夏玉米-冬小麦轮作期土壤呼吸的温度敏感性分析

doi:10.3969/j.issn.1000-6362.2020.07.001

摘要/Abstract

摘要： 研究土壤呼吸和温度敏感性（Q10）的季节变化对丰富农田土壤的碳循环理论具有重要理论和现实意义。采用动态密闭气室法于2018年6月-2019年6月连续监测北京夏玉米-冬小麦轮作期间农田土壤呼吸速率，研究不同作物生育期Q10值和土壤呼吸变化特征，综合分析土壤温度和土壤含水率对土壤呼吸的影响。结果表明：日内尺度上不同作物生育期土壤呼吸变化均呈单峰型，对土壤温度昼夜变化的响应关系呈顺时针近椭圆曲线；Q10具有明显的季节变化特征，夏玉米苗期、拔节-抽雄、开花-成熟3个时期Q10分别为2.27、6.13、1.28，在整个夏玉米季，土壤体积含水率在19.52%～45.43%变化，水分解释了50%的土壤呼吸变化（P<0.05），临界值土壤体积含水率为27.84%（田间持水量的83.83%），土壤温度只能解释夏玉米季土壤呼吸速率变化的3%（P>0.05），Q10为1.29。冬小麦出苗-分蘖期、越冬期、返青-拔节期、孕穗-抽穗期、开花-成熟期Q10分别为4.17、8.41、6.57、2.53、1.92，与土壤温度呈显著负相关关系（P<0.05），温度能够解释冬小麦季土壤呼吸变化的88%（P<0.01），Q10为2.50。在整个轮作周年，土壤温度和土壤含水率分别解释54%（P<0.01）、28%（P<0.05）的土壤呼吸变化，周年尺度的Q10为1.72。可见，在气候变化背景下，使用Q10预测土壤呼吸需采用合适的时间尺度，同时注意土壤水分对Q10模型适用性的影响。

关键词: , 土壤呼吸速率, 温度敏感性, Q10值, 夏玉米-冬小麦轮作

Abstract: The temperature sensitivity of soil respiration (Q10) is often used in exponential models to predict or interpolate soil respiration (RS). However, beyond temperature, Q10 can be influenced by factors such as soil water content, substrate availability and microbial activity, so that Q10 may vary with seasonally fluctuating conditions and processes, and differences between Q10 derived from different time scales may exist. In order to understand the variation of RS and Q10 on croplands soils, RS was measured continuously for half an hour by a multichannel automatic soil CO2 efflux system (Li-8150, USA) in a summer maize-winter wheat double cropping system from June 2018 to June 2019 in Beijing suburb. Summer maize growth season was divided into three stages (2018-06-22—2018-07-15, 2018-07-16—2018-08-15, 2018-08-16—2018-09-17), and winter wheat growth season were decomposed into five stages (2018-10-01—2018-11-22, 2018-11-23—2019-02-25, 2018-02-26—2019-04-10, 2019-04-11—2019-05-13, 2019-05-14—2019-06-17) according to the phenology. Seasonal variation of RS and Q10 values at different crop growth stages were studied, respectively, and their responses to the influence factors including soil temperature at 5cm depth, soil water content, leaf area index and aboveground biomass were analyzed in this article. Moreover, diurnal dynamics of soil respiration rate at different growth state were calculated. The main results are showed as follow: (1) the diurnal variation of the soil respiration rates in different growth stages appeared as a single-peak curve as well as the soil temperature. But soil temperature often peaked later than the half-hourly soil respiration rates at the wheat growth season. The lag time of soil temperature for each growth stages were 4.5, 5.0, 5.0, 2.5, 0.5h. The relationships between diurnal RS and soil temperature showed a clockwise nearly elliptic curve. (2) Q10 exhibited a strong seasonal variation. At seedling, jointing to tasseling, and flowering to mature stage of summer maize, Q10 values were 2.27, 6.13 and 1.28 respectively. During the whole growth period of summer maize, soil water content ranged from 19.52% to 45.43%, and an quadric curve downwards of soil moisture could explain 50% of variation for RS (P<0.05), with the threshold value being 27.84%, which came to about 83.83% of field capacity. Exponential models of soil temperature could only explain 3% of variation for RS (P>0.05), and the Q10 value obtaining from whole growth stage of summer maize was 1.29. (3) Q10 values at different growth stages of winter wheat were 4.17, 8.41, 6.57, 2.53, 1.92, respectively, negatively correlated with soil temperature (P<0.05). At the scale of whole winter wheat season, Q10 value reached to 2.50, and soil temperature was a major factor influencing RS, which explained 88% of the variation for RS (P<0.01). On one-year scale, soil temperature and soil water content explained 54% (P<0.01), 28% (P<0.05) of the variation for RS, and Q10 was 1.72. In consideration of the difference of Q10 at each stage, we found that RS may decoupled from soil temperature at higher soil water content which were closed to field capacity, influencing the applicability of Q10 value. Additionally, time scale should be ascertained with caution, for the Q10 values obtained from inappropriate scales may underestimate or overestimate the future soil respiration rates under the conditions of global warming.

Key words: Soil respiration, Temperature sensitively, Q10, Summer maize-winter wheat

中图分类号:

卢闯，胡海棠，淮贺举，程成，田宇杰，李存军. 夏玉米-冬小麦轮作期土壤呼吸的温度敏感性分析[J]. 中国农业气象, 2020, 41(07): 403-412.

LU Chuang, HU Hai-tang, HUAI He-ju, CHENG Cheng, TIAN Yu-jie, LI Cun-jun. Characteristics of Temperature Sensitivity of Soil Respiration in a Summer Maize- Winter Wheat Rotation Cropland[J]. Chinese Journal of Agrometeorology, 2020, 41(07): 403-412.

参考文献

[1]Zhou L Y,Zhou X H,Zhang B C,et al.Different responses of soil respiration and its components to nitrogen addition among biomes:a meta-analysis[J].Global Change Biology, 2014,20(7):2332-2343. [2]Raich J W,Potter C S,Bhagawati D,et al.Interannual variability in global soil respiration[J].Global Change Biology,2010,8(8):800-812. [3]Zheng Z M,Yu G R,Fu Y L,et al.Temperature sensitivity of soil respiration is affected by prevailing climatic conditions and soil organic carbon content:a trans-China based case study[J].Soil Biology and Biochemistry,2009,41:1531- 1540. [4]张彦军,党水纳,郭胜利.黄土高原旱地冬小麦不同生育期根系呼吸及其温度敏感性[J].应用生态学报,2019,30(11): 3762-3770. Zhang Y J,Dang S N,Guo S L.Root respiration and its temperature sensitivity at various growth stages of winter wheat in the Loess Plateau,Northwest China[J].Chinese Journal of Applied Ecology,2019,30(11):3762-3770.(in Chinese) [5]杨庆朋,徐明,刘洪升,等.土壤呼吸温度敏感性的影响因素和不确定性[J].生态学报,2011,31(8):2301-2311. Yang Q P,Xu M,Liu H S,et al.Impact factors and uncertainties of the temperature sensitivity of soil respiration[J].Acta Ecologica Sinica,2011,31(8):2301- 2311.(in Chinese) [6]葛怡情,闫玉龙,梁艳,等.模拟降水氮沉降对藏北高寒草甸土壤呼吸的影响[J].中国农业气象,2019,40(4):214-221. Ge Y Q,Yan Y L,Liang Y,et al.The effects of nitrogen deposition on soil respiration in an alpine meadow in northern Tibet[J].Chinese Journal of Agrometeorology, 2019,40(4):214-221.(in Chinese) [7]Yang P,Derrick Y F,Lai J,et al.Temporal variations and temperature sensitivity of ecosystem respiration in three brackish marsh communities in the Min River Estuary, southeast China[J].Geoderma,2018,327:138-150. [8]Yan T,Song H S,Wang Z W,et al.Temperature sensitivity of soil respiration across multiple time scales in a temperate plantation forest[J].Science of the Total Environment,2019, 688:479-485. [9]Han M G,Jin G Z.Seasonal variation of Q10 soil respiration and its components in the temperate forest ecosystems, northeastern China[J].European Journal of Soil Biology, 2018,85:36-42. [10]Chen B Y,Liu S R,Ge J P,et al.Annual and seasonal variations of Q10 soil respiration in the sub-alpine forests of the Eastern Qinghai-Tibet Plateau,China[J].Soil Biology and Biochemistry,2010,42(10):1735-1742. [11]Curiel Y,Janssens I,Carrara A,et al.Annual Q10 of soil respiration reflects plant phenological patterns as well as temperature sensitively[J].Global Change Biology,2004 (10):161-169. [12]张国平,周伟军.作物栽培学[M].杭州:浙江大学出版社,2016. Zhang G P,Zhou W J.Crop production[M].Hangzhou: Zhejiang University Press,2016.(in Chinese) [13]Luo Y Q,Zhou X H.Soil respiration and the environment [M].Beijing:High Education Press,2007. [14]Jia X,Zha T S,Wu B,et al.Temperature response of soil respiration in a Chinese pine plantation:hysteresis and seasonal vs. Diel Q10[J].Plos One,2013,8(2):1-9. [15]毛一男,胡振华,彭致功,等.不同施肥水平对夏玉米土壤呼吸的影响研究[J].中国农村水利水电,2019,(4):43-46. Mao Y N,Hu Z H,Peng Z G,et al.Effects of different nitrogen levels on soil respiration of summer maize[J]. China Rural Water and Hydropower,2019,(4):43-46.(in Chinese) [16]Lee X H,Wu H J,Sigler J,et al.Siccama T. rapid and transient response of soil respiration to rain[J].Global Change Biology,2004,10(6):1017-1026. [17]杜珊珊,丁新宇,杨倩,等.黄土旱塬区免耕玉米田土壤呼吸对降雨的响应[J].生态学报,2016,36(9):2571-2577. Du S S,Ding X Y,Yang Q,et al.Response of soil respiration of corn field under no tillage to precipitation events in loessial tablelands[J].Acta Ecologica Sinica, 2016,36(9): 2571-2577.(in Chinese) [18]金冠一,赵秀海,康峰峰,等.太岳山油松人工林土壤呼吸对强降雨的响应[J].生态学报,2013,33(6):1832-1841. Jin G Y, Zhao X H, Kang F F, et al. The great rainfall effect on soil respiration of Pinus tabulaeformis plantation in Taiyue Mountain[J].Acta Ecologica Sinica,2013,33(6): 1832-1841.(in Chinese) [19]Liang G P, Albert A, Wu H J, et al. Seasonal patterns of soil respiration and related soil biochemical properties under nitrogen addition in winter wheat field[J].Plos One,2015, 10(12):e0144115. [20]Tong X J,Li J,Rachael H,et al.Biophysical controls of soil respiration in a wheat-maize rotation system in the North China Plain[J].Agricultural and Forest Meteorology, 2017,246:231-240. [21]Jassens I A,Pilegaard K.Large seasonal change in Q10 of soil respiration in beech forest[J].Global Change Biology, 2003,9:911-918. [22]Andrews J A,Matamala R,Westover K M,et al.Temperature effects on the diversity of soil heterotrophs and the 13C of soil respired CO2[J].Soil Biology ＆ Biochemistry,2000, 32:699-706. [23]Huang W J,Liu J X,Han T F,et al.Different plant covers change soil respiration and its sources in subtropics[J]. Biology and Fertility of Soils,2017,53(4):1-10. [24]Yuste J C,Janssens I A,Carrara A R,et al.Annual Q10 of soil respiration reflects plant phenological patterns as well as temperature sensitivity[J].Global Change Biology,2004, 10:161-169. [25]Wang B,Zha T S,Jia X,et al.Soil mositure modifies the response of soil respiration to temperature in a desert shrub ecosystem[J].Biogeosciences,2014,11:259-268. [26]张盼弟,王旭,陈宝瑞,等.呼伦贝尔地区贝加尔针茅草甸草原土壤CO2排放特征[J].应用生态学报,2014,25(2): 387-393. Zhang P D,Wang X,Chen B R,et al.CO2 release characteristics from Stipa baicalensis meadow steppe in the Hulunbeir region,Inner Mogolia,China[J].Chinese Journal of Applied Ecology,2014,25(2):387-393.(in Chinese) [27]Phillips C L,Nickerson N,Risk D,et al.Interpreting diel hysteresis between soil respiration and temperature[J]. Global Change Biology,2011,17:515-527. [28]张晓龙,沈冰,权全,等.渭河平原农田冬小麦土壤呼吸及其影响因素[J].应用生态学报,2016,27(8):2551-2560. Zhang X L,Shen B,Quan Q,et al.Soil respiration rates and its affecting factors in winter wheat land in the Weihe Plain,Northwest China[J].Chinese Journal of Applied Ecology,2016,27(8):2551-2560.(in Chinese)