|
|
Research status of steel slag used for soil remediation and improvement |
LONG Hong-ming1,2, WU Hao-tian1, YU Xian-kun2,3, YE Yan-fei4, CHEN Yu5, ZHANG Hao1,2 |
1. Key Laboratory of Metallurgical Emission Reduction and Resources Recycling (Anhui University of Technology), Ministry of Education, Maanshan 243002, Anhui, China; 2. School of Metallurgical Engineering, Anhui University of Technology, Maanshan 243032, Anhui, China; 3. Sinosteel Maanshan General Institute of Mining Research Co., Ltd., Maanshan 243000, Anhui, China; 4. Baowu Environmental Technology (Zhanjiang) Resources Recycling Co., Ltd., Zhanjiang 524033, Guangdong, China; 5. College of Agro-Grassland Science, Nanjing Agricultural University, Nanjing 210095, Jiangsu, China |
|
|
Abstract According to the National Soil Pollution Survey Bulletin released by the Ministry of Environmental Protection and the Ministry of Land and Resources, heavy metal contaminated soil in China has caused serious harm to ecological environment and people's health, effective measures must be taken to repair and improve contaminated soil. Steel slag-based remediation materials are prepared by utilizing the high alkaline, porous and cementitious properties of steel slag for soil remediation and improvement, becoming one of the important ways. The physical and chemical properties of steel slag are firstly briefly introduced, steel slag-based remediation materials as soil remediation and improvement agents are specifically analyzed. Engineering application of steel slag-based remediation materials in soil remediation and improvement are pointed out respectively. Then, the development trend of steel slag-based remediation materials is reviewed. Eventually, it is proposed to optimize the properties of steel slag-based remediation materials and expand their applications in soils with different properties, and combined with lawn planting, leisure agriculture planting, agricultural landscape design and other development of a variety of steel slag-based restoration materials, which will be the main development directions of steel slag used for soil remediation and improvement in the future.
|
Received: 23 December 2022
|
|
|
|
[1] |
Wang G M,Edge W D,Woltf J O. Demographic uncertainty inecological risk assessments[J]. Ecological Modeling,2001,13(6):362.
|
[2] |
Saria L,Shimaoka T,Miyawaki K. Leaching of heavy metals in acid mine drainage[J]. Waste Management and Research,2006,24(2):134.
|
[3] |
Navarro M C,Perez S C,Martinez S M J,et al. Abandoned mine sites as a source of contamination by heavy metals:A case study in a semi-arid zone[J]. Journal of Geochemical Exploration,2008,96(2/3):183.
|
[4] |
YANG J,LIU A J,LI X L,et al. China's ion-adsorption rare earth resources,mining consequences and preservation[J]. Environmental Development,2013(8):131.
|
[5] |
Tekedil Z H,Srivastava R K. Impact of rare earth mining and processing on soil and water environment at Chavara,Kollam,Kerala:A case study[J].Procedia Earth and Planetary Science,2015,11:566.
|
[6] |
赵立杰,张芳. 钢渣资源综合利用及发展前景展望[J]. 材料导报,2020,34(增刊2):1319.
|
[7] |
ZHANG H,FANG Y. Temperature dependent photoluminescence of surfactant assisted electrochemically synthesized ZnSe nanostructures[J]. Journal of Alloys and Compounds,2019,781:201.
|
[8] |
GUO J,BAO Y,WANG M. Steel slag in China:treatment,recycling,and managemen[J]. Waste Management,2018,78:318.
|
[9] |
吴跃东,彭犇,吴龙,等. 国内外钢渣处理与资源化利用技术发展现状综述[J]. 环境工程,2021,39(1):161.
|
[10] |
ZHANG H,LI Z H. MicroRNA-16 via Twist1 inhibits EMT induced by PM2.5 exposure in human hepatocellular carcinoma[J]. Open Medicine,2019,14:673.
|
[11] |
龙红明,郑伟成,裴元东,等. 钢渣改性制备高性能化工填料的研究与应用[J]. 钢铁研究学报,2021,33(10):1076.
|
[12] |
ZHANG H. Magnetic properties and thermal stability of SrFe12O19/gamma-Fe4N composites with effective magnetic exchange coupling[J]. Ceramics International,2020,46(7):9972.
|
[13] |
Yildirim I Z,Prezzi M. Chemical,mineralogical,and morphological properties of steel slag[J]. Advances in Civil Engineering,2011:463638.
|
[14] |
李少华,宗燕兵,李宇,等. 电炉还原渣制备钢渣陶瓷的实验研究[J]. 冶金能源,2015,34(3):7.
|
[15] |
Nanukuttan S V,Basheer P A M,Mccarter W J,et al. The performance of concrete exposed to marine environments:Predictive modelling and use of laboratory/on site test methods[J]. Construction and Building Materials,2015,93:831.
|
[16] |
Fisher L V,Barron A R. The recycling and reuse of steel making slags-A review[J]. Resources,Conservation and Recycling,2019,146:244.
|
[17] |
廖杰龙. 两种工艺处理的钢渣特性研究及其循环利用分析[D]. 西安:西安建筑科技大学,2014.
|
[18] |
饶磊. 转炉钢渣成分、结构及性能间内在规律及其应用研究[D]. 北京:北京科技大学,2020.
|
[19] |
HUANG Y,XU G P,CHENG H G,et al. The 7th international conference on waste management and technology an overview of utilization of steel slag[J]. Procedia Environmental Sciences,2012,16:791.
|
[20] |
李婷,杨刚,陈华,等. 不同产出环节和处理工艺钢渣的基本性质及其利用[J]. 硅酸盐通报,2015,34(9):2619.
|
[21] |
LIAO J L,ZHANG Z H,JU J T,et al. Comparative analysis of steel slag characteristics and treatment process[J]. Advanced Materials Research,2013(10):378.
|
[22] |
李云云,倪文,李佳,等. 滚筒渣与热闷渣基础性能研究[J]. 哈尔滨工业大学学报,2020,52(12):132.
|
[23] |
WEI W U,MENG H D,LIU L,et al. Melting characteristics of recycling slag in decarburization converter and its application effects[J]. Journal of Iron and Steel Research International,2013,20:7.
|
[24] |
姚星亮,廖洪强,宋慧平,等. 钢渣超微粉理化特性[J]. 钢铁研究学报,2017,29(3):195.
|
[25] |
Humaria M S Y. Impact of iron and steel slag on crop cultivation:A review[J]. Current World Environment,2014,9(1):216.
|
[26] |
陈宗武. 钢渣理化特性及其沥青混凝土性能研究[D]. 武汉:武汉理工大学,2017.
|
[27] |
张浩,刘秀玉,刘影. XRD与SEM的钢渣尾渣物理激发机理研究[J]. 光谱学与光谱分析,2019,39(3):937.
|
[28] |
MA J F. Role of silicon in enhancing the resistance of plants to biotic and abiotic stresses[J]. Soil Science and Plant Nutrition,2004,50(1):11.
|
[29] |
SUN D D,ZHANG L L,LAI D. Stabilization of mercury using waste ladle furnace slag[J]. Journal of the Air and Waste Management Association,2013,63(12):1469.
|
[30] |
QIU H,GU H H,HE E K,et al. Attenuation of metal bioavailability in acidic multi-metal contaminated soil treated with fly ash and steel slag[J]. Pedosphere,2012,22(4):544.
|
[31] |
罗惠莉. 赤泥改性颗粒修复材料及其对铅锌污染土壤的原位稳定化研究[D]. 长沙:中南大学,2012.
|
[32] |
王孝堂. 土壤酸度对重金属形态分配的影响[J]. 土壤学报,1991,28(1):103.
|
[33] |
张学科,王琼,王文杰,等. 钢渣组分特征及其用于土壤改良的可行性初步研究[J]. 植物研究,2013,33(5):635.
|
[34] |
Epstein E. Silicon:its manifold roles in plants[J]. Annals of Applied Biology,2009,155(2):155.
|
[35] |
GU H H,QIU H,TIAN T,et al. Mitigation effects of silicon rich amendments on heavy metal accumulation in rice (Oryza sativa L.) planted on multi-metal contaminated acidic soil[J]. Chemosphere,2011,83(9):1234.
|
[36] |
杨刚. 钢渣用于Ni/Pb污染土壤原位固化稳定化修复的研究[D]. 西安:西安建筑科技大学,2020.
|
[37] |
杨刚,李辉,陈华. 钢渣微粉对重金属污染土壤的修复及机理研究[J]. 建筑材料学报,2021,24(2):318.
|
[38] |
朱李俊,刘国威,王磊,等. 钢渣对稀土矿区酸性土壤的改良效果[J]. 安徽农业科学,2016,44(6):159.
|
[39] |
张浩,于先坤,徐修平,等. 基于XRD与SEM研究风淬渣微粉用于重金属污染土壤的修复机理[J]. 光谱学与光谱分析,2021,41(1):278.
|
[40] |
魏贤. 钢渣对不同轮作制度酸性土壤改良效果及其安全性评价[D]. 武汉:华中农业大学,2015.
|
[41] |
王昭然,于巧娣,李灿华,等. 钢渣-锰渣复混肥的制备、结构与性能[J]. 中国冶金,2021,31(1):75.
|
|
|
|