1、主要知识产权证明目录 [1]授权发明专利,一种草方格造林对植被和土壤特征影响的研究方法,中国, ZL201911323014.6 [2]授权发明专利,A method for studying the eco-stoichiometric characteristics of C,N and P in soil at different altitudes and their microbial driving mechanism,欧洲, LU502734 [3]授权发明专利,一种用于沙地防风固沙绿植栽培装置,中国,ZL202411754920.2 [4]授权发明专利 Monitoring and regulation method for improving soil fertility in desert steppes,欧洲,LU507370 [5]授权发明专利,一种生态保湿固沙植被促长剂及其制备方法,中国,ZL202010295107.9 [6]授权发明专利,一种草原生态修复用种植装置,中国,ZL202510330049.1 [7]授权发明专利,一种用于沙化草地生态修复的播种装置,中国,ZL202411736998.1 [8]授权发明专利, Effects of precipitation and grazing on the diversity and productivity of desert steppe,欧洲,LU507369 [9]实用新型专利,一种采集不同土层土壤种子库样品的装置,中国,ZL202220696462.1 [10]实用新型专利,一种凋落物分解袋,中国,ZL202320393210.6 [11]实用新型专利,一种地表风蚀物分层捕获器,中国,ZL202322581971.7 [12]实用新型专利,一种饲草种植用松土装置,中国,ZL202420339030.4 [13]实用新型专利,一种植物叶片功能性状鉴定装置,中国,ZL202323310163.3 [14]实用新型专利,一种草原土壤筛根装置,中国,ZL202323327670.8 [15]实用新型专利,一种方便操作的草地生态修复装置,中国,ZL202323328046.X [16]计算机软件著作,干旱区退化草地生态修复管控系统V1. 0,中国,2025SR0971867 [17]计算机软件著作,干早区沙地治理综合系统V1.0,中国,2025SR0971878 [18]计算机软件著作,智慧沙质草原生态改良保护管理系统V1. 0,中国,2024SR1863874 [19]计算机软件著作,沙质草原提质增效评价系统V1. 0,中国,2024SR1870029 [20]计算机软件著作,沙质草原碳储存能力动态监测系统V1. 0,中国,2024SR1863884 [21]计算机软件著作,沙质草原生态改良示范区动态监测系统V1.0,中国,2024SR1863893 [22]计算机软件著作,智慧放牧精准定位跟踪平台V1. 0,中国,2025SR0718283 [23]计算机软件著作,智慧放牧远程决策支持软件V1.0,中国,2025SR1266284 [24]中华人民共和国国家标准,家庭牧场草地放牧强度分级,GB/T,34754-2017 [25]中华人民共和国林业行业标准,草畜平衡评价技术规范,LY/T,3320-2022 [26]内蒙古自治区地方标准,混播人工草地放牧利用技术规范,DB15/T,3262—2023 [27]内蒙古自治区地方标准,干旱半干旱区苜蓿保护性耕作技术规程,DB15/T,1090-2017 [28]内蒙古自治区地方标准,典型草原牧草主要病害调查规范,DB15/T,1097-2017 [29]内蒙古自治区地方标准,蒙桑播种育苗技术规程,DB15/T,3102-2023 [30]内蒙古自治区地方标准,内蒙古黄土丘陵区坡面植被修复技术规程,DB15/T,3240-2023 2、代表性论文专著目录 [1]科学出版社,生态环境监测与恢复—以宁夏东部风沙区沙化草地为例,2021,许冬梅, 邱开阳, 王建军 [2]中国农业科学技术出版社,内蒙古荒漠草原放牧响应过程与利用模式应用,2023,孙世贤,殷国梅,卫媛 [3]中国农业科学技术出版社,内蒙古高原荒漠草原野生种子植物图谱,2021,张璞进,晔薷罕 [4]中国农业科学技术出版社,草地与放牧家畜管理技术,2025,屈志强,张彬,王静 [5]中国农业科学技术出版社,草地与放牧家畜管理技术,2025,屈志强、张彬、王静、李治国 [6]中国农业科学技术出版社,内蒙古高原荒漠草原野生种子植物图谱,2021,张璞进、晔薷罕、清华、赵利清、木兰、支尚文、白其格那、任瑾涛、伊风艳、朱蔚娜、张国龙、张艳丽、金正亮、罗洪涛、单玉梅、宝文智、温超、樊文涛 [7]Journal of Environmental Management,Atmospheric dryness thresholds of grassland productivity decline in China , 2023, He, P; Han, Z; Sun, Z [8]Ecological Indicators, Spatiotemporal evolutionary and mechanism analysis of grassland GPP in China, 2022, He, P; Ma, X; Meng, X. [9]Environmental Research Letters, Compound drought constrains gross primary productivity in Chinese grasslands, 2022, He, P; Ma, X; Sun, Z. [10]Frontiers in Plant Science, Ecological dichotomies of solar energy expansion: resilience in arid regions versus fragility in humid ecosystems, 2025, Xiao, J; He, P; Li, Y. [11]Microbial Ecology, High-throughput absolute quantification sequencing reveals that combination of leguminous shrub is effective in driving soil bacterial diversity during the process of desertification reversal, 2023, Liu, W; Qiu, K; Xie, Y. [12]Scientific Reports, Ecosystem functions including soil organic carbon, total nitrogen and available potassium are crucial for vegetation recovery, 2018, Qiu, K; Xie, Y; Xu, D. [13]LAND DEGRADATION & DEVELOPMENT, Effects of precipitation and grazing on the diversity and productivity of desert steppe, 2023, Ye, R., Yu, W., Yang, D. [14]LAND DEGRADATION & DEVELOPMENT, Grazing effects on total carbon and nitrogen content of wind- eroded soils in desert steppe, 2023, Zhang, B.; Qu, Z; Lv, S. [15]Frontiers in Environmental Science, The Branching Architecture of Artemisia Ordosica and Its Resistance to Wind Erosion, 2022, Qu, Z.; Li, Z.; Hu, L. [16]Agronomy, Desertification Reversal Promotes the Complexity of Plant Community by Increasing Plant Species Diversity of Each Plant Functional Type, 2024, Qiu, K; Li, Z; Xie, Y. [17]Global Ecology and Conservation, Response of plant traits of Stipa breviflora to grazing intensity and fluctuation in annual precipitation in a desert steppe, northern China, 2020, Ye, R., Liu, G., Chang, H. [18]PeerJ, Years of sand fixation with Caragana korshinskii drive the enrichment of its rhizosphere functional microbes by accumulating soil N, 2022, Liu, W; Qiu, K; Xie, Y. [19]Frontiers of Earth Science, Combining gradual and abrupt analysis to detect variation of vegetation greenness on the loess areas of China, 2022, He, P; Sun, Z; Xu, D. [20]Brazilian Journal of Botany, Photosynthesis-related properties are affected by desertification reversal and associated with soil N and P availability, 2018, Qiu, K; Xie, Y; Xu, D. [21]生态学报, 宁夏东部风沙区沙化草地土壤水分和植被的空间特征, 2022, 郭艳菊; 马晓静; 许爱云 [22]中国草地学报, 不同补播模式对荒漠草原土壤团聚体稳定性的影响, 2019, 时龙; 郭艳菊; 于双 [23]草业学报, 不同固沙植被恢复模式对土壤理化性质、酶活性和草本植物多样性的影响, 2025, 马玉龙; 邱开阳; 骆欣怡 [24]草业学报, 不同恢复措施对宁夏荒漠草原土壤碳氮储量的影响, 2019, 于双; 许冬梅; 许爱云 [25]草地学报, 氮磷添加对宁夏荒漠草原植物物种多样性和群落稳定性的影响, 2025, 杨云涛; 邱开阳; 王玉娟 [26]草地学报, 不同放牧强度对荒漠草原草地微斑块特征的影响, 2024, 屈志强; 孙雪岩; 杨子琼 [27]草地学报, 基于遥感影像的和林格尔黄土丘陵区治理成效分析, 2023, 屈志强; 韩国栋; 铁英 [28]草地学报, 毛乌素沙地南缘不同固沙灌木下土壤养分的空间异质性, 2021, 赵朋波; 邱开阳; 谢应忠 [29]草地学报, 补播对退化荒漠草原土壤有机碳及其分布的影响, 2019, 郭艳菊; 马晓静; 于双 [30]生态科学, 宁夏东部杨柴生态修复区短期水氮添加对草本植物群落的影响, 2024, 苗虎; 邱开阳; 苏云 [31]草业科学, 毛乌素沙地南缘不同固沙灌木群落土壤质量评价, 2022, 何毅; 邱开阳; 苏云 [32]草原与草坪, 毛乌素沙地南缘柠条固沙恢复区植物多样性及生物量对水氮添加的响应, 2022, 李亚园; 邱开阳; 何毅 [33]草原与草坪, 固沙灌木配置模式对宁夏东部风沙区土壤生态化学计量特征的影响, 2022,李海泉; 邱开阳; 谢应忠 [34]畜牧与饲料科学, 草地生态系统土壤与植被对极端干旱的响应研究进展, 2024, 晔薷罕; 希吉日塔娜; 常虹 [35]畜牧与饲料科学, 毛乌素沙化草地植被群落特征及物种多样性对不同生态修复措施的响应, 2022, 殷国梅; 冀超; 刘思博 [36]畜牧与饲料科学, 降水、氮沉降及放牧对草地生态系统凋落物分解的影响研究进展 , 2021, 晔薷罕; 萨茹拉其其格; 温超 [37]畜牧与饲料科学, 不同修复措施在退化荒漠草原生态修复中的效果研究, 2021, 殷国梅; 镡建国; 王晓栋 | 