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马林


        马林,中国科学院遗传与发育生物学研究所农业资源研究中心研究员,博士生导师,科技部“中青年科技创新领军人才”入选者,中科院“高层次人才计划”终期评估优秀。



研究领域
        养分资源管理和农业生态学。
 
研究内容
        “食物-环境-资源”耦合与调控机制研究小组Coupling of Food, Environmental protection and Resource use (COFER)。具体研究包括:
        可持续食物链系统养分资源管理研究;
        农牧系统面源污染机理与防控途径研究;
        农牧生产系统废弃物循环关键过程机理和技术研究。
 
学术兼职
        农业部科学施肥专家指导组专家
        国家畜禽养殖废弃物资源化处理科技创新联盟专家委员会专家
        河北省奶牛体系-绿色发展与废弃物资源化利用岗位科学家
        中国自然资源学会农业资源利用专业委员会副主任
        河北省果菜有机肥替代化肥行动专家组副组长
        河北省青年科技工作者协会副会长
        河北省农业系统工程学会理事
        河北省土壤生态学重点实验室副主任
 
研究业绩
        在食物链和农牧系统养分高效利用理论与废弃物养分资源化利用技术方面取得了系统的创新性成果,研究结果先后发表在Nature Food、Nature Sustainability、Nature Communications、Science Advances、Global Change Biology、Environmental Science and Technology等环境和农业类刊物上。近年来发表学术论文100余篇。主持和参与国家重点研发计划项目、国家自然科学基金项目等10余项。主要研究成果包括:(1)提出了食物链养分流动金字塔理论,构建了食物链和农牧系统养分流动模型(NUFER),为实现食物链和农牧系统可持续发展研究提供了创新方法。(2)阐明了我国农牧系统和食物链氮磷流量、利用效率和环境排放的时空分异特征,为优化我国农牧系统养分管理提供了理论依据。揭示了我国“饲料–粪尿排泄–饲舍–储藏–处理–施用”全链条养分流动特征,研究发现饲舍和储藏环节是氮素环境排放的主要环节,农牧结合和粪尿资源化利用是大幅度减少化肥施用和环境排放的关键途径。(3)探索了畜禽粪尿资源化的技术途径,研发了智能堆肥反应器,将储存和处理合二为一,实现畜禽粪尿快速无害化、资源化和氨气减排。在禽养殖废弃物资源化利用技术与模式方面上取得了重要进展,研究成果被中央电视台科教频道《科技之光》栏目以《点废成金》为题进行了专题报道(播放链接:http://tv.cctv.com/2018/03/06/VIDE5xVbFymvz0S7CDHK4pfW180306.shtml);被中央电视台科教频道《创新进行时》栏目以《养鸡场里的危机》为题进行了专题报道(播放链接:https://tv.cctv.com/2020/01/13/VIDEZfiR92BTlDLdCDB4bY9G200113.shtml、https://tv.cctv.com/2020/01/14/VIDEfAuc0XpORuH01LjZcLhG200114.shtml?spm=C53121759377.PvNzMjwOU8x4.Ezufm7A0dzE0.62);

代表论著:
2022
1) Bai, Z*., Fan, X., Jin, X., Zhao, Z., Wu, Y., Oenema, O., Velthof, G., Hu, C., Ma, L*., 2022. Relocate 10 billion livestock to reduce harmful nitrogen pollution exposure for 90% of China’s population. Nature Food 3, 152-160.
2) Wang, M*., Janssen, A.B.G., Bazin, J., Strokal, M., Ma, L*., Kroeze, C., 2022. Accounting for interactions between Sustainable Development Goals is essential for water pollution control in China. Nat Commun 13, 730.
3) Chen, X*., Strokal, M., van Vliet, M.T.H., Fu, X., Wang, M., Ma, L*, Kroeze, C., 2022. In-stream surface water quality in China: A spatially-explicit modelling approach for nutrients. Journal of Cleaner Production 334(16), 130208.
4) Li, Y*., Wang, M., Chen, X., Cui, S., Hofstra, N., Kroeze, C., Ma, L., Xu, W*., Zhang, Q., Zhang, F., Strokal, M., 2022. Multi-pollutant assessment of river pollution from livestock production worldwide. Water Res 209, 117906.
5) Liu, Z., Wang, X., Li, S., Bai, Z., Ma, L*., 2022. Advanced composting technologies promotes environmental benefits and eco-efficiency: a life cycle assessment. Bioresour Technol 346, 126576.
6) Cao, Y., Wang, X., Zhang, X., Misselbrook, T.H., Bai, Z., Wang, H., Ma, L*., 2022. The effects of electric field assisted composting on ammonia and nitrous oxide emissions varied with different electrolytes. Bioresour Technol 344, 126194.
7) Yang, J., Strokal, M., Kroeze, C., Ma, L*., Bai, Z., Teurlincx, S., Janssen, A.B.G., 2022. What is the pollution limit? Comparing nutrient loads with thresholds to improve water quality in Lake Baiyangdian. Sci Total Environ 807, 150710.
8) Chen, X., Wang, Y., Bai, Z., Ma, L., Strokal, M., Kroeze, C., Chen, X., Zhang, F., Shi, X*., 2022. Mitigating phosphorus pollution from detergents in the surface waters of China. Sci Total Environ 804, 150125.
9) Ma, Y., Hou, Y*., Dong, P., Velthof, G.L., Long, W., Ma, L., Ma, W., Jiang, R., Oenema, O., 2022. Cooperation between specialized livestock and crop farms can reduce environmental footprints and increase net profits in livestock production. J Environ Manage 302, 113960.
10) Meng, F., Wang, M*., Strokal, M., Kroeze, C., Ma, L., Li, Y., Zhang, Q., Wei, Z., Hou, Y., Liu, X., Xu, W., Zhang, F., 2022. Nitrogen losses from food production in the North China Plain: A case study for Quzhou. Sci Total Environ,816, 151557.
11) Xu, P., Li, G., Houlton, B.Z., Ma, L., Ai, D., Zhu, L., Luan, B., Zhai, S., Hu, S., Chen, A., Zheng, Y*., 2022. Role of Organic and Conservation Agriculture in Ammonia Emissions and Crop Productivity in China. Environ Sci Technol.
 
2021
12) Zhao, H., Chang, J., Havlík, P*., van Dijk, M., Valin, H., Janssens, C., Ma, L*., Bai, Z., Herrero, M., Smith, P., Obersteiner, M., 2021. China’s future food demand and its implications for trade and environment. Nature Sustainability 4, 1042-1051.
13) Bai, Z., Ma, W., Zhao, H., Guo, M., Oenema, O., Smith, P., Velthof, G., Liu, X., Hu, C., Wang, P., Zhang, N., Liu, L., Guo, S., Fan, X., Winiwarter, W., Ma, L*., 2021. Food and feed trade has greatly impacted global land and nitrogen use efficiencies over 1961–2017. Nature Food 2, 780-791.
14) Bai, Z., Jin, X., Oenema, O., Lee, M.R.F., Zhao, J*., Ma, L*., 2021. Impacts of African swine fever on water quality in China. Environmental Research Letters 16, 054032.
15) Bai, Z., Wang, X., Wu, X., Wang, W., Liu, L., Zhang, X., Fan, X., Ma, L*., 2021. China requires region-specific manure treatment and recycling technologies. Circular Agricultural Systems 1, 1-8.
16) Cao, Y., Wang, X., Zhang, X., Misselbrook, T., Bai, Z., Ma, L*., 2021. An electric field immobilizes heavy metals through promoting combination with humic substances during composting. Bioresour Technol 330, 124996.
17) Cao, Y., Wang, X., Zhang, X., Misselbrook, T., Bai, Z., Ma, L*., 2021. Nitrifier denitrification dominates nitrous oxide production in composting and can be inhibited by a bioelectrochemical nitrification inhibitor. Bioresour Technol 341, 125851.
18) Jin, X., Zhang, N., Zhao, Z., Bai, Z*., Ma, L., 2021. Nitrogen budgets of contrasting crop-livestock systems in China. Environ Pollut 288, 117633.
19) Wang, X*., Ledgard, S., Luo, J., Chen, Y., Tian, Y., Wei, Z., Liang, D., Ma, L*., 2021. Life cycle assessment of alfalfa production and potential environmental improvement measures in Northwest China. Journal of Cleaner Production 304, 127025.
20) Wang, H., Zhao, Z., Winiwarter, W., Bai, Z., Wang, X., Fan, X., Zhu, Z., Hu, C., Ma, L*., 2021. Strategies to reduce ammonia emissions from livestock and their cost-benefit analysis: A case study of Sheyang county. Environ Pollut 290, 118045.
21) Li, S., Wu, J., Ma, L*., 2021. Economic, energy and environmental consequences of shifting from maize-wheat to forage rotation in the North China Plain. Journal of Cleaner Production 328, 129670.
22) Yang, J., Strokal, M., Kroeze, C., Chen, X., Bai, Z., Li, H., Wu, Y., Ma, L*., 2021. Seasonal River Export of Nitrogen to Guanting and Baiyangdian Lakes in the Hai He Basin. Journal of Geophysical Research: Biogeosciences 126.
23) Zhang, N., Bai, Z., Ledgard, S., Luo, J., Ma, L*. 2021. Ammonia mitigation effects from the cow housing and manure storage chain on the nitrogen and carbon footprints of a typical dairy farm system on the North China Plain. Journal of Cleaner Production 280, 124465.
24) Guo, C., Bai, Z., Shi, X., Chen, X., Chadwick, D., Strokal, M., Zhang, F., Ma, L., Chen, X*., 2021. Challenges and strategies for agricultural green development in the Yangtze River Basin. Journal of Integrative Environmental Sciences 18, 37-54.
25) Li, A., Yuan, Q*., Strokal, M., Kroeze, C., Ma, L., Liu, Y., 2021. Equality in river pollution control in China. Science of The Total Environment 777.
26) Liu, B., Wang, X., Ma, L., Chadwick, D., Chen, X*., 2021. Combined applications of organic and synthetic nitrogen fertilizers for improving crop yield and reducing reactive nitrogen losses from China’s vegetable systems: A meta-analysis. Environ Pollut 269, 116143.
27) Strokal, M*., Bai, Z., Franssen, W., Hofstra, N., Koelmans, A.A., Ludwig, F., Ma, L., van Puijenbroek, P., Spanier, J.E., Vermeulen, L.C., van Vliet, M.T.H., van Wijnen, J., Kroeze, C., 2021. Urbanization: an increasing source of multiple pollutants to rivers in the 21st century. npj Urban Sustainability24, 1.
28) Strokal, M*., Janssen, A.B.G., Chen, X., Kroeze, C., Li, F., Ma, L., Yu, H., Zhang, F., Wang, M., 2021. Green Agriculture and Blue Water in China: Reintegrating Crop and Livestock Production for Clean Water. Frontiers of Agricultural Science and Engineering 8(1): 72–80.
29) Zhang, Q., Li, Y., Wang, M., Wang, K., Meng, F., Liu, L., Zhao, Y., Ma, L., Zhu, Q., Xu, W*., Zhang, F., 2021. Atmospheric nitrogen deposition: A review of quantification methods and its spatial pattern derived from the global monitoring networks. Ecotoxicol Environ Saf 216, 112180.
30) Zhou, J., Jiao, X., Ma, L., de Vries, W., Zhang, F., Shen, J*., 2021. Model-based analysis of phosphorus flows in the food chain at county level in China and options for reducing the losses towards green development. Environ Pollut 288, 117768.
31) 马林,王洪媛,刘刚,胡克林,梁超,杜连凤,郭胜利,柏兆海,王凤花,李晓欣,王仕琴,胡春胜*.中国北方农田氮磷淋溶损失污染与防控机制[J].中国生态农业学报(中英文),2021,29(01):1-10.
32) 金欣鹏,柏兆海,马林*.基于养分损失脆弱区的氮磷淋溶分区消减策略[J].中国生态农业学报(中英文),2021,29(01):217-229.
33) 李硕,李晓欣,赵善丽,郝曼,柏兆海,马林*.华北平原有机肥替代化肥条件下“粮-饲”轮作系统氮素表观平衡研究[J/OL].农业环境科学学报, 2021, 1-15
34) 张陆,曹玉博,王惟帅,张新媛,王选,姚培清,刘双,王红,马林*.鸡粪添加对蔬菜废弃物堆肥腐殖化过程的影响[J].中国生态农业学报(中英文):2021,1-11.
35) 王洪媛,李俊改,樊秉乾,骆晓声,彭畅,翟丽梅,李虎,马林,刘宏斌*.中国北方主要农区农田氮磷淋溶特征与时空规律[J].中国生态农业学报(中英文),2021,29(01):11-18.
36) 李晓欣,王仕琴,陈肖如,雷玉平,高鹏程,胡春胜*,马林.北方区域尺度地下水-包气带硝酸盐分布与变化特征[J].中国生态农业学报(中英文),2021,29(01):208-216.
37) 王仕琴*,檀康达,郑文波,马林,宋献方,唐常源,胡春胜.白洋淀流域浅层地下水硝酸盐分布及来源的区域分异特征[J].中国生态农业学报(中英文),2021,29(01):230-240.
38) 刘学军*,沙志鹏,宋宇,董红敏,潘月鹏,高志岭,李玉娥,马林,董文旭,胡春胜,王文林,王悦,耿红,郑云昊,顾梦娜.我国大气氨的排放特征、减排技术与政策建议[J].环境科学研究,2021,34(01):149-157.
39) 韩婉雪,王凤花*,柏兆海,李文彦,王新珍,马林.畜禽粪便堆放地土壤中抗生素抗性基因和细菌群落的垂直分布特征[J].中国生态农业学报(中英文):2021,1-9.
2020
40) Bai, Z., Schmidt-Traub, G., Xu, J., Liu, L., Jin, X., Ma, L*., 2020. A food system revolution for China in the post-pandemic world. Resour. Environ. Sustain. 2, 100013.
41) Wang, M*., Kroeze, C., Strokal, M., van Vliet, M.T.H., Ma, L*., 2020. Global Change Can Make Coastal Eutrophication Control in China More Difficult. Earth’s Futur. 8, 1–19.
42) Chen, X, Strokal, M., Kroeze, C., Supit, I., Wang, M., Ma, L., Chen, X., Shi, X*., 2020. Modeling the Contribution of Crops to Nitrogen Pollution in the Yangtze River. Environ. Sci. Technol. 54, 11929–11939.
43) Strokal, M*., Kahil, T*., Wada, Y., Albiac, J., Bai, Z., Ermolieva, T., Langan, S., Ma, L., Oenema, O., Wagner, F., Zhu, X., Kroeze, C., 2020. Cost-effective management of coastal eutrophication: A case study for the yangtze river basin. Resour. Conserv. Recycl. 154, 104635.
44) Liu, L., Guo, Y., Tu, Y., Zhang, N., Bai, Z*., Chadwick, D., Dou, Z., Ma, L*., 2020. A higher water-soluble phosphorus supplement in pig diet improves the whole system phosphorus use efficiency. J. Clean. Prod. 272, 122586.
45) Cao, Y., Wang, X., Liu, L., Velthof, G.L., Misselbrook, T., Bai, Z., Ma, L*., 2020. Acidification of manure reduces gaseous emissions and nutrient losses from subsequent composting process. J. Environ. Manage. 264, 110454.  
46) Cao, Y., Bai, Z., Misselbrook, T., Wang, X., Ma, L*., 2021. Ammonia emissions from different pig production scales and their temporal variations in the North China Plain. J. Air Waste Manag. Assoc. 71, 23–33.
47) Ma, C., Strokal, M., Kroeze, C., Wang, M., Li, X., Hofstra, N., Ma, L*., 2020. Reducing river export of nutrients and eutrophication in Lake Dianchi in the future. Blue-Green Syst. 2, 73–90.
48) Li, S., Wu, J., Wang, X., Ma, L*., 2020. Economic and environmental sustainability of maize-wheat rotation production when substituting mineral fertilizers with manure in the North China Plain. J. Clean. Prod. 271, 122683.
49) Chen, X*., Strokal, M., Van Vliet, M.T.H., Stuiver, J., Wang, M., Bai, Z., Ma, L*., Kroeze, C., 2019. Multi-scale Modeling of Nutrient Pollution in the Rivers of China. Environ. Sci. Technol. 53, 9614–9625.
50) Jin, X., Bai, Z*., Oenema, O., Winiwarter, W., Velthof, G., Chen, X., Ma, L*., 2020. Spatial Planning Needed to Drastically Reduce Nitrogen and Phosphorus Surpluses in China’s Agriculture. Environ. Sci. Technol. 54, 11894–11904.
51) Chadwick, D.R*., Williams, J.R., Lu, Y., Ma, L., Bai, Z., Hou, Y., Chen, X., Misselbrook, T.H., 2020. Strategies to reduce nutrient pollution from manure management in China. Front. Agric. Sci. Eng. 7, 45–55.
52) Liu, Z., Wang, X., Wang, F., Bai, Z., Chadwick, D., Misselbrook, T., Ma, L*., 2020. The progress of composting technologies from static heap to intelligent reactor: Benefits and limitations. J. Clean. Prod. 270, 122328.
53) Guo, Y., Chen, Y., Searchinger, T.D., Zhou, M., Pan, D., Yang, J., Wu, L., Cui, Z., Zhang, W., Zhang, F., Ma, L., Sun, Y., Zondlo, M.A., Zhang, L*., Mauzerall, D.L*., 2020. Air quality, nitrogen use efficiency and food security in China are improved by cost-effective agricultural nitrogen management. Nat. Food 1, 648–658.
54) Zhang, Q., Chu, Y., Xue, Y., Ying, H., Chen, X., Zhao, Y., Ma, W., Ma, L., Zhang, J., Yin, Y., Cui, Z*., 2020. Outlook of China’s agriculture transforming from smallholder operation to sustainable production. Glob. Food Sec 26, 100444.
55) Winiwarter, W*., Amon, B., Bai, Z., Greinert, A., Kaltenegger, K., Ma, L., Myszograj, S., Schneidergruber, M., Suchowski-Kisielewicz, M., Wolf, L., Zhang, L., Zhou, F., 2020. Urban nitrogen budgets: flows and stock changes of potentially polluting nitrogen compounds in cities and their surroundings–a review. J. Integr. Environ. Sci. 17, 57–71.
56) 曹玉博,张陆,王选,马林*.畜禽废弃物堆肥氨气与温室气体协同减排研究[J].农业环境科学学报,2020,39(04):923-932.
57) 宋晨阳,张建杰,刘玲,马文奇,马林,丁尚,赵洪伟*.海南岛农业绿色发展指标时空变化特征[J].中国生态农业学报(中英文),2020,28(08):1156-1167.
58) 李雨濛,张建杰,崔石磊,马林,马文奇,魏静*.河北省县域农业绿色发展指标时空变化特征[J].中国生态农业学报(中英文),2020,28(08):1168-1180.
59) 刘泽龙,王选,曹玉博,马林*.立式筒仓反应器堆肥技术工艺优化研究[J].中国生态农业学报(中英文),2020,28(12):1979-1989.
60) 马文奇,马林,张建杰,张福锁.农业绿色发展理论框架和实现路径的思考[J].中国生态农业学报(中英文),2020,28(08):1103-1112.
61) 金欣鹏,马林*,张建杰,马文奇,张福锁.农业绿色发展系统研究思路与定量方法[J].中国生态农业学报(中英文),2020,28(08):1127-1140.
62) 高巍,张建杰,张艳舫,张楠楠,王选,柏兆海,马文奇,马林*.中国奶业全产业链绿色发展指标的时空变化特征[J].中国生态农业学报(中英文),2020,28(08):1181-1199.
63) 崔石磊,张建杰,佟丙辛,马林,马文奇*.中国农业绿色发展相关氮素指标的时空变化特征[J].中国生态农业学报(中英文),2020,28(08):1141-1155.
64) 张建杰,崔石磊,马林,孟凡磊,宋晨阳,李雨濛,马文奇*.中国农业绿色发展指标体系的构建与例证[J].中国生态农业学报(中英文),2020,28(08):1113-1126.
65) Dorris Chebeth,柏兆海,马林*.肯尼亚和中国农业资源投入与农业单产水平变化(英文)[J].中国生态农业学报(中英文),2020,28(06):900-909.
66) 吕雪梅, 曾阳, 田世丽, 孙杰, 张国忠, 黄威, 顾梦娜, 许稳, 刘学军, 董红敏, 马林, 程一松, 胡春胜, 吴电明, 潘月鹏*. 华北典型农田和畜禽场环境大气中活性氮化学组成和浓度变化特征[J]. 中国生态农业学报(中英文), 2020, 28(7):1043-1050.
2019
67) Zhao, J*., Bai, Z., Ma, L., 2019. China needs long-term solutions for African Swine Fever. Sci. Bull. 64, 1469–1471.
68) Bai, Z., Jin, S., Wu, Y., Ermgassen, E. zu, Oenema, O., Chadwick, D., Lassaletta, L., Velthof, G., Zhao, J*., Ma, L*., 2019. China’s pig relocation in balance. Nat. Sustain. 2, 888.
69) Guo, Y.Q., Tong, B.X., Wu, Z.G., Ma, W.Q., Ma, L*., 2019. Dietary manipulation to reduce nitrogen and phosphorus excretion by dairy cows. Livest. Sci. 228, 61–66.
70) Bai, Z., Winiwarter, W., Klimont, Z., Velthof, G., Misselbrook, T., Zhao, Z., Jin, X., Oenema, O., Hu, C*., Ma, L*., 2019. Further Improvement of Air Quality in China Needs Clear Ammonia Mitigation Target. Environ. Sci. Technol. 53, 10542–10544.
71) Li, A*., Strokal, M., Bai, Z., Kroeze, C., Ma, L*., 2019. How to avoid coastal eutrophication - a back-casting study for the North China Plain. Sci. Total Environ. 692, 676–690.
72) Cao, Y., Wang, X., Bai, Z., Chadwick, D., Misselbrook, T., G. Sommer, S., Qin, W., Ma, L*., 2019. Mitigation of ammonia, nitrous oxide and methane emissions during solid waste composting with different additives: A meta-analysis. J. Clean. Prod. 235, 626–635.  
73) Lu, J., Bai, Z., Chadwick, D., Velthof, G.L., Zhao, H., Li, X., Hu, C., Ma, L*., 2019. Mitigation options to reduce nitrogen losses to water from crop and livestock production in China. Curr. Opin. Environ. Sustain. 40, 95–107.  
74) Chen, X*., Strokal, M., Van Vliet, M.T.H., Stuiver, J., Wang, M., Bai, Z., Ma, L*., Kroeze, C., 2019. Multi-scale Modeling of Nutrient Pollution in the Rivers of China. Environ. Sci. Technol. 53, 9614–9625.
75) Zhang, N., Bai, Z., Winiwarter, W., Ledgard, S., Luo, J., Liu, J., Guo, Y., Ma, L*., 2019. Reducing ammonia emissions from dairy cattle production via cost-effective manure management techniques in China. Environ. Sci. Technol. 53, 11840–11848.
76) Liu, L., Guo, Y., Bai, Z*., Cao, Y., Tu, Y., Wang, Z., Li, Y., Wu, Z., Ma, L*., 2019. Reducing phosphorus excretion and loss potential by using a soluble supplement source for swine and poultry. J. Clean. Prod. 237, 117654.  
77) Bai, Z., Zhao, J., Wei, Z., Jin, X., Ma, L*., 2019. Socio-economic drivers of pig production and their effects on achieving sustainable development goals in China. J. Integr. Environ. Sci. 16, 141–155.
78) Li, A*., Kroeze, C., Kahil, T., Ma, L., Strokal, M., 2019. Water pollution from food production: lessons for optimistic and optimal solutions. Curr. Opin. Environ. Sustain. 40, 88–94.
79) Ma, L*., Bai, Z., Ma, W., Guo, M., Jiang, R., Liu, J., Oenema, O., Velthof, G.L., Whitmore, A.P., Crawford, J., Dobermann, A., Schwoob, M., Zhang, F., 2019. Exploring Future Food Provision Scenarios for China. Environ. Sci. Technol. 53, 1385–1393.
80) Zhao, Z., Qin, W., Bai, Z., Ma, L*., 2019. Agricultural nitrogen and phosphorus emissions to water and their mitigation options in the Haihe Basin, China. Agric. Water Manag. 212, 262–272.  
81) Lu, J., Bai, Z., Velthof, G.L., Wu, Z., Chadwick, D., Ma, L*., 2019. Accumulation and leaching of nitrate in soils in wheat-maize production in China. Agric. Water Manag. 212, 407–415.
82) Yang, J., Strokal, M., Kroeze, C., Wang, M., Wang, J., Wu, Y., Bai, Z., Ma, L*., 2019. Nutrient losses to surface waters in Hai He basin: A case study of Guanting reservoir and Baiyangdian lake. Agric. Water Manag. 213, 62–75.
83) Wang, M*., Strokal, M., Burek, P., Kroeze, C., Ma, L*., Janssen, A.B.G., 2019. Excess nutrient loads to Lake Taihu: Opportunities for nutrient reduction. Sci. Total Environ. 664, 865–873.
84) Li, X., Janssen, A.B.G., de Klein, J.J.M., Kroeze, C., Strokal, M., Ma, L., Zheng, Y*., 2019. Modeling nutrients in Lake Dianchi (China) and its watershed. Agric. Water Manag. 212, 48–59.
85) Ledgard, S.F*., Wei, S., Wang, X., Falconer, S., Zhang, N., Zhang, X., Ma, L., 2019. Nitrogen and carbon footprints of dairy farm systems in China and New Zealand, as influenced by productivity, feed sources and mitigations. Agric. Water Manag. 213, 155–163.
86) Chen, X, Strokal, M., Kroeze, C., Ma, L., Shen, Z., Wu, J., Chen, Xinping, Shi, X*., 2019. Seasonality in river export of nitrogen: A modelling approach for the Yangtze River. Sci. Total Environ. 671, 1282–1292.
87) 刘娟,柏兆海,曹玉博,张楠楠,赵占轻,马林*.家畜圈舍粪尿表层酸化对氨气排放的影响[J].中国生态农业学报(中英文),2019,27(05):677-685.
88) 李硕,王选,张西群,刘泽龙,赵浩,赵占轻,张玉铭,孙宏勇,马林*.猪场肥水施用对玉米-小麦农田氨排放、氮素利用与表观平衡的影响[J].中国生态农业学报(中英文),2019,27(10):1502-1514.
2018
89) Bai, Z., Ma, W., Ma, L*., Velthof, G.L., Wei, Z., Havlík, P., Oenema, O., Lee, M.R.F., Zhang, F., 2018. China’s livestock transition: Driving forces, impacts, and consequences. Sci. Adv. 4, 1–12.  
90) Bai, Z., Lee, M.R.F., Ma, L*., Ledgard, S., Oenema, O., Velthof, G.L., Ma, W., Guo, M., Zhao, Z., Wei, S., Li, S., Liu, X., Havlík, P., Luo, J., Hu, C., Zhang, F., 2018. Global environmental costs of China’s thirst for milk. Glob. Chang. Biol. 24, 2198–2211.
91) Bai, Z., Lu, J., Zhao, H., Velthof, G.L., Oenema, O., Chadwick, D., Williams, J.R., Jin, S., Liu, H., Wang, M., Strokal, M., Kroeze, C., Hu, C., Ma, L*., 2018. Designing Vulnerable Zones of Nitrogen and Phosphorus Transfers to Control Water Pollution in China. Environ. Sci. Technol. 52, 8987–8988.
92) Wang, M*., Ma, L*., Strokal, M., Ma, W., Liu, X., Kroeze, C., 2018. Hotspots for Nitrogen and Phosphorus Losses from Food Production in China: A County-Scale Analysis. Environ. Sci. Technol. 52, 5782–5791.  
93) Wang, X, Bai, Z., Yao, Y., Gao, B., Chadwick, D., Chen, Q., Hu, C., Ma, L*., 2018. Composting with negative pressure aeration for the mitigation of ammonia emissions and global warming potential. J. Clean. Prod. 195, 448–457.
94) Wei, S., Bai, Z., Chadwick, D., Hou, Y., Qin, W., Zhao, Z.Q., Jiang, R *., Ma, L*., 2018. Greenhouse gas and ammonia emissions and mitigation options from livestock production in peri-urban agriculture: Beijing – A case study. J. Clean. Prod. 178, 515–525.  
95) Wang, X, Ledgard, S., Luo, J., Guo, Y., Zhao, Z., Guo, L., Liu, S., Zhang, N., Duan, X., Ma, L*., 2018. Environmental impacts and resource use of milk production on the North China Plain, based on life cycle assessment. Sci. Total Environ. 625, 486–495.  
96) Wei, S., Bai, Z, Qin, W., Wu, Z.G., Jiang, R *., Ma, L*., 2018. Nutrient use efficiencies, losses, and abatement strategies for peri-urban dairy production systems. J. Environ. Manage. 228, 232–238.  
97) Wang, M*., Ma, L*., Strokal, M., Chu, Y., Kroeze, C., 2018. Exploring nutrient management options to increase nitrogen and phosphorus use efficiencies in food production of China. Agric. Syst. 163, 58–72.  
98) Zhao, J*., Bai, Z., Ma, L., 2018. Dairy farming in China at a crossroad. Sci. Bull. 63, 1534–1535.  
99) Chen, X., Ma, L., Ma, W., Wu, Z., Cui, Z., Hou, Y., Zhang, F*., 2018. What has caused the use of fertilizers to skyrocket in China? Nutr. Cycl. Agroecosystems 110, 241–255.
100) 马林*,马文奇,张福锁. 农牧系统养分管理[J]. 中国农业科学,2018,(03):401-405.
101) 马林*,柏兆海,王选,曹玉博,马文奇,张福锁.中国农牧系统养分管理研究的意义与重点[J]. 中国农业科学, 2018,(03):406-416.
102) 魏莎,柏兆海,吴迪梅,夏立江,江荣风, 马林*.都市圈“土壤-饲料-动物”系统养分流动与环境效应—以北京市为例[J]. 中国农业科学,2018, (03):430-441.
103) 马怡斐,柏兆海, 马林*,聂永强,江荣风.栾城城郊型农牧系统养分流动与环境排放时空特征[J]. 中国农业科学,2018, (03):493-506.
104) 魏志标,柏兆海, 马林*,张福锁.中国苜蓿、黑麦草和燕麦草产量差及影响因素[J]. 中国农业科学,2018, (03):507-522.
105) 魏志标,柏兆海, 马林*,张福锁.中国天然草地氮磷流动空间特征[J]. 中国农业科学,2018, (03):523-534.
106) 魏志标,柏兆海, 马林*,张福锁.中国栽培草地氮磷流动空间特征[J]. 中国农业科学,2018, (03):535-555.
107) 曹玉博,邢晓旭,柏兆海,王选,胡春胜, 马林*.农牧系统氨挥发减排技术研究进展[J]. 中国农业科学,2018, (03):566-580.
108) 郭勇庆,屠焰,张乃锋,刘国华,唐德富,王宗勇,钟昊,李耀基, 马林*.中国饲料磷推荐水平及磷酸盐应用现状和优化分析[J]. 中国农业科学,2018, (03): 581-593.
109) 郭勇庆,屠焰,柏兆海, 马林*.“饲料-畜禽-粪尿”链中磷高效利用与减排研究[J].动物营养学报,2018,30(09):3329-3336.
110) 马林,卢洁,赵浩,柏兆海,胡春胜*.中国硝酸盐脆弱区划分与面源污染阻控[J].农业环境科学学报,2018,37(11):2387-2391.
111) 马林*,马文奇,张福锁,柏兆海,侯勇.中国食物链养分流动与管理研究[J].中国生态农业学报,2018,26(10):1494-1500.
2017
112) Bai, Z., Li, X., Lu, J., Wang, X., Velthof, G.L., Chadwick, D., Luo, J., Ledgard, S., Wu, Z., Jin, S., Oenema, O., Ma, L*., Hu, C*., 2017. Livestock Housing and Manure Storage Need to Be Improved in China. Environ. Sci. Technol.51, 8212–8214.
113) Zhao, Z., Bai, Z., Winiwarter, W., Kiesewetter, G., Heyes, C., Ma, L*., 2017. Science of the Total Environment Mitigating ammonia emission from agriculture reduces PM 2.5 pollution in the Hai River Basin in China 609, 1152–1160.
114) Zhao, Z., Bai, Z., Wei, S., Ma, W., Wang, M., Kroeze, C., Ma, L*., 2017. Modeling farm nutrient flows in the North China Plain to reduce nutrient losses. Nutr. Cycl. Agroecosystems 108, 231–244.
115) Li, A., Strokal, M., Bai, Z., Kroeze, C., Ma, L*., Zhang, F. 2017. Modelling reduced coastal eutrophication with increased crop yields in Chinese agriculture. Soil Research, 55(6): 506-517.
116) Zhang, N., Bai, Z., Luo, J., Ledgard, S., Wu, Z., Ma, L*., 2017. Science of the Total Environment Nutrient losses and greenhouse gas emissions from dairy production in China?: Lessons learned from historical changes and regional differences. Sci. Total Environ. 598, 1095–1105.  
117) Wang, M*., Kroeze, C., Strokal, M., Ma, L*., 2017. Reactive nitrogen losses from China’s food system for the shared socioeconomic pathways (SSPs). Sci. Total Environ. 605–606, 884–893.
118) Guo, M., Chen, X., Bai, Z., Jiang, R*., Galloway, J.N., Leach, A.M., Cattaneo, L.R., Oenema, O., Ma, L*., Zhang, F., 2017. How China’s nitrogen footprint of food has changed from 1961 to 2010. Environmental Research Letters 12, 104006.
119) Strokal, M*., Kroeze, C., Wang, M., Ma, L., 2017. Reducing future river export of nutrients to coastal waters of China in optimistic scenarios. Sci. Total Environ. 579, 517–528.
120) Shibata, H*., Galloway, J.N., Leach, A.M., Cattaneo, L.R., Noll, L.C., Erisman, J.W., Gu, B., Liang, X., Hayashi, K., Ma, L., Dalgaard, T., Graversgaard, M., Chen, D., Nansai, K., Shindo, J., Matsubae, K., Oita, A., Su, M., Mishima, S., Bleeker, A., 2017. Nitrogen footprints?: Regional realities and options to reduce nitrogen loss to the environment. Ambio 46, 129–142.
121) Luo, J*., Wyatt, J., van der Weerden, T.J., Thomas, S.M., de Klein, C.A.M., Li, Y., Rollo, M., Lindsey, S., Ledgard, S.F., Li, J., Ding, W., Qin, S., Zhang, N., Bolan, N., Kirkham, M.B., Bai, Z., Ma, L., Zhang, X., Wang, H., Liu, H., Rys, G., 2017. Potential Hotspot Areas of Nitrous Oxide Emissions From Grazed Pastoral Dairy Farm Systems. Advances in Agronomy 145, 205–268.
122) 魏莎,柏兆海,吴迪梅,江荣风*,夏立江,马林*. 北京“土壤-饲料-奶牛”系统氮磷流动及环境损失时空特征[J]. 中国生态农业学报,2017,25(03):316-327.
123) 陈炫冀,陈晓辉,柏兆海, 马林*.化肥和饲料添加剂生产磷流动特征研究[J].中国生态农业学报,2017,25(11):1565-1579.
2016
124) Bai, Z., Ma, L*., Jin, S., Ma, W., Velthof, G.L., Oenema, O., Liu, L., Chadwick, D., Zhang, F., 2016. Nitrogen, phosphorus, and potassium flows through the manure management chain in China. Environ. Sci. Technol. 50, 13409–13418. 8
125) Bai, Z., Ma, L*., Ma, W., Qin, W., Velthof, G.L., Oenema, O., Zhang, F., 2016. Changes in phosphorus use and losses in the food chain of China during 1950–2010 and forecasts for 2030. Nutr. Cycl. Agroecosystems 104, 361–372.
126) Hou, Y., Bai, Z., Lesschen, J.P., Staritsky, I.G., Sikirica, N., Ma, L., Velthof, G.L., Oenema, O., 2016. Feed use and nitrogen excretion of livestock in EU-27. Agric. Ecosyst. Environ. 218, 232–244.
127) Strokal, M., Kroeze, C., Wang, M., Bai, Z., Ma, L., 2016a. The MARINA model (Model to Assess River Inputs of Nutrients to seAs): Model description and results for China. Sci. Total Environ. 562, 869–888.
128) Strokal, M., Ma, L*., Bai, Z., Luan, S., Kroeze, C., Oenema, O., Velthof, G., Zhang, F., 2016b. Alarming nutrient pollution of Chinese rivers as a result of agricultural transitions. Environ. Res. Lett. 11.
129) Wei, S., Bai, Z.H., Qin, W., Xia, L.J., Oenema, O., Jiang, R.F*., Ma, L*., 2016. Environmental, economic and social analysis of peri-urban pig production. J. Clean. Prod. 129, 596–607.
130) 魏莎,马林*,江荣风,柏兆海,吴迪梅,夏立江. 基于NUFER模型的生猪养殖氮磷利用效率及排放时空变化[J]. 农业工程学报,2016,13:190-196.
131) 马林,柏兆海,胡春胜*.“农田氮磷淋溶损失污染与防控机制研究”项目正式启动[J]. 中国生态农业学报,2016,11:1575-1576.
2015
132) Hou, Y., Ma, L., Sárdi, K., Sisák, I., Ma, W., 2015. Nitrogen flows in the food production chain of Hungary over the period 1961–2010. Nutr. Cycl. Agroecosystems 102, 335–346. (Co-first author)
133) Ma, L., Qin, W., Garnett, T., Zhang, F., 2015. Review on drivers, trends and emerging issues of the food wastage in China. Front. Agric. Sci. Eng. 2, 159–167.
2014
134) Bai, Z.H., Ma, L., Qin, W., Chen, Q., Oenema, O., Zhang, F.S., 2014. Changes in pig production in china and their effects on nitrogen and phosphorus use and losses. Environ. Sci. Technol. 48, 12742–12749. (Co-first author)
135) Chen, X., Cui, Z., Fan, M., Vitousek, P., Zhao, M., Ma, W., Wang, Zhenlin, Zhang, Weijian, Yan, X., Yang, J., Deng, X., Gao, Q., Zhang, Q., Guo, S., Ren, J., Li, S., Ye, Y., Wang, Zhaohui, Huang, J., Tang, Q., Sun, Y., Peng, X., Zhang, J., He, M., Zhu, Y., Xue, J., Wang, G., Wu, Liang, An, N., Wu, Liangquan, Ma, L., Zhang, Weifeng, Zhang, F., 2014. Producingmore grain with lower environmental costs. Nature 514, 486–489.
136) Li, Y., Zhang, W., Ma, L., Wu, L., Shen, J., Davies, W.J., Oenema, O., Zhang, F., Dou, Z., 2014. An analysis of China’s grain production: Looking back and looking forward. Food Energy Secur. 3, 19–32.
137) Ma, L., Guo, J., Velthof, G.L., Li, Y., Chen, Q., Ma, W., Oenema, O., Zhang, F., 2014a. Impacts of urban expansion on nitrogen and phosphorus flows in the food system of Beijing from 1978 to 2008. Glob. Environ. Chang. 28, 192–204. 5
138) Ma, L., Velthof, G.L., Kroeze, C., Ju, X., Hu, C., Oenema, O., Zhang, F., 2014b. Mitigation of nitrous oxide emissions from food production in China. Curr. Opin. Environ. Sustain. 9, 82–89.
139) Oenema, O., Ju, X., de Klein, C., Alfaro, M., del Prado, A., Lesschen, J.P., Zheng, X., Velthof, G., Ma, L., Gao, B., Kroeze, C., Sutton, M., 2014. Reducing nitrous oxide emissions from the global food system. Curr. Opin. Environ. Sustain. 9–10, 55–64.
 
2013
140) Bai, Z.H., Ma, L., Oenema, O., Chen, Q., Zhang, F.S., 2013. Nitrogen and Phosphorus Use Efficiencies in Dairy Production in China. J. Environ. Qual. 42, 990–1001. (Co-first author)
141) Gu, B., Leach, A.M., Ma, L., Galloway, J.N., Chang, S.X., Ge, Y., Chang, J., 2013. Nitrogen footprint in China: Food, energy, and nonfood goods. Environ. Sci. Technol. 47, 9217–9224.
142) Hou, Y., Ma, L., Gao, Z.L., Wang, F.H., Sims, J.T., Ma, W.Q., Zhang, F.S., 2013. The Driving Forces for Nitrogen and Phosphorus Flows in the Food Chain of China, 1980 to 2010. J. Environ. Qual. 42, 962–971. (Co-first author)
143) Li, Y., Zhang, W., Ma, L., Huang, G., Oenema, O., Zhang, F., Dou, Z., 2013. An Analysis of China’s Fertilizer Policies: Impacts on the Industry, Food Security, and the Environment. J. Environ. Qual. 42, 972–981.
144) Ma, L, Wang, F., Zhang, W., Ma, W., Velthof, G., Qin, W., Oenema, O., Zhang, F., 2013. Environmental assessment of management options for nutrient flows in the food chain in China. Environ. Sci. Technol. 47, 7260–7268.
145) Ma, L., Zhang, W.F., Ma, W.Q., Velthof, G.L., Oenema, O., Zhang, F.S., 2013. An Analysis of Developments and Challenges in Nutrient Management in China. J. Environ. Qual. 42, 951–961.
146) Sims, J.T., Ma, L., Oenema, O., Dou, Z., Zhang, F.S., 2013. Advances and Challenges for Nutrient Management in China in the 21st Century. J. Environ. Qual. 42, 947–950.
147) Yan, Z., Liu, P., Li, Y., Ma, L., Alva, A., Dou, Z., Chen, Q., Zhang, F., 2013. Phosphorus in China’s Intensive Vegetable Production Systems: Overfertilization, Soil Enrichment, and Environmental Implications. J. Environ. Qual. 42, 982–989. https://doi.org/10.2134/jeq2012.046
148) 张卫峰*,马林,黄高强,武良,陈新平,张福锁.中国氮肥发展、贡献和挑战[J].中国农业科学,2013,46(15):3161-3171.
 
2012
149) Ma, L., Velthof, G.L., Wang, F.H., Qin, W., Zhang, W.F., Liu, Z., Zhang, Y., Wei, J., Lesschen, J.P., Ma, W.Q., Oenema, O., Zhang, F.S., 2012. Nitrogen and phosphorus use efficiencies and losses in the food chain in China at regional scales in 1980 and 2005. Sci. Total Environ. 434, 51–61.
 
2011
150) Li, H., Huang, G., Meng, Q., Ma, L., Yuan, L., Wang, F., Zhang, W., Cui, Z., Shen, J., Chen, X., Jiang, R., Zhang, F., 2011. Integrated soil and plant phosphorus management for crop and environment in China. A review. Plant Soil. 349, 157–167.
151) Ma, W*., Ma, L., Li, J., Wang, F., Sisák, I., Zhang, F., 2011. Phosphorus flows and use efficiencies in production and consumption of wheat, rice, and maize in China. Chemosphere. 84, 814–821.
152) Wang, F., Sims, J.T., Ma, L., Ma, W., Dou, Z., Zhang, F., 2011. The Phosphorus Footprint of China’s Food Chain: Implications for Food Security, Natural Resource Management, and Environmental Quality. J. Environ. Qual. 40, 1081–1089.
153) 曾韵婷,向玥皎,马林*,张卫峰,张福锁.欧盟养分管理政策法规对中国的启示[J].世界农业,2011(04):39-43.
154) 向玥皎,王方浩,覃伟,马林*,张卫峰,张福锁.美国养分管理政策法规对中国的启示[J].世界农业,2011(03):51-55+86.
 
2010
155) Ma, L., Ma, W.Q., Velthof, G.L., Wang, F.H., Qin, W., Zhang, F.S., Oenema, O., 2010. Modeling Nutrient Flows in the Food Chain of China. J. Environ. Qual. 39, 1279–1289.
156) Wang, F., Dou, Z., Ma, L., Ma, W., Sims, J.T., Zhang, F., 2010. Nitrogen Mass Flow in China’s Animal Production System and Environmental Implications. J. Environ. Qual. 39, 1537–1544.
157) Zhang, Y., Dore, A.J., Ma, L., Liu, X.J., Ma, W.Q., Cape, J.N., Zhang, F.S., 2010. Agricultural ammonia emissions inventory and spatial distribution in the North China Plain. Environ. Pollut. 158, 490–501.
 
2009
158) 马林,魏静,王方浩,马文奇*,张福锁.中国食物链氮素资源流动特征分析[J].自然资源学报,2009,24(12):2104-2114.
159) 马林,魏静,王方浩,高利伟,赵路,马文奇*,张福锁.基于模型和物质流分析方法的食物链氮素区域间流动——以黄淮海区为例[J].生态学报,2009,29(01):475-483.
160) 高利伟,马林,张卫峰,王方浩,马文奇*,张福锁.中国作物秸秆养分资源数量估算及其利用状况[J].农业工程学报,2009,25(07):173-179.
161) 高利伟,马林,张卫峰,王方浩,马文奇*,张福锁.黄淮海三省两市作物秸秆及其养分资源利用现状分析[J].中国农学通报,2009,25(11):186-193.
162) 魏静,马林,马文奇*,路光,赵路.城镇化对我国不同年代农田氮素循环的影响[J].河北农业大学学报,2009,32(01):6-9.
163) 赵路,魏静,马林,王方浩,马文奇*.河北省不同养殖模式的畜禽粪尿资源及污染风险分析[J].农业环境科学学报,2009,28(03):544-548.
164) 魏静,马林,杨玉荣,马文奇*,路光,赵路.城镇化对我国食物消费系统氮素水体排放的影响[J].生态学报,2009,29(11):6035-6041.
 
2008
165) Ma, W*., Li, J., Ma, L., Wang, F., Sisák, I., Cushman, G., Zhang, F., 2008. Nitrogen flow and use efficiency in production and utilization of wheat, rice, and maize in China. Agric. Syst. 99, 53–63.
166) 刘东,王方浩,马林,马文奇*,张福锁.中国猪粪尿NH_3排放因子的估算[J].农业工程学报,2008(04):218-224.
167) 魏静,马林,路光,马文奇*,李建辉,赵路.城镇化对我国食物消费系统氮素流动及循环利用的影响[J].生态学报,2008(03):1016-1025.
168) 路光, 魏静*, 马文奇, 杨玉荣, 马林 等,城镇化对我国家庭体系磷流动及环境的影响研究. 中国人口资源与环境, 2008. 18: 64-67.
 
2007
169) 李建辉,马林,王激清,王方浩,马文奇*,张福锁.中国玉米生产-消费体系养分流动分析[J].自然资源学报,2007(03):455-462.
170) 刘东,马林,王方浩,卞芬茹,马文奇*,张福锁.中国猪粪尿N产生量及其分布的研究[J].农业环境科学学报,2007(04):1591-1595.
171) 刘东,马林,王方浩,马文奇*,张福锁.河北省猪粪尿氮产生量及氨挥发量的研究[J].河北农业大学学报,2007(06):5-10.
 
2006
172) 马林,王方浩,马文奇,等. 中国东北地区中长期畜禽粪尿资源与污染潜势估算. 农业工程学报 ,2006, 22(8):170-174. (EI收录)
173) 马林,王方浩,刘东,等.河北省畜禽粪尿养分资源分布及其污染潜力分析.河北农业大学学报,2006,29(6):99-103.
174) 李建辉,马林,王方浩,等.中国家庭营养体系养分流动模式分析.中国人口资源与环境,2006(4)
175) 王方浩,马文奇,窦争霞,马林,刘小利,许俊香,张福锁.中国畜禽粪便产生量估算及环境效应[J].中国环境科学,2006(05):614-617.
 
2005
176) 许俊香,刘晓利,王方浩,张福锁,马文奇*,马林.我国畜禽生产体系中磷素平衡及其环境效应[J].生态学报,2005(11):119-126.
 
参编专著
1) 陈新平等编著,长江经济带农业绿色发展—挑战与行动. 北京:科学出版社,2022,2.
2) 张福锁等编著,中国农业绿色发展理论与实践. 北京:中国农业大学出版社,2021,3.
3) Aline Mosnier et al., Pathways to Sustainable Land-Use and Food Systems. Report of the FABLE Consortium, 2020,3.
4) Aline Mosnier et al., Pathways to Sustainable Land-Use and Food Systems. Report of the FABLE Consortium, 2019,3.
5) Henk Westhoek et al., Natural resources and environmental impacts of food systems. UNEP, Food Systems and Natural Resources, 2016,11.
6) 张福锁等编著,高产高效养分管理技术. 北京:中国农业大学出版社,2012,11.
7) 张福锁等编著,最佳养分管理技术列单. 北京:中国农业大学出版社,2010,10.
8) 张福锁等编著,养分资源综合管理与技术概论. 北京:中国农业大学出版社,2006,12.
 
授权专利
1.  王选,唐子贵,马林,柏兆海. 智能分层曝气堆肥反应器系统. 中国, 发明专利, ZL 201710670003 .X . 2017年.
2.  马林,张西群,王选,柏兆海. 施肥播种系统和液态粪尿注射施用与播种一体化机具. 中国, 实用新型, ZL 201820811241.8. 2018年.
3.  马林,张西群,王选,柏兆海.液态粪尿供给存储系统和液态粪尿注射施用与播种机具, 中国, 实用新型, ZL 201820809769.1. 2018年.
4.  柏兆海,马林,王选,张楠楠. 一种用于在粪污表面均匀铺洒酸化蛭石的装置.中国, 实用新型专利, ZL 201821861866.1. 2018年.
5.  王选,唐子贵,马林,柏兆海. 分层曝气系统堆肥反应气泵热能利用系统. 中国, 实用新型, ZL201920940666.3. 2019年.
6.  王选,唐子贵,马林,柏兆海. 分层曝气系统堆肥反应器冷凝水回收系统. 中国, 实用新型, ZL201920940740.1. 2019年.
7.  王选,张晓航,马林,柏兆海. 一种自走式液体肥料定量喷施装置, 中国, 实用新型, ZL 202020385055.X. 2020年.
8.  王选,张晓航,马林,柏兆海. 一种对好氧堆肥过程中产生的挥发气体进行回收的装置, 中国, 实用新型, ZL202021909558.9. 2020年.
王选,张晓航,马林,柏兆海. 养殖废气回收利用装置, 中国,外观专利, ZL 202030519198.0. 2020