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中国农学通报

中国农学通报 ›› 2023, Vol. 39 ›› Issue (35): 111-117.doi: 10.11924/j.issn.1000-6850.casb2022-0979

• 资源·环境·生态·土壤·气象 • 上一篇    下一篇

增温和土壤肥力对大豆光合特征和产量的影响

冯茜(), 金丽惠, 薛海清, 岳娅, 苗欢, 苗淑杰, 乔云发()   

  1. 南京信息工程大学应用气象学院,南京 210044
  • 收稿日期:2022-11-17 修回日期:2023-01-09 出版日期:2023-12-11 发布日期:2023-12-11
  • 通讯作者:
    乔云发,男,1975年出生,黑龙江讷河人,教授,博士,研究方向:全球气候变化与土壤生态过程研究。通信地址:210044 江苏省南京市宁六路219号 南京信息工程大学应用气象学院,Tel:025-58731193,E-mail:
  • 作者简介:

    冯茜,女,1998年出生,山西忻州人,硕士,主要从事气象生态研究。通信地址:210044 江苏省南京市宁六路219号 南京信息工程大学应用气象学院,E-mail:

  • 基金资助:
    极端降水对农田生态系统减排增汇的驱动机制(BE2023400); 江苏省碳达峰碳中和科技创新专项资金“稻麦轮作生态系统应对气候变化的影响及适应性技术研究”(BE2022312)

Effects of Elevated Temperature and Soil Fertility on Photosynthetic Characteristics and Yield of Soybean

FENG Qian(), JIN Lihui, XUE Haiqing, YUE Ya, MIAO Huan, MIAO Shujie, QIAO Yunfa()   

  1. School of Applied Meteorology, Nanjing University of Information Sciences & Technology, Nanjing 210044
  • Received:2022-11-17 Revised:2023-01-09 Published-:2023-12-11 Online:2023-12-11

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摘要:

面对全球变暖的大背景,研究增温对大豆生长的影响,以期为大豆生产应对未来气候变化提供理论依据。选取高肥力和低肥力2个土壤类型,采用开放式增温系统,设置常温(aT)和增温(eT)处理,以‘金大豆626’为供试品种,探究增温对大豆三叶期、开花期和鼓粒期叶绿素含量、光合特性和产量的影响。结果表明:在三叶期,增温使高肥力土壤上大豆叶片Pn(光合速率)、Gs(气孔导度)和Tr(蒸腾速率)较对照分别下降了21.3%、36.7%、17.4%,低肥力土壤上大豆SPAD值(叶绿素)较对照提高了15.1%,而Pn下降了11.4%;在开花期,增温使高肥力土壤上叶片SPAD值提高了24.0%,而PnGsCi(胞间CO2浓度)和Tr(蒸腾速率)较对照均显著下降,低肥力土壤上大豆叶片GsCiTr较对照也均显著下降;在鼓粒期,与对照相比,增温使高肥力土壤上的大豆叶片PnGsTr分别提高了25.6%、55.5%和33.8%,而低肥力土壤上分别下降了42.4%、58.7%和56.1%。增温使高肥力土壤上的大豆较对照增产23.3%,而低肥力土壤上却减产10.9%。总体表明,大豆鼓粒期的光合能力是限制产量形成的关键要素,尤其在高肥力土壤上可以弥补生育前中期光合速率的不足,最终提高产量。因此,可以通过适当提高土壤肥力来增强大豆对未来气候变暖的适应能力。

关键词: 增温, 大豆, 光合参数, 产量, 土壤肥力

Abstract:

In face of global warming, the effect of elevated temperature on soybean growth was studied to provide theoretical basis for soybean production responding to future climate change. Two soil types, high and low fertility, were selected to study the effects of elevated temperature on chlorophyll content, photosynthetic characteristics and soybean yield at three leaf stage, flowering stage and bulking stage under ambient temperature (aT) and elevated temperature (eT) treatments by using an open warming system. The results showed that at the three leaf stage, eT decreased the Pn (photosynthetic rate), Gs (stomatal conductance) and Tr (transpiration rate) of soybean leaves by 21.3%, 36.7% and 17.4% on high fertility soil, respectively, while increased the SPAD value by 15.1% and decreased Pn by 11.4% on low fertility soil, respectively, compared to control. At flowering stage, leaf SPAD value was increased by 24.0% on high fertility soil, while Pn, Gs, Ci (intercellular CO2 concentration) and Tr (transpiration rate) were decreased significantly on low fertility soil at eT than that of control, and eT decreased leaf Gs, Ci and Tr on low fertility soil compared with the control. At the bulking stage, in contrast to control, leaf Pn, Gs and Tr at eT were increased by 25.6%, 55.5% and 33.8% on high fertility soil, but were decreased by 42.4%, 58.7% and 56.1% on low fertility soil, respectively. The increased temperature resulted in a 23.3% yield increase of soybean on high fertility soils compared to the control, while a 10.9% yield reduction on low fertility soils. The photosynthetic capacity of soybean at bulking stage was the key factor in limiting yield formation, especially on high fertility soil, which can offset the insufficient photosynthesis at early growth stage, and finally improved yield. Therefore, adjusting soil fertility would be a potential strategy to improve the adaptability of soybean production to future global warming.

Key words: warming, soybeans, photosynthetic parameter, output, soil fertility