Stormwater quantity and quality control performance of bioretention systems: A literature review

doi:10.13287/j.1001-9332.202301.028

Abstract

Abstract: Bioretention systems, as one of the most widely used modern stormwater management tools, have outstanding performance in capturing runoff, mitigating peak flow, delaying outflow occur time, and improving effluent quality. We reviewed the research of hydrologic and water quality performance of bioretention systems around the world from different perspectives, including the structure and classification of bioretention systems, the mechanisms of runoff and pollutants regulation of bioretention systems, the hydrologic and water quality performances of bioretention systems, the runoff control and water purification evaluation models of bioretention systems, as well as the influencing factors of runoff control and water purification efficiency. We proposed that future research should focus on hydrologic and water quality of bioretention systems, e.g., optimization of design configurations, revealing the mechanisms of plant action, revealing the mechanisms of microbial action, the effects of climate change on hydrologic and water quality performance, watershed/regional scale hydrologic and water quality performance, purification effect and mechanisms of emerging pollutants, maintenance methods, as well as life-cycle assessment and cost analysis. This review would provide theoretical and technical supports for research, design, construction, and maintenance of bioretention systems.

Key words: bioretention system, stormwater control, water quality purification, simulation model, influencing factor.

ZHANG Wen-long, ZHANG Shou-hong, ZHANG Jian-jun. Stormwater quantity and quality control performance of bioretention systems: A literature review[J]. Chinese Journal of Applied Ecology, 2023, 34(1): 264-276.

References

[1] Davis AP. Field performance of bioretention: Hydrology impacts. Journal of Hydrologic Engineering, 2008, 13: 90-95
[2] 孙艳伟, 王文川, 魏晓妹, 等. 城市化生态水文效应. 水科学进展, 2012, 23(4): 569-574
[3] 张建云, 王银堂, 贺瑞敏, 等. 中国城市洪涝问题及成因分析. 水科学进展, 2016, 27(4): 485-491
[4] Davis AP, Mccuen RH. Stormwater Management for Smart Growth. New York: Springer, 2005: 1-6
[5] 张建云, 宋晓猛, 王国庆, 等. 变化环境下城市水文学的发展与挑战——I. 城市水文效应. 水科学进展, 2014, 25(4): 594-605
[6] Wang H, Mei C, Liu JH, et al. A new strategy for integrated urban water management in China: Sponge city. Science China Technological Sciences, 2018, 61: 317-329
[7] Xia J, Zhang YY, Xiong LH, et al. Opportunities and challenges of the sponge city construction related to urban water issues in China. Science China Earth Sciences, 2017, 60: 652-658
[8] 刘文, 陈卫平, 彭驰. 城市雨洪管理低影响开发技术研究与利用进展. 应用生态学报, 2015, 26(6): 1901-1912
[9] Davis AP, Hunt WF, Traver RG, et al. Bioretention technology: Overview of current practice and future needs. Journal of Environmental Engineering, 2009, 135: 109-117
[10] 胡爱兵, 张书函, 陈建刚. 生物滞留池改善城市雨水径流水质的研究进展. 环境污染与防治, 2011, 33(1): 87-90, 95
[11] Li GH, Xiong JQ, Zhu J, et al. Design influence and evaluation model of bioretention in rainwater treatment: A review. Science of the Total Environment, 2021, 787: 147592
[12] 蒋春博, 李家科, 李怀恩. 生物滞留系统处理径流营养物研究进展. 水力发电学报, 2017, 36(8): 67-79
[13] Spraakman S, Rodgers TFM, Monri-Fung H, et al. A need for standardized reporting: A scoping review of bioretention research 2000-2019. Water, 2020, 12: 3122
[14] Muerdter CP, Wong CK, Lefever GH. Emerging investigator series: The role of vegetation in bioretention for stormwater treatment in the built environment: Pollutant removal, hydrologic function, and ancillary benefits. Environmental Science: Water Research & Technology, 2018, 4: 592-612
[15] Li JK, Liu F, Li YJ. Simulation and design optimization of rain gardens via DRAINMOD and response surface methodology. Journal of Hydrology, 2020, 585: 124788
[16] 李家科, 刘增超, 黄宁俊, 等. 低影响开发(LID)生物滞留技术研究进展. 干旱区研究, 2014, 31(3): 431-439
[17] Liu J, Sample DJ, Bell C, et al. Review and research needs of bioretention used for the treatment of urban stormwater. Water, 2014, 6: 1069-1099
[18] Skorobogatov A, He JX, Chu A, et al. The impact of media, plants and their interactions on bioretention performance: A review. Science of the Total Environment, 2020, 715: 136918
[19] Szota C, McCarthy MJ, Sanders GJ, et al. Tree water-use strategies to improve stormwater retention perfor-mance of biofiltration systems. Water Research, 2018, 144: 285-295
[20] 高建平, 潘俊奎, 谢义昌. 生物滞留带结构层参数对道路径流滞蓄效应影响. 水科学进展, 2017, 28(5): 702-711
[21] Eger CG, Chandler DG, Driscoll CT. Hydrologic processes that govern stormwater infrastructure behaviour. Hydrological Processes, 2017, 31: 4492-4506
[22] Hong EY, Seagren EA, Davis AP. Sustainable oil and grease removal from synthetic stormwater runoff using bench-scale bioretention studies. Water Environment Research, 2006, 78: 141-155
[23] Dietz ME, Clausen JC. Saturation to improve pollutant retention in a rain garden. Environmental Science & Technology, 2006, 40: 1335-1340
[24] Tirpak RA, Afrooz AN, Winston RJ, et al. Conventional and amended bioretention soil media for targeted pollutant treatment: A critical review to guide the state of the practice. Water Research, 2021, 189: 116648
[25] Lopez-Ponnada EV, Lynn TJ, Ergas SJ, et al. Long-term field performance of a conventional and modified bioretention system for removing dissolved nitrogen species in stormwater runoff. Water Research, 2020, 170: 115336
[26] Bratieres K, Fletcher TD, Deletic A, et al. Nutrient and sediment removal by stormwater biofilters: A large-scale design optimization study. Water Research, 2008, 42: 3930-3940
[27] Li JK, Davis AP. A unified look at phosphorus treatment using bioretention. Water Research, 2016, 90: 141-155
[28] Rycewicz-Borecki M, McLean JE, Dupont RR. Nitrogen and phosphorus mass balance, retention and uptake in six plant species grown in stormwater bioretention microcosms. Ecological Engineering, 2017, 99: 409-416
[29] Le Coustumer S, Fletcher TD, Deletic A, et al. The influence of design parameters on clogging of stormwater biofilters: A large-scale column study. Water Research, 2012, 46: 6743-6752
[30] Jiang CB, Li JK, Li HE, et al. Nitrogen retention and purification efficiency from rainfall runoff via retrofitted bioretention cells. Separation and Purification Technology, 2019, 220: 25-32
[31] Zuo XJ, Guo ZY, Wu X, et al. Diversity and metabolism effects of microorganisms in bioretention systems with sand, soil and fly ash. Science of the Total Environment, 2019, 676: 447-454
[32] Maltais-Landry G, Maranger R, Brisson J, et al. Nitrogen transformations and retention in planted and artificially aerated constructed wetlands. Water Research, 2009, 43: 535-545
[33] 李立青, 胡楠, 刘雨情, 等. 3种生物滞留设计对城市地表径流溶解性氮的去除作用. 环境科学, 2017, 38(5): 1881-1888
[34] 李立青, 刘雨情, 杨佳敏, 等. 生物滞留对城市地表径流磷的去除途径. 环境科学, 2018, 39(7): 3150-3157
[35] Sun XL, Davis AP. Heavy metal fates in laboratory bioretention systems. Chemosphere, 2007, 66: 1601-1609
[36] Johnson JP, Hunt WF. Field assessment of the hydrolo-gic mitigation performance of three aging bioretention cells. Journal of Sustainable Water in the Built Environment, 2020, 6: 04020017
[37] Brown RA, Hunt WF. Impacts of media depth on effluent water quality and hydrologic performance of undersized bioretention cells. Journal of Irrigation and Drai-nage Engineering, 2011, 137: 132-143
[38] Brown RA, Hunt WF. Improving bioretention/biofiltration performance with restorative maintenance. Water Science and Technology, 2012, 65: 361-367
[39] Olszewski JM, Davis AP. Comparing the hydrologic performance of a bioretention cell with predevelopment va-lues. Journal of Irrigation and Drainage Engineering, 2013, 139: 124-130
[40] DeBusk KM, Wynn TM. Storm-water bioretention for runoff quality and quantity mitigation. Journal of Environmental Engineering, 2011, 137: 800-808
[41] Winston RJ, Dorsey JD, Hunt WF. Quantifying volume reduction and peak flow mitigation for three bioretention cells in clay soils in northeast Ohio. Science of the Total Environment, 2016, 553: 83-95
[42] Jiang CB, Li JK, Li HE, et al. Low-impact development facilities for stormwater runoff treatment: Field monitoring and assessment in Xi'an area, China. Journal of Hydrology, 2020, 585: 124803
[43] Mai YP, Huang GR. Hydrology and rainfall runoff pollutant removal performance of biochar-amended bioretention facilities based on field-scale experiments in lateritic red soil regions. Science of the Total Environment, 2021, 761: 143252
[44] Li H, Sharkey LJ, Hunt WF, et al. Mitigation of impervious surface hydrology using bioretention in North Carolina and Maryland. Journal of Hydrologic Engineering, 2009, 14: 407-415
[45] Hunt WF, Smith JT, Jadlocki SJ, et al. Pollutant removal and peak flow mitigation by a bioretention cell in urban Charlotte, NC. Journal of Environmental Engineering, 2008, 134: 403-408
[46] Jiang CB, Li JK, Li HE, et al. Field performance of bioretention systems for runoff quantity regulation and pollutant removal. Water, Air and Soil Pollution, 2017, 228: 468
[47] Liu JY, Davis AP. Phosphorus speciation and treatment using enhanced phosphorus removal bioretention. Environmental Science & Technology, 2014, 48: 607-614
[48] Li LQ, Davis AP. Urban stormwater runoff nitrogen composition and fate in bioretention systems. Environmental Science & Technology, 2014, 48: 3403-3410
[49] Hatt BE, Fletcher TD, Deletic A. Pollutant removal performance of field-scale stormwater biofiltration systems. Water Science and Technology, 2009, 59: 1567-1576
[50] Passeport E, Hunt WF, Line DE, et al. Field study of the ability of two grassed bioretention cells to reduce storm-water runoff pollution. Journal of Irrigation and Drainage Engineering, 2009, 135: 505-510
[51] Li H, Davis AP. Water quality improvement through reductions of pollutant loads using bioretention. Journal of Environmental Engineering, 2009, 135: 567-576
[52] Diblasi CJ, Li H, Davis AP, et al. Removal and fate of Polycyclic Aromatic Hydrocarbon pollutants in an urban stormwater bioretention facility. Environmental Science & Technology, 2009, 43: 494-502
[53] Smyth K, Drake J, Li YR, et al. Bioretention cells remove microplastics from urban stormwater. Water Research, 2021, 191: 116785
[54] Roy-Poirier A, Champagne P, Filion Y. Review of bioretention system research and design: Past, present, and future. Journal of Environmental Engineering, 2010, 136: 878-889
[55] Yang Y, Chui TFM. Optimizing surface and contributing areas of bioretention cells for stormwater runoff quality and quantity management. Journal of Environmental Management, 2018, 206: 1090-1103
[56] Zhang L, Lu Q, Ding YF, et al. A procedure to design road bioretention soil media based on runoff reduction and pollutant removal performance. Journal of Cleaner Production, 2021, 287: 125524
[57] Chui TFM, Liu X, Zhan WT. Assessing cost-effectiveness of specific LID practice designs in response to large storm events. Journal of Hydrology, 2016, 533: 353-364
[58] Zhang K, Chui TFM. Assessing the impact of spatial allocation of bioretention cells on shallow groundwater: An integrated surface-subsurface catchment-scale analysis with SWMM-MODFLOW. Journal of Hydrology, 2020, 586: 124910
[59] Tirpak RA, Hathaway JM, Khojandi A, et al. Building resiliency to climate change uncertainty through bioretention design modifications. Journal of Environmental Management, 2021, 287: 112300
[60] Ahiablame LM, Engel BA, Chaubey I. Effectiveness of low impact development practices: Literature review and suggestions for future research. Water, Air and Soil Pollution, 2012, 223: 4253-4273
[61] 李家科, 赵瑞松, 李亚娇. 基于HYDRUS-1D模型的不同生物滞留池中水分及溶质运移特征模拟. 环境科学学报, 2017, 37(11): 4150-4159
[62] Li JK, Zhao RS, Li YJ, et al. Modeling the effects of parameter optimization on three bioretention tanks using the HYDRUS-1D model. Journal of Environmental Management, 2018, 217: 38-46
[63] Li JK, Zhao RS, Li YJ, et al. Simulation and optimization of layered bioretention facilities by HYDRUS-1D model and response surface methodology. Journal of Hydrology, 2020, 586: 124813
[64] 王奇凯. 基于HYDRUS-1D模型的融雪剂对生物滞留池影响研究. 硕士论文. 哈尔滨: 哈尔滨工业大学, 2020
[65] 李家科, 刘周立, 张蓓. DRAINMOD模型研究与应用进展. 地球科学进展, 2019, 34(7): 679-687
[66] Brown RA, Skaggs RW, Hunt WF. Calibration and validation of DRAINMOD to model bioretention hydrology. Journal of Hydrology, 2013, 486: 430-442
[67] Hathaway JM, Brown RA, Fu JS, et al. Bioretention function under climate change scenarios in North Carolina, USA. Journal of Hydrology, 2014, 519: 503-511
[68] Dussaillant AR, Wu CH, Potter KW. Richards equation model of a rain garden. Journal of Hydrologic Enginee-ring, 2004, 9: 219-225
[69] 孙艳伟, 魏晓妹. 生物滞留池的水文效应分析. 灌溉排水学报, 2011, 30(2): 98-103
[70] Li H, Davis AP. Urban particle capture in bioretention media. II: Theory and model development. Journal of Environmental Engineering, 2008, 134: 419-432
[71] Li H, Davis AP. Heavy metal capture and accumulation in bioretention media. Environmental Science & Techno-logy, 2008, 42: 5247-5253
[72] He ZX, Davis AP. Unit process modeling of stormwater flow and pollutant sorption in a bioretention cell. World Environmental and Water Resources Congress 2009, Kansas City, MI, USA, 2009: 1-9
[73] Randelovic A, Zhang KF, Jacimovic N, et al. Stormwater biofilter treatment model (MPiRe) for selected micro-pollutants. Water Research, 2016, 89: 180-191
[74] He ZX, Davis AP. Process modeling of storm-water flow in a bioretention cell. Journal of Irrigation and Drainage Engineering, 2011, 137: 121-131
[75] 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. 水科学进展, 2015, 26(1): 140-150
[76] Li YQ, Zhang Y, Yu H, et al. Enhancing nitrate remo-val from urban stormwater in an inverted bioretention system. Ecological Engineering, 2021, 170: 106315
[77] Valenca R, Le H, Zu YY, et al. Nitrate removal uncertainty in stormwater control measures: Is the design or climate a culprit? Water Research, 2021, 190: 116781
[78] Hunt WF, Jarrett AR, Smith JT, et al. Evaluating bioretention hydrology and nutrient removal at three field sites in North Carolina. Journal of Irrigation and Drai-nage Engineering, 2006, 132: 600-608
[79] 孟依柯, 王媛, 汪传跃. 木屑生物炭在雨水径流中的氮磷淋出和吸附特性. 环境科学, 2021, 42(9): 4332-4340
[80] Kim HH, Seagren EA, Davis AP. Engineered bioretention for removal of nitrate from stormwater runoff. Water Environment Research, 2003, 75: 355-367
[81] Hatt BE, Fletcher TD, Deletic A. Hydrologic and pollutant removal performance of stormwater biofiltration systems at the field scale. Journal of Hydrology, 2009, 365: 310-321
[82] Lefevre GH, Paus KH, Natarajan P, et al. Review of dissolved pollutants in urban storm water and their removal and fate in bioretention cells. Journal of Environmental Engineering, 2015, 141: 04014050
[83] 王建军, 李田, 张颖. 给水厂污泥改良生物滞留填料除磷效果的研究. 环境科学, 2014, 35(12): 4642-4647
[84] Tian J, Jin J, Chiu PC, et al. A pilot-scale, bi-layer bioretention system with biochar and zero-valent iron for enhanced nitrate removal from stormwater. Water Research, 2019, 148: 378-387
[85] 郝珊, 王晨光, 张阿凤, 等. 不同物料配比对城市绿地土壤渗透性及污染物净化效果的影响. 应用生态学报, 2020, 31(4): 1349-1356
[86] Muerdter C, Özkök E, Li LQ, et al. Vegetation and media characteristics of an effective bioretention cell. Journal of Sustainable Water in the Built Environment, 2016, 2: 04015008
[87] Tirpak RA, Hathaway JM, Franklin JA. Investigating the hydrologic and water quality performance of trees in bioretention mesocosms. Journal of Hydrology, 2019, 576: 65-71
[88] Chen T, Liu Y, Zhang B, et al. Plant rhizosphere, soil microenvironment, and functional genes in the nitrogen removal process of bioretention. Environmental Science: Processes & Impacts, 2019, 21: 2070-2079
[89] Read J, Wevill T, Fletcher T, et al. Variation among plant species in pollutant removal from stormwater in biofiltration systems. Water Research, 2008, 42: 893-902
[90] Payne EGI, Fletcher TD, Russell DG, et al. Temporary storage or permanent removal? The division of nitrogen between biotic assimilation and denitrification in stormwater biofiltration systems. PLoS One, 2014, 9(3): e90890
[91] Chandrasena GI, Pham T, Payne EG, et al. E. coli removal in laboratory scale stormwater biofilters: Influence of vegetation and submerged zone. Journal of Hydrology, 2014, 519: 814-822
[92] Chen XL, Peltier E, Sturm BSM, et al. Nitrogen remo-val and nitrifying and denitrifying bacteria quantification in a stormwater bioretention system. Water Research, 2013, 47: 1691-1700
[93] Luo YH, Yue XP, Duan YQ, et al. A bilayer media bioretention system for enhanced nitrogen removal from road runoff. Science of the Total Environment, 2020, 705: 135893
[94] 石雷, 杨小丽, 吴青宇, 等. 生态沟渠-生物滞留池组合控制农村径流污染. 环境科学, 2022, 43(6): 3160-3167
[95] 陈垚, 李欣芮, 郑爽, 等. 前期干旱天数对生物滞留系统除氮性能的影响. 环境科学, 2021, 42(1): 263-273
[96] Hermawan AA, Talei A, Salamatinia B, et al. Seasonal performance of stormwater biofiltration system under tropical conditions. Ecological Engineering, 2020, 143: 105676
[97] Zinger Y, Prodanovic V, Zhang KF, et al. The effect of intermittent drying and wetting stormwater cycles on the nutrient removal performances of two vegetated biofiltration designs. Chemosphere, 2021, 267: 129294
[98] Blecken GT, Zinger Y, Muthanna TM, et al. The influence of temperature on nutrient treatment efficiency in stormwater biofilter systems. Water Science and Technology, 2007, 56: 83-91
[99] Burgis CR, Hayes GM, Zhang WH, et al. Tracking denitrification in green stormwater infrastructure with dual nitrate stable isotopes. Science of the Total Environment, 2020, 747: 141281
[100] Goor J, Cantelon J, Smart C, et al. Seasonal perfor-mance of field bioretention systems in retaining phosphorus in a cold climate: Influence of prolonged road salt application. Science of the Total Environment, 2021, 778:146069
[101] Le Coustumer S, Fletcher TD, Deletic A, et al. Hydraulic performance of biofilter systems for stormwater management: Influences of design and operation. Journal of Hydrology, 2009, 376: 16-23
[102] 唐双成, 罗纨, 贾忠华, 等. 雨水花园对暴雨径流的削减效果. 水科学进展, 2015, 26(6): 787-794
[103] Yang FK, Fu DF, Zevenbergen C, et al. A comprehensive review on the long-term performance of stormwater biofiltration systems (SBS): Operational challenges and future directions. Journal of Environmental Management, 2022, 302: 113956
[104] Costello DM, Hartung EW, Stoll JT, et al. Bioretention cell age and construction style influence stormwater pollutant dynamics. Science of the Total Environment, 2020, 712: 135597
[105] Lucke T, Nichols PWB. The pollution removal and stormwater reduction performance of street-side bioretention basins after ten years in operation. Science of the Total Environment, 2015, 536: 784-792