The synergy problem was discussed linking Se nanoparticles and different soil fertility agents. Se zero-valent-state nanoparticles were investigated as fertilizers and antioxidants. A technology was proposed for producing Se zero-valent-state nanoparticles. Se nanoparticles were obtained by laser ablation of Se in water using a fiber ytterbium laser, with a wavelength between 1060 and 1070 nm, a pulse repetition rate of 20 kHz, a pulse duration of 80 ns, and an average power of 20 W, and a copper vapor laser with wavelengths of 510.6 and 578.2 nm and an average power of 8 W. The main particle mass part shifted from 800 nm to a size less than 100 nm, corresponding to the increase in the laser fragmentation time. The resulting nanoparticles were monodisperse in size and mass. The Se nanoparticle water suspension was introduced into the soil. The soil Se nanoparticle concentrations were about 1, 5, 10, and 25 μg kg~(–1). An experiment was carried out in a climate chamber in two series: (1) growing plants in soil imitating the standard organogenesis environment conditions such as illumination of 16 h per day, temperature of 22 °C, soil humidity of 25% SDW, and an experiment duration of 30 days and (2) growing plants in soil under changing environmental conditions of organogenesis. The standard environmental conditions for the first 10 days are illumination of 16 h day~(–1), temperature of 22 °C, and soil humidity of 25% SDW. The plant stress for 5 days is hyperthermia of 40 °C. The standard environmental conditions for the next 15 days are illumination of 16 h day~(–1), temperature of 22 °C, and soil humidity of 25% SDW. At standard organogenesis, the plant leaf plate surface area was 30 ± 2 cm~(2) in the control option, and the Se nanoparticle doses were correspondingly 1 μg kg~(–1) for 32 ± 3 cm~(2), 5 μg kg~(–1) for 37 ± 2 cm~(2), 10 μg kg~(–1) for 38 ± 3 cm~(2), and 25 μg kg~(–1) for 28 ± 4 cm~(2). Hyperthermia stressed plant growth was studied. The highest plant growth rate was in Se nanoparticle concentrations of 5 and 10 μg kg~(–1). The eggplant growth on the soil with the Se nanoparticle addition at a concentration of 10 μg kg~(–1) of leaf plate surface area was twice compared to the eggplant growth in untreated soil. The same was for tomato plants. The leaf plate surface area of the cucumber plant grown using Se nanoparticles was 50% higher compared to the control option. The Biogeosystem technique methodology of 20–45 cm soil-layer intrasoil milling for soil multilevel aggregate system formation and intrasoil pulse continuous-discrete watering for soil water regime control was proposed for the Se nanoparticles for better function in the real soil, providing a synergy effect of soil mechanical processing, nanoparticles, humic substances, and polymicrobial biofilms on soil fertility.
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机译:讨论了链接SE纳米颗粒和不同土壤肥力剂的协同问题。 SE Zero-Valent-rency纳米粒子被研究为肥料和抗氧化剂。提出了一种用于生产SE零价纳米粒子的技术。通过使用纤维YTTerbium激光激光在水中激光烧蚀Se的纳米颗粒,波长在1060和1070nm之间,脉冲重复率为20kHz,脉冲持续时间为80ns,平均功率为20W,波长为510.6和578.2nm的铜蒸汽激光和8W的平均功率。主要颗粒质量部分从800nm偏移到小于100nm的尺寸,对应于激光碎片时间的增加。所得纳米颗粒的大小和质量是单分散的。将SE纳米粒子水悬浮液引入土壤中。土壤Se纳米颗粒浓度为约1,5,10和25μgkg〜(-1)。在两个系列的气候室中进行了实验:(1)在土壤中种植植物,仿标准的有机组织环境条件,如每天6小时的照明,温度为22°C,土壤湿度为25%SDW,以及实验持续时间为30天和(2)变化的机组体环境条件下土壤中种植植物。前10天的标准环境条件是16小时〜(-1),温度为22°C的照明,土壤湿度为25%SDW。植物应激5天是40°C的热疗。下一个15天的标准环境条件是16小时〜(-1),温度为22°C的照明,土壤湿度为25%SDW。在标准的器官发生中,控制选项中的植物叶片表面积为30±2cm〜(2),并且SE纳米颗粒剂量相应地为1μgkg〜(-1)32±3cm〜(2),5 μgkg〜(-1)37±2cm〜(2),10μgkg〜(-1),38±3cm〜(2),25μgkg〜(-1),28±4 cm〜 (2)。研究了高温强调植物生长。最高植物生长速率在硒纳米颗粒浓度为5和10μgkg〜(-1)。与未处理土壤中的茄子生长相比,用SE纳米粒子的浓度添加到10μgkg〜(-1)的浓度为10μgkg〜(-1)的茄子生长。这也是番茄植物。与对照选项相比,使用SE纳米粒子生长的黄瓜植物的叶片表面积比为50%。用于土壤多级系统形成和intrasoil脉冲的土壤多级系统形成和intrasoil脉冲连续离散浇水的生物晶片体系方法,为土壤水分控制,为实际土壤较好,提供了一种协同作用土壤机械加工,纳米粒子,腐殖质和多发性生物膜对土壤肥力。
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