在2.00和2.50 mg·g-1拌种剂量时显著高于对照和其他处理；在1.00～2.50 mg·g-1范围内，硒吸收量存在显著差异；在0.25～250 mg·g-1[JP]范围内，硒转化率呈先降低后增加的趋势。综上，冷冻干燥制备法可获得分散均匀、尺寸均一的纳米硒微肥。拌种剂量控制在0.25~2.50 mg·g-1范围内时，豌豆幼苗地下部分对纳米硒的吸收率大于硒转化率，可采用冷冻干燥法制备纳米硒微肥用于豌豆生产。

Abstract:: In order to prepare nano-selenium microfertilizer which is easy to absorb， nano-selenium was prepared by chemical reduction method. The morphology， size and stability of nano-selenium were studied by different drying treatments and scanning electron microscopy. The seed of Pisum sativum was mixed with nano-selenium， and then the pot experiment was carried out to determine the selenium absorption and selenium transformation rate of Pisum satirum seedlings. The results showed that under transmission electron microscope and scanning electron microscope，the nano-selenium prepared by freeze-drying was spherical particles with uniform distribution and size， and the average particle size was about 28 nm. When the seed dressing dose (nano-selenium/pea seed) was in the range of 0.25-2.50 mg·g-1， nano-selenium microfertilizer has little effect on the physiological indexes of Pisum sativum seedlings. The selenium content in the root of pea seedlings reached a very significant level， and the selenium content in the aboveground part was significantly higher than that of the control and other treatments at the dosage of 2.00 and 2.50 mg·g-1 seed dressing. In the range of 1.00-2.50 mg·g-1， there was a significant difference in selenium absorption; In the range of 0.25-2.50 mg·g-1， the selenium transformation rate decreased first and then increased. To sum up， the freeze-drying preparation method can obtain nano-selenium microfertilizer with uniform dispersion and size. When the seed dressing dose was controlled in the range of 0.25-2.50 mg·g-1， the absorption rate of nano-selenium in the underground part of pea seedlings was greater than the selenium transformation rate， so nano-selenium microfertilizer can be prepared by freeze-drying method for Pisum sativum production.

参考文献/References:

［1］WANG J，LI H R，YANG L S，et al.Distribution and translocation of selenium from soil to highland barley in the Tibetan PlateauKashin-Beck disease area[J].Environmental Geochemistry and Health，2017，39(1):221-229．[2]中华人民共和国卫生部.2009中国卫生统计年鉴[M].北京：中国协和医科大学出版社，2009.[3]WILLIAMSP N，LOMBI E，SUN G X，et al.Selenium characterization in the global rice supply chain[J].Environmental Science & Technology，2009，43(15)：6024-6030.[4]RAYMAN M P.Selenium and human health[J].Lancet，2012，379(9822):1256-1268.[5]王晓芳，陈思杨，罗章，等.植物对硒的吸收转运和形态转化机制[J].农业资源与环境学报，2014，31(6):39-544.[6]张驰，吴永尧，彭振坤.植物硒的研究进展[J].湖北民族学院学报(自然科学版)，2002，20(3)：58-62．[7]BOLDRIN P F，FAQUIN V，RAMOS S J，et al.Soil and foliar application of selenium in rice biofortification[J].Journal of Food Composition and Analysis，2013，31(2):238-244.[8]GUSTAVO M M，JON S L，MARA E L G，et al.Insights into the accumulation and transformation of Ch-SeNPs by Raphanus sativus and Brassica juncea：effect on essential elements uptake[J].Science of the Total Environment，2020，725:138453.[9]WANG K，WANG Y，LI K，et al.Uptake，translocation and biotransformation of selenium nanoparticles in rice seedlings(Oryza sativa L.)[J].Journal of Nanobiotechnology，2020，18:103-115.[10](黄开规，徐辉碧．硒的化学、生物化学及其在生命科学中的应用[Ｍ]．武汉：华中科技大学出版社，2009.[11]周勋波，吴海燕，张惠君，等.喷施硒肥对大豆生长发育和生理生态参数的影响[J].华北农学报，2004，19(4)：77-80.[12]唐巧玉，吴永尧，周大寨.硒对大豆苗期生长的影响[J].湖北民族学院学报(自然科学版)，2005，23(2)：124-126.[13]铁梅，韩杰，李宝瑞，等.土壤施硒对黑豆和黄豆硒质量分数及产量的影响[J].西北农业学报，2014，23(10)：90-96.[14]刘春菊，刘夫国，陈伟，等.叶面喷施硒肥对鲜食玉米硒富集的影响[J].江苏农业学报，2012，28(4)：713-716.[15]SHABAAN M，ASGHAR H N，AKHTAR M J，et al.Role of plant growth promoting rhizobacteria in the alleviation of lead toxicity to Pisum sativum L.[J].International Journal of Phytoremediation，2020，23(8):837-845.[16]TERRY N，ZAYED A M，de SOUZA M P，et al.Selenium in higher plants[J].Annual Review of Plant Physiology & Plant Molecular Biology，2000，51(1):401-432.[17]SORS T，ELLIS D，SALT D.Selenium uptake，translocation，assimilation and metabolic fate in plants[J].Photosynthesis Research，2005，86(3):373-389.[18]ZHAO X Q，MITANI N，YAMAJI N，et al.Involvement of silicon infux transporter OsNIP2;1 in selenite uptake in rice[J].Plant Physiology，2010，153(4):1871-1877.[19]LI H，McGRATH S P，ZHAO F.Selenium uptake，translocation and speciation in wheat supplied with selenate or selenite[J].New Phytologist，2010，178(1):92-102.[20]ZHANG L，HU B，LI W，et al.OsPT2，a phosphate transporter，is involved in the active uptake of selenite in rice[J].New Phytologist，2014，201(4):1183-1191.[21]WANG P，MENZIES N W，LOMBI E，et al.Synchrotron-based X-ray absorption near-edge spectroscopy imaging for laterally resolved speciation of selenium in fresh roots and leaves of wheat and rice[J].Journal of Experimental Botany，2015，66(15):4795-4806.[22]YANG X，ALIDOUST D，WANG C.Effects of iron oxide nanoparticles on the mineral composition and growth of soybean (Glycine max L.) plants[J].Acta Physiologiae Plantarum，2020，42（8）:128-139.[23]NGAN H T M，TUNG H T，van LE B，et al.Evaluation of root growth，antioxidant enzyme activity and mineral absorbability of carnation (Dianthus caryophyllus “Express golem”) plantlets cultured in two culture systems supplemented with iron nanoparticles[J].Scientia Horticulturae，2020，272:109612-109623.[24]GHAFARIYAN M H，MALAKOUTI M J，DADPOUR M R，et al.Effects of magnetite nanoparticles on soybean chlorophyll[J].Environmental Science & Technology，2013，47(18)：10645-10652.[25]PULIZZI F.Nano in the future of crops[J].Nature Nanotechnology，2019，14(6):507.[26]GOLSHAHI S，AHANGAR AG，MIR N，et al.A comparison of the use of different sources of nanoscale iron particles on the concentration of micronutrients and plasma membrane stability in sorghum[J].Journal of Soil Science and Plant Nutrition，2018，18(1)：236-252.[27]HAGHIGHI M，ABOLGHASEMI R，SILVA J A T D.Low and high temperature stress affect the growth characteristics of tomato in hydroponic culture with Se and nano-Se amendment[J].Scientia Horticulturae，2014，178：231-240.[28]LI Y X，ZHU N L，LIANG X J，et al.A comparative study on the accumulation，translocation and transformation of selenite，selenate，and SeNPs in a hydroponic-plant system[J].Ecotoxicology and Environmental Safety，2019，189(1):1-7.[29]WANG K，WANG Y Q，LI K，et al.Uptake，translocation and biotransformation of selenium nanoparticles in rice seedlings (Oryza sativa L.)[J].Journal of Nanobiotechnology，2020，18:103-118.[30]INGLE A P，DURAN N，RAI M.Bioactivity，mechanism of action，and cytotoxicity of copper-based nanoparticles：a review[J].Applied Microbiology and Biotechnology，2014，98(3):1001-1009.[31]MOORE M N.Do nanoparticles present ecotoxicological risks for the health of the aquatic environment[J].EnvironmentInternational，2006，32(8):967-976.[32]王雅琦，朱丽娜，李奎，等.小麦和水稻对纳米硒的吸收和转运[J].环境科学，2019，40（10）：4654-4660.[33]HU T，LI H F，LI J X，et al.Absorption and bio-transformation of selenium nanoparticles by wheat seedlings (Triticum aestivum L.) [J].Frontiers in Plant Science，2018，9:597.[34]HU T，LI H F，ZHAO G S，et al.Selenium enriched Hypsizygus marmoreus，a potential food supplement with improved Se bioavailability[J].Food Science and Technology，2021，140:110819.[35]LUO H W，HE L X，DU B，et al.Biofortification with chelating selenium in fragrant rice:effects on photosynthetic rates，aroma，grain quality and yield formation[J].Field Crops Research，2020，255:107909.

相似文献/References:

[1]刘东林,张玉山. 寒区湿地水稻施用微肥技术研究[J].黑龙江农业科学,1993,(05):3.[doi:10.11942/j.issn1002-2767.1993.05.0003]
　[J].HEILONGJIANG AGRICULTURAL SCIENCES,1993,(04):3.[doi:10.11942/j.issn1002-2767.1993.05.0003]
[2]倪淑君. 氨基酸复合微肥喷施西瓜的综合效应[J].黑龙江农业科学,1997,(02):42.[doi:10.11942/j.issn1002-2767.1997.02.0042]
　[J].HEILONGJIANG AGRICULTURAL SCIENCES,1997,(04):42.[doi:10.11942/j.issn1002-2767.1997.02.0042]
[3]孟庆英,韩旭东,张春峰,等.根瘤菌与微肥对大豆生理及产量的影响[J].黑龙江农业科学,2017,(02):51.[doi:10.11942/j.issn1002-2767.2017.02.0051]
　MENG Qing-ying,HAN Xu-dong,ZHANG Chun-feng,et al.Effect of Rhizobia and Trace Fertilizer on Physiological and Yield of Soybean[J].HEILONGJIANG AGRICULTURAL SCIENCES,2017,(04):51.[doi:10.11942/j.issn1002-2767.2017.02.0051]
[4]孙思淼,王晓军,高洪生.矿质生物肥和秸秆还田耦合技术对水稻产量的影响[J].黑龙江农业科学,2023,(02):17.[doi:10.11942/j.issn1002-2767.2023.02.0017]
　SUN Simiao,WANG Xiaojun,GAO Hongsheng.Effects of Coupling Technology of Mineral Biofertilizer and Straw Returning on Rice Yield[J].HEILONGJIANG AGRICULTURAL SCIENCES,2023,(04):17.[doi:10.11942/j.issn1002-2767.2023.02.0017]

备注/Memo

收稿日期：2022-12-09

基金项目：甘肃省高等学校创新基金项目（2022A-112）。

第一作者：高义霞（1982-），女，硕士，副教授，从事资源植物的开发利用研究。E-mail:egaoxy@126.com。

更新日期/Last Update: 2023-04-10