Soil nutrients and carbon management indexes in the rhizosphere versus non-rhizosphere area of different plant species in desert grassland

doi:10.11686/cyxb2017077

Abstract

Abstract: The main plant species used in the Ningxia Desert Grassland Vegetation Restoration Project are Caragana korshinskii, Artemisia ordosica, Stipa breviflora, and Agropyron mongolicum. The aim of this study was to explore the effects of different types of vegetation restoration on soil nutrients and carbon pool management index (CPMI) characteristics. We collected rhizosphere and non-rhizosphere soil from the surface (0-5 cm), subsurface (5-10 cm), and deep (10-15 cm) soil layers, and determined soil total carbon (C_r), active organic carbon (C_A), carbon pool index (CPI) and CPMI. For all four plant species, soil nutrients decreased with increasing soil depth, and these decreases were greater in the rhizosphere soil than in the non-rhizosphere soil. The content of available potassium (AK) in the rhizosphere and non-rhizosphere of the C. korshinskii community was 130.81 and 111.96 mg/kg, respectively. The soil AK content showed a “fat island” aggregation effect on the desert steppe, and showed significant differences among the different communities (P<0.05). 2) The total organic carbon content in soil ranged from 2.09 to 17.11 g/kg, and was higher in the rhizosphere soil than in the non-rhizosphere soil. The vertical distributions of C_r and C_A in the soil profile were similar, and showed a “poly table” effect. The carbon pool activity in the surface layer of the C. korshinskii and A. mongolicum community was 38.41% and 29.54% higher, respectively, than that in the deep layer. The four vegetation types could be ranked, from highest carbon pool activity to lowest, as follows: A. mongolicum>A. ordosica>C. korshinskii>S. breviflora. Vegetation restoration significantly improved the distribution of soil organic matter and the quality of the soil carbon pool, and increased the soil carbon sink function of the desert grassland. 3) The soil CPMI was significantly correlated with soil nutrient content in the desert grassland, and pH was negatively correlated with C_r, C_A, CPI, and CPMI (correlation coefficients of -0.661, -0.437, -0.661, and -0.410, respectively). The soil CPMI was significantly or extremely significantly positively correlated with other soil nutrients (P<0.05; P<0.01). Higher soil N, P, and K contents promoted the soil carbon pool turnover rate, and significantly improved soil quality and productivity. These results show that CPMI serves as an effective index when evaluating soil quality and soil management practices.

ZHANG Yi-Fan, CHEN Lin, LI Xue-Bin, LI Yue-Fei, YANG Xin-Guo. Soil nutrients and carbon management indexes in the rhizosphere versus non-rhizosphere area of different plant species in desert grassland[J]. Acta Prataculturae Sinica, 2017, 26(8): 24-34.

References

[1] Zhou L, Li B G, Zhou G S. Advances in controlling factors of soil organic carbon.Advances in Earth Science, 2005, 20(1): 99-105.
周莉, 李保国, 周广胜. 土壤有机碳的主导影响因子及其研究进展. 地球科学进展, 2005, 20(1): 99-105.
[2] Wang Q K, Zhong M C, Wang S L. A meta-analysis on the response of microbial biomass, dissolved organic matter respiration and Nmine ralization in mineral soil to fire in forest ecosystems. Forest Ecology and Management, 2012, 27(1): 91-97.
[3] Ji J Q, Xia Z J, Si H L, et al . Impacts of different varieties and farming methods on rhizosphere soil microorganisms of sweet potato in saline and alkaline. Shandong Science, 2013, 26(1): 22-27.
纪婧琦, 夏志洁, 司红丽,等. 不同品种及农作方式对盐碱地甘薯根际微生物的影响. 山东科学, 2013, 26(1): 22-27.
[4] Wang C, Wu F, Liu X L, et al . Tobacco rhizosphere microorganism in different fertility of soil. China Tobacco Science, 2005, 26(2): 12-14.
王超, 吴凡, 刘训理, 等. 不同肥力条件下烟草根际微生物的初步研究. 中国烟草科学, 2005, 26(2): 12-14.
[5] Zhang B, Yang Y A, Zepp H. Effect of vegetation restoration on soil and water erosion and nutrient losses of a severely eroded clayey Plinthudult in southeastern China. Catena, 2004, 57(1): 77-90.
[6] Zhang H H, Tang M, Chen H, et al . Microbial communities in Pinus tabulaeform is mycor rhizosphere under different ecological conditions. Acta Ecologica Sinica, 2007, 27(12): 5463-5470.
张海涵, 唐明, 陈辉, 等. 不同生态条件下油松( Pinus tabulaeformis )菌根根际土壤微生物群落. 生态学报, 2007, 27(12): 5463-5470.
[7] Huang Z Q, Liao L P, Wang S L, et al . Allelopathy of phenolics from decomposing stump-roots in replant Chinese fie woodland. Journal of Chemical Ecology, 2000, 26(9): 2211-2219.
[8] Li X Y, Zheng X F, Zhou J B. Contents and characteristic of organic carbon and nitrogen in wheat rhizosphere with different soil textures. Chinese Journal of Soil Science, 2012, 43(3): 610-613.
李晓月, 郑险峰, 周建斌. 不同质地小麦根际土壤有机碳, 氮含量及特性研究. 土壤通报, 2012, 43(3): 610-613.
[9] Zhang W J, Liao H K, Long J, et al , Effects of Chinese prickly ash orchard on soil organic carbon mineralization and labile organic carbon in Karst Rocky desertification region of Guizhou province. Environmental Science, 2015, 36(3): 1053-1059.
张文娟, 廖洪凯, 龙健, 等. 种植花椒对喀斯特石漠化地区土壤有机碳矿化及活性有机碳的影响. 环境科学, 2015, 36(3): 1053-1059.
[10] Wen Y C, Li Y Q, Yuan L, et al . Comprehensive assessment methodology of characteristics of soil fertility under different fertilization regimes in North China. Ransactions of the Chinese Society of Agricultural Engineering, 2015, 31(7): 91-99.
温延臣, 李燕青, 袁亮, 等. 长期不同施肥制度土壤肥力特征综合评价方法. 农业工程学报, 2015, 31(7): 91-99.
[11] Song X Y, Zhang D J, Zhang J, et al . Effects of gap size in Pinus massoniana plantations on different soil labile organic carbon fractions. Acta Ecologica Sinica, 2015, 35(16): 5393-5402.
宋小艳, 张丹桔, 张健, 等. 马尾松( Pinus massoniana )人工林林窗对土壤不同形态活性有机碳的影响. 生态学报, 2015, 35(16): 5393-5402.
[12] Wu C S, Zhang M K. Effects of long-term different fertilization on carbon, nitrogen and phosphorus pools in tea garden soils. Chinese Journal of Soil Science, 2015, 46(3): 578-583.
吴崇书, 章明奎. 长期不同施肥对茶园土壤碳氮磷构成的影响. 土壤通报, 2015, 46(3): 578-583.
[13] Hu N J, Han X Z, Yang M F, et al . Short-term influence of straw return on the contents of soil organic carbon fractions, enzyme activities and crop yields in rice-wheat rotation farmland. Journal of Plant Nutrition and Fertilizer, 2015, 21(2): 371-377.
胡乃娟, 韩新忠, 杨敏芳, 等. 秸秆还田对稻麦轮作农田活性有机碳组分含量、酶活性及产量的短期效应. 植物营养与肥料学报, 2015, 21(2): 371-377.
[14] Li X B, Fan R X, Liu X D. Advance in studies on carbon storage and carbon process in grassland ecosystem of China. Ecology and Environmental Sciences, 2014, 23(11): 1845-1851.
李学斌, 樊瑞霞, 刘学东. 中国草地生态系统碳储量及碳过程研究进展. 生态环境学报, 2014, 23(11): 1845-1851.
[15] Cheng J M, Jin J W, Tian Y, et al . Distribution characteristics of vegetation and soil carbon density of different forests in Ningxia. Transactions of the Chinese Society of Agricultural Engineering, 2016, 32(13): 109-117.
程积民, 金晶炜, 田瑛, 等. 宁夏森林植被及土壤碳密度分布特征. 农业工程学报, 2016, 32(13): 109-117.
[16] Liu W, Cheng J M, Gao Y, et al . Distribution of organic carbon in grassland on loessplateau and its influencing factors. Acta Pedologica Sinica, 2012, 49(1): 68-76.
刘伟, 程积民, 高阳, 等. 黄土高原草地土壤有机碳分布及其影响因素. 土壤学报, 2012, 49(1): 68-76.
[17] Xu M G, Yu R, Sun X F, et al . Effects of long-term fertilization on labile organic matter and carbon management index (CMI) of the typical soils of China. Plant Nutrition and Fertilizer Science, 2006, 12(4): 459-465.
徐明岗, 于荣, 孙小凤, 等. 长期施肥对我国典型土壤活性有机质及碳库管理指数的影响. 植物营养与肥料学报, 2006, 12(4): 459-465.
[18] Shi W M, Wang X C, Yan W D. Distribution patterns of available P and K in rape rhizosphere in relation to genotypic difference. Plant and Soil, 2004, 261(12): 11-16.
[19] Shao X Q, Shen Y Y, Wang K. Effects of conservation tillage on the photosynthesis, transpiration and water use efficiency of summer sown Glucine max. Acta Prataculturae Sinica, 2006, 15(6): 82-86.
邵新庆, 沈禹颖, 王堃. 水土保持耕作对夏种大豆光合, 蒸腾及水分利用效率的影响. 草业学报, 2006, 15(6): 82-86.
[20] Sun X L, Kang S R L, Zhang Q, et al . Relationship between species diversity, productivity, climatic factors and soil nutrients in the desert steppe. Acta Prataculturae Sinica, 2015, 24(12): 10-19.
孙小丽, 康萨如拉, 张庆, 等. 荒漠草原物种多样性、生产力与气候因子和土壤养分之间关系的研究. 草业学报, 2015, 24(12): 10-19.
[21] An S S, Huang Y M. Study on the ameliorate benefits of Caragana korshinskii shrub wood to soil properties in loess hilly area. Scientia Silvae Sinicae, 2006, 42(1): 70-75.
安韶山, 黄懿梅. 黄土丘陵区柠条林改善土壤作用的研究. 林业科学, 2006, 42(1): 70-75.
[22] Ren X, Chu G X, Song R Q, et al , The characteristics of “Fertile Island” on haloxylon ammodendron at an oasis-desert ecotone in the south edge of Junggar basin. Chinese Journal of Soil Science, 2010, 41(1): 100-104.
任雪, 褚贵新, 宋日权, 等. 准噶尔盆地南缘绿洲-荒漠过渡带梭梭“肥岛”效应特征. 土壤通报, 2010, 41(1): 100-104.
[23] Liu R T, Li X B, Xin M, et al , Response of the ground arthropod community to exclosure of desert steppe in semi-arid regions. Acta Prataculturae Sinica, 2012, 21(1): 66-74.
刘任涛, 李学斌, 辛明, 等. 半干旱沙地草场地面节肢动物群落对封育措施的响应. 草业学报, 2012, 21(1): 66-74.
[24] Yang Y, Liu B R, Song N P, et al . The effect of planted Caragana density on the spatial distribution of soil nutrients in desert steppe. Acta Prataculturae Sinica, 2014, 23(5): 107-115.
杨阳, 刘秉儒, 宋乃平, 等. 人工柠条灌丛密度对荒漠草原土壤养分空间分布的影响. 草业学报, 2014, 23(5): 107-115.
[25] Guo Z S. Limit of vegetation rehabilitation for soil and water conservation in semi-arid region of Loess Plateau: A case study of artificial Caragana korshihskii Kom stand. Science of Soil and Water Conservation, 2009, 7(4): 49-54.
郭忠升. 黄土高原半干旱区水土保持植被恢复限度-以人工柠条林为例. 中国水土保持科学, 2009, 7(4): 49-54.
[26] Bi J Q, Du F, Liang Z S, et al . Research on root system of Caragana korshinskii at different site conditions in the hilly regions of loess plateau. Forest Research, 2006, 19(2): 225-230.
毕建琦, 杜峰, 梁宗锁, 等. 黄土高原丘陵区不同立地条件下柠条根系研究. 林业科学研究, 2006, 19(2): 225-230.
[27] Shi Y H, Han J G, Shao X Q, et al . Effects of dairy cows grazing on soil physical and chemical properties of alfalfa grass pasture in agro pastoral transitional zone of north China. Chinese Journal of Grassland, 2007, 29(1): 24-30.
石永红, 韩建国, 邵新庆, 等. 奶牛放牧对人工草地土壤理化特性的影响. 中国草地学报, 2007, 29(1): 24-30.
[28] Rong Y P, Han J G, Wang P, et al . The effects of grazing intensity on soil physics and chemical properties. Grassland of China, 2001, 23(4): 41-47.
戎郁萍, 韩建国, 王培, 等. 放牧强度对草地土壤理化性质的影响. 中国草地, 2001, 23(4): 41-47.
[29] Bastida F, Barber G G, Garca C, et al . Influence of orientation vegetation and seas on soil micro biomass and biochemical characteristics under semiarid conditions. Applied Soil Ecology, 2008, 38(1): 62-70.
[30] Wu J G, Zhang X Q, Xu D Y. Changes in soil labile organic carbon under different land use in the liupan mountain forest zone. Acta Phytoecologica Sinica, 2004, 28(5): 657-664.
吴建国, 张小全, 徐德应. 六盘山林区几种土地利用方式下土壤活性有机碳的比较. 植物生态学报, 2004, 28(5): 657-664.
[31] Yu W T, Zhao X, Ma Q, et al . Effect of long-term fertilization on available carbon pool and carbon pool management index in an aquic brown soil. Chinese Journal of Soil Science, 2008, 39(3): 539-545.
宇万太, 赵鑫, 马强, 等. 长期定位试验下施肥对潮棕壤活性碳库及碳库管理指数的影响. 土壤通报, 2008, 39(3): 539-545.
[32] Luo Y J, Wang Z F, Gao M, et al . Effects of different tillage systems on soil labile organic matter and carbon management index of purple paddy soil. Journal of Soil and Water Conservation, 2007, 21(5): 55-58, 81.
罗友进, 王子芳, 高明, 等. 不同耕作制度对紫色水稻土活性有机质及碳库管理指数的影响. 水土保持学报, 2007, 21(5): 55-58, 81.
[33] Moore J M, Klose S, Tabatabai M A. Soil microbial bio-mass carbon and nitrogen as affected by cropping system. Biology and Fertility of Soils, 2000, 31: 200-210.
[34] Ma M D, Li Q, Luo C D, et al . Study on soil labile organic carbon under some main forest types in Wolong nature reserve, China. Journal of Soil and Water Conservation, 2009, 23(2): 127-131.
马明东, 李强, 罗承德, 等. 卧龙亚高山主要森林植被类型土壤碳汇的研究. 水土保持学报, 2009, 23(2): 127-131.
[35] Jia J J, Li J H, Wang G, et al . Effects of the introduction of legume species on soil nutrients and microbial biomass of abandoned-fields. Journal of Lanzhou University Natural Sciences, 2007, 43(5): 32-36.
贾举杰, 李金花, 王刚, 等. 添加豆科植物对弃耕地土壤养分和微生物量的影响. 兰州大学学报自然科学版, 2007, 43(5): 32-36.
[36] He J S, Bazzaz F A, Schmid B. Interactive effects of diversity, nutrients and elevated CO 2 on experimental plant communities. Oikos, 2002, 97, 337-348.
[37] Wang Y H, Su Y R, Li Y, et al . Response of the turnover of soil organic carbon to the soil moisture in paddy and upland soil. Scientia Agricultura Sinica, 2012, 45(2): 266-274.
王嫒华, 苏以荣, 李杨, 等. 水田和旱地土壤有机碳周转对水分的响应. 中国农业科学, 2012, 45(2): 266-274.
[38] Majumder B, Mandal B, Bandyopadhyay P K, et al . Organic a-mendments influence soil organic carbon pools and rice-wheatproductivity. Soil Science Society of American Journal, 2008, 72: 775-785.
[39] Li Y K, Chen M P, Mei X R, et al . Effects of soil moisture and nitrogen addition on organic carbon mineralization in a high-yield cropland soil of the North China Plain. Acta Ecologica Sinica, 2014, 34(14): 4037-4046.
李银坤, 陈敏鹏, 梅旭荣, 等. 土壤水分和氮添加对华北平原高产农田有机碳矿化的影响. 生态学报, 2014, 34(14): 4037-4046.
[40] Min K, Kang H, Lee D. Effects of ammonium and nitrate additions on carbon mineralization in wetland soils. Soil Biology and Biochemistry, 2011, 43(12): 2461-2469.
[41] Dai W H, Huang Y, Wu L, et al . Relationships between soil organic matter content (SOM) and pH in topsoil of zonal soils in China. Acta Pedologica Sinica, 2009, 46(5): 851-860.
戴万宏, 黄耀, 武丽, 等. 中国地带性土壤有机质含量与酸碱度的关系. 土壤学报, 2009, 46(5): 851-860.
[42] Curtin D, Campbell C A, Jalil A. Effects of acidity on mineralization: pH-dependence of organic matter mineralization in weakly acid soils. Soil Biology and Biochemistry, 1998, 30: 57-64.
[43] Moody P W, Yo S A, Aitken R L. Soil organic carbon, permanganate fractions and the chemical properties of acidic soils. Australian Journal of Soil Research, 1997, 35: 1301-1308.