模拟大气温度和CO2浓度升高对双季稻氮素利用的影响

doi:10.3724/SP.J.1006.2015.01295

Abstract

Abstract:

Preventing 2°C of warming and restricting the CO₂ level to 450 µL L^-1 are the safety threshold for climate change based on the Copenhagen Consensus. It is an important reference for the security of rice yields to study the influence of elevated air temperature and CO₂ concentration on the nitrogen use of rice. In this paper, a modified open-top chamber (OTC) device was used to simulate relative 60 µL L^-1 CO₂ concentration rise (based on CO₂ background concentration of 390 µL L^-1) and 2°C temperature increase scenario in a double rice field experiment with Liangyou 287 and Xiangfengyou 9 as the early and late rice varieties respectively. There were five treatments with three replications: 1) UC: Paddy field without OTC cover; 2) CK: Check OTC with the similar temperature and CO₂ concentration to the field environment; 3) CT: OTC with 2°C temperature increase; 4) CC: OTC with 60 µL L^-1 CO₂ concentration elevated; 5) CTC: OTC with 2°C temperature increase and 60 µL L^-1 CO₂ concentration elevated. The nitrogen accumulation, translocation and utilization in different treatments were explored. The results showed significant interactions between temperature increase and CO₂ concentration elevated on the yield and nitrogen use. In early rice CC and CTC achieved an increase for grain yield (19.7% and 2.0%) and nitrogen accumulation (15.7% and 5.1%) compared with CK while CT presented a decrease. In late rice warming and high CO₂concentration (CT, CC, and CTC) benefited the grain yield and nitrogen uptake, increasing 9.2%, 14.4%, 18.8% and 7.3%, 10.2%, 15% compared with CK respectively. Nitrogen translocation and contribution efficiency (from stem and leaf to grain) of CC and CTC was lower than that of CK in early rice, and higher than that of CK in late rice. Nitrogen recovery efficiency of CC and CTC reached to 45.7% and 48.5% in early and late rice respectively, achieving the highest increase of 35.3% and 33.1% compared with that of CK. CC and CTC got the highest nitrogen agronomic efficiency by 23.1 kg kg^-1 and 26.9 kg kg^-1 in early and late rice respectively, and CC got the highest nitrogen physiological efficiency by 50.7 kg kg^-1 and 56 kg kg^-1 in both early and late rice. There existed no significant difference between CK and UC, which suggested the impact on rice growth under OTC covering was slight. In conclusion, it tends to a negative effect with 2°C temperature increase on yield and nitrogen utilization for early rice, while a positive effect for late rice. A positive effect with 60 µL L^-1 CO₂ concentration elevated always exists during double rice growth. The condition of 2°C temperature increase and 60 µL L^-1 CO₂ concentration elevated has an antagonistic effect on early rice, while a synergistic effect on late rice.

Key words: Open-top chamber, Temperature, CO₂concentration, Double rice, Nitrogen accumulation, Nitrogen use efficiency

WANG Bin,WAN Yun-Fan,GUO Chen,LI Yu-E,YOU Song-Cai,QIN Xiao-Bo,CHEN Hui-Lin. Effects of Elevated Air Temperature and Carbon Dioxide Concentration on the Nitrogen Use of Double Rice (Oryza sativa L.) in Open-top Chambers[J].Acta Agron Sin, 2015, 41(08): 1295-1303.

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Effects of Elevated Air Temperature and Carbon Dioxide Concentration on the Nitrogen Use of Double Rice (Oryza sativa L.) in Open-top Chambers

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