Air warming and CO enrichment increase N use efficiency and decrease N surplus in a Chinese double rice cropping system.

Effectiveness of N might be modified in rice cultivation under future climate change with elevated atmospheric CO concentration ([CO]). At present, limited information is available to understand how plant N uptake and N use efficiency respond to elevated [CO] and/or temperature in Chinese double rice cropping systems. A four-year field experiment was therefore conducted using open-top chambers with varying [CO] (ambient, ambient +60 μmol mol) and varying temperature (ambient, ambient +2 °C) in Hubei Province, Central China. Compared with ambient conditions, elevated [CO] increased plant N uptake and N use efficiency, as measured by fertilizer N recovery efficiency (NRE), N agronomic efficiency (NAE), N physiological efficiency (NPE) and apparent system N use efficiency (NUE), in both early rice and late rice. CO enrichment tended to decrease soil mineral N concentration since more N was assimilated by plants. Elevated temperature led to lower plant N uptake and decreased NRE and NAE in early rice, due to a reduction in grain yield induced by heat injury. In contrast, warming increased plant N uptake and N use efficiency in late rice as no heat stress existed. Warming tended to increase soil mineral N concentration in early rice but had negligible effects in late rice. When elevated [CO] and temperature were combined, the positive effects of CO enrichment for N utilization were able to compensate for the negative effects of warming in early rice, while the interaction was synergetic in late rice. Hence, co-elevation of [CO] and temperature led to higher N use efficiency (64.6% for NUE across four years) and decreased annual N surplus by 28.6-36.5 kg N ha compared with ambient conditions. Our findings confirm that CO enrichment and air warming can improve N use efficiency at both crop level and system level in Chinese double rice cultivation.