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Relationship Between Negative Air Ion Generation by Plants and Stomatal Characteristics Under Stimulation of Pulsed Electrical Field
Wu Renye, Sun Yuanfen, Zheng Jingui, Deng Chuanyuan, Ye Dapeng, Wang Qingshui
Chinese Bulletin of Botany    2017, 52 (6): 744-755.   DOI: 10.11983/CBB16242
Abstract   (1297 HTML17 PDF(pc) (641KB)(1142)  

Under normal conditions, the capacity of plants to generate negative air ions (NAIs) is very weak. However, stimulation of a pulsed electrical field can result in substantial improvement of the ability for NAI generation. We examined NAI generation in Stromanthe sanguinea, Calathea zebrina, and Hippeastrum rutilum in glass chambers under the natural state and under pulsed electrical field and light stimulation and analyzed the shape of stomata. We found variation in NAI generation by plants due to the different combined parameters of the pulsed electrical field. Each plant has its own optimal pulsed electrical field with a combination of parameters for efficient NAI generation: S. sanguinea with A3B3C3 (A3, U=1.5×104 V; B3, T=1.5 s; C3, τ =65 ms), C. zebrina with A3B4C1 (A3, U=1.5×104 V; B4, T=2.0 s; C1,τ =5 ms) and H. rutilum with A4B4C1 (A4, U=2.0×104 V; B4, T=2.0 s; C1, τ=5 ms). With the application of a pulsed electrical field to plants, the higher the voltage, the greater the capacity for NAI generation. With enhanced light intensity, the ability to generate NAI significantly increased with application of a pulsed electrical field. Without the pulsed electrical field, despite the slightly increased NAI concentration with increasing light intensity, NAI concentration did not differ (P>0.05). Finally, NAI generation was closely related to the characteristics of leaf stomata. Furthermore, a greater degree of stomatal opening and stomatal density was associated with stronger capacity to generate NAI.


Figure 1 Schematic of detecting negative air ions concentration by plant in a sealed chamber
a: High-voltage pulsed generator; b: Pulse probe; c: Air ions detector; d: Computer; e: Glass chamber; f: Plant; g: Adjustable insulation platform
Extracts from the Article
实验于2016年6-8月进行, 选择该段时间的晴天, 采用厚度为4 mm玻璃制成的规格为80 cm×80 cm×80 cm的可密封式玻璃室, 在其一个侧面截取104 mm×104 mm的小窗口, 窗口大小与DLY-4G-232型空气离子测量仪的进风口相匹配, 未测量时用玻璃挡板封闭窗口(图1)。调节盆栽植物中心, 使其与玻璃箱的中心重叠, 以保持空气离子测量仪进气口的中心与株顶处于同一水平。负离子浓度使用DLY-4G-232 型空气离子测量仪测定, 每秒读取1个数据, 并通过RS-232接口传输至电脑, 连续读取有效时间150秒, 取150个数据的平均值作为该植株释放负离子的浓度值, 将3组重复的负离子浓度平均值作为该种植物在该状态下释放的负离子浓度值。
图1
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