| [1] | 林修咏. 阶梯式生物滞留系统运行效能优化与脱氮机理研究[D]. 福州: 福州大学, 2018. |
| [2] | 仇付国, 李林彬, 王娟丽, 等. 给水厂污泥改良雨水生物滞留系统填料层最优设计深度研究[J]. 环境工程, 2018, 36(12): 81-86. |
| [3] | 余雪花, 陈垚, 任萍萍, 等. 生物滞留系统植物筛选与综合评价[J]. 环境工程学报, 2019, 13(7): 1634-1644. |
| [4] | 高晓丽, 张书函, 肖娟, 等. 雨水生物滞留设施中填料的研究进展[J]. 中国给水排水, 2015, 31(20): 17-21. |
| [5] | 王书敏, 黄克舒, DAVIS P A, 等. 生物滞留系统介质土的理化性质比较研究[J]. 中国给水排水, 2019, 35(17): 133-138. |
| [6] | 仇付国, 代一帆, 卢超, 等. 基质改良和结构优化强化雨水生物滞留系统除污[J]. 中国给水排水, 2017, 33(7): 157-162. |
| [7] | 仇付国, 王珂, 李林彬, 等. 滞留时间和进水有机物对生物滞留系统除氮的影响[J]. 科学技术与工程, 2018, 18(4): 197-202. |
| [8] | HERMAWAN A A, TALEI A, SALAMATINIA, et al. Seasonal performance of stormwater biofiltration system under tropical conditions[J]. Ecological Engineering, 2020, 143: 105676. |
| [9] | 陈韬, 张本, 李剑沣, 等. 几种生物滞留植物对雨水中营养物的吸收动力学特征[J]. 环境工程, 2018, 36(9): 26-30. |
| [10] | 王书敏, 何强, 徐强, 等. 生物滞留系统去除地表径流中的氮素研究评述[J]. 水科学进展, 2015, 26(1): 140-150. |
| [11] | 王书敏, 何强, 艾海男, 等. 山地城市暴雨径流污染特性及控制对策[J]. 环境工程学报, 2012, 6(5): 1445-1450. |
| [12] | GOH H W, ZAKARIA N A, LAU T L, et al. Mesocosm study of enhanced bioretention media in treating nutrient rich stormwater for mixed development area[J]. Urban Water Journal, 2015, 7(1/2): 581-590. |
| [13] | 陈垚, 任萍萍, 张彩, 等. 生物滞留系统中植物去除氮素机理及影响因素[J]. 环境科学与技术, 2017, 40(S2): 85-90. |
| [14] | WANG R, ZHANG X, LI M H. Predicting bioretention pollutant removal efficiency with design features: A data-driven approach[J]. Journal of Environmental Management, 2019, 242(15): 403-414. |
| [15] | GITARI H I, KARANJA N N, GACHENE C K K, et al. Nitrogen and phosphorous uptake by potato (Solanum tuberosum l.) and their use efficiency under potato-legume intercropping systems[J]. Field Crops Research, 2018, 222: 78-84. doi: 10.1016/j.fcr.2018.03.019 |
| [16] | PAYNE E G I, PHAM T, DELETIC A, et al. Which species? A decision-support tool to guide plant selection in stormwater biofilters[J]. Advances in Water Resources, 2018, 113: 86-99. doi: 10.1016/j.advwatres.2017.12.022 |
| [17] | 王红莲. 不同水生植物对富营养化水体反硝化脱氮及净化效果影响的研究[D]. 南京: 南京农业大学, 2014. |
| [18] | 李迪, 陈垚, 吕波. 生物滞留系统对溶解性污染物的去除特性及优化途径[J]. 环境工程, 2020, 38(10): 120-127. |
| [19] | PAYNE E G, FLETCHER T D, RUSSELL D G, et al. Temporary storage or permanent removal?The division of nitrogen between biotic assimilation and denitrification in stormwater biofiltration systems[J]. Plos One, 2014, 9(3): 1-12. |
| [20] | 王超, 陈煜权, 蔡丽婧, 等. 不同季节大型生态净化工程对原水氮素净化效果[J]. 环境工程学报, 2015, 9(8): 3763-3767. |
| [21] | 李品, 木勒德尔·吐尔汗拜, 田地, 等. 全球森林土壤微生物生物量碳氮磷化学计量的季节动态[J]. 植物生态学报, 2019, 43(6): 532-542. |
| [22] | LEFEVRE G H, PAUS K H, NATARAJAN P, et al. Review of dissolved pollutants in urban storm water and their removal and fate in bioretention cells[J]. Journal of Environmental Engineering, 2015, 141(1): 04014050. doi: 10.1061/(ASCE)EE.1943-7870.0000876 |
| [23] | MUERDTER C P, SMITH D J, DAVIS A P. Impact of vegetation selection on nitrogen and phosphorus processing in bioretention containers[J]. Water Environment Research, 2020, 92(2): 236-244. doi: 10.1002/wer.1195 |
| [24] | OSMAN M, WAN YUSOF K, et al. A review of nitrogen removal for urban stormwater runoff in bioretention system[J]. Sustainability, 2019, 11(19): 5415. |
| [25] | WANG C, WANG F, QIN H, et al. Effect of saturated zone on nitrogen removal processes in stormwater bioretention systems[J]. Water, 2018, 10(2): 162. |
| [26] | YOU Z, ZHANG L, PAN S Y, et aL. Performance evaluation of modified bioretention systems with alkaline solid wastes for enhanced nutrient removal from stormwater runoff[J]. Water Research, 2019, 161(15): 61-73. |
| [27] | 朱越, 滕俊伟, 陈瑞弘, 等. 内部蓄水层对生物滞留设施中氮去除效率的中试[J]. 净水技术, 2017, 36(2): 26-30. |
| [28] | AHMAD A, ARIF M S, YASMEEN T, et al. Seasonal variations of soil phosphorus and associated fertility indicators in wastewater irrigated urban aridisol[J]. Chemosphere, 2020, 239: 124725. doi: 10.1016/j.chemosphere.2019.124725 |
| [29] | YUJIA S, SHOUFA S. Migration and transformation of different phosphorus forms in rainfall runoff in bioretention system[J]. Environmental Science & Pollution Research, 2018, 26: 30633-30640. |
| [30] | 仇付国, 卢超, 代一帆, 等. 改良雨水生物滞留系统除污效果及基质中磷的形态分布研究[J]. 给水排水, 2017, 53(3): 48-54. |
| [31] | 熊家晴, 何一帆, 白雪琛, 等. 改良填料生物滞留池对雨水径流中磷的去除效果[J]. 环境工程学报, 2019, 13(9): 2164-2172. |
| [32] | 李来燕. 改良生物滞留设施对磷素净化性能的试验研究[D]. 西安: 西安理工大学, 2019. |
| [33] | 匡颖, 董启荣, 王鹤立. 海绵铁与火山岩填料A/O生物滴滤池脱氮除磷的中试研究[J]. 水处理技术, 2012, 38(9): 50-53. |
| [34] | LI J, DAVIS A P. A unified look at phosphorus treatment using bioretention[J]. Water Research, 2016, 90(86): 141-155. |
| [35] | 仇付国, 陈丽霞. 雨水生物滞留系统控制径流污染物研究进展[J]. 环境工程学报, 2016, 10(4): 1593-1602. |
| [36] | GUO C, LI J, LI H, et al. Seven-year running effect Evaluation and fate analysis of rain gardens in Xi′an, Northwest China[J]. Water, 2018, 10(7): 944. doi: 10.3390/w10070944 |
| [37] | YANG H, DICK W A, MCCOY E L, et al. Field evaluation of a new biphasic rain garden for stormwater flow management and pollutant removal[J]. Ecological Engineering, 2013, 54: 22-31. doi: 10.1016/j.ecoleng.2013.01.005 |
| [38] | 郭超. 雨水花园集中入渗对土壤和地下水影响的试验研究[D]. 西安: 西安理工大学, 2019. |
| [39] | 宫永伟, 张贤巍, 翟丹丹, 等. 简单式绿色屋顶对雨水径流水质的影响规律研究[J]. 环境污染与防治, 2020, 42(3): 264-267. |
| [40] | 蒋春博. 生物滞留系统填料改良及径流调控研究[D]. 西安: 西安理工大学, 2019. |
| [41] | JIANG C, LI J, LI H, et al. An improved approach to design bioretention system media[J]. Ecological Engineering, 2019, 136: 125-133. doi: 10.1016/j.ecoleng.2019.06.014 |
| [42] | 刘增超, 李家科, 蒋春博, 等. 4种生物滞留填料对径流污染净化效果对比[J]. 水资源保护, 2018, 34(4): 71-79. |
| [43] | 卢静芳, 孔祥媚, 赵瑞斌. 强化混凝去除微污染湖泊水浊度及TOC的研究[J]. 环境科学与技术, 2010, 33(3): 76-79. |
| [44] | 付山. 不同基质生物滞留系统雨水净化效果研究[D]. 西安: 西安建筑科技大学, 2018. |
| [45] | 王娟丽. 给水厂污泥改良生物滞留系统对氮磷去除的优化探究[D]. 北京: 北京建筑大学, 2019. |
| [46] | 田婧, 刘丹. 生物炭对去除生物滞留池氨氮及雨水持留的影响[J]. 西南交通大学学报, 2017, 52(6): 1201-1207. |
| [47] | JIANG C, LI J, LI H, et al. Field performance of bioretention systems for runoff quantity regulation and pollutant removal[J]. Water, Air, and Soil Pollution, 2017, 228(12): 468. doi: 10.1007/s11270-017-3636-6 |
| [48] | THOMAS S C, HALIM M A, GALE N V, et al. Biochar enhancement of facilitation effects in agroforestry: Early growth and physiological responses in a maize-leucaena model system[J]. Agroforestry Systems, 2019, 93: 2213-2225. doi: 10.1007/s10457-018-0336-1 |