不同粒径金属基纳米颗粒的性质与其环境行为和生物效应的关系

doi:10.11896/cldb.19110024

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Abstract With the rapid development of nanotechnology, relationships between the varying physicochemical properties of metal-based nanoparticles (MNPs) and their environmental behaviors or biological responses have recently received intensive attentions from researchers and policy makers. Due to the unique physiochemical properties, MNPs have been applied in various fields including agriculture, chemistry, aerospace and so on. This inevitably leads to their release into the environment, posing a great threat to environmental living organisms or even the human health. With the decrease of particle size, the properties of MNPs can be also altered such as showing a larger specific surface area, an increased surface charge density and surface energy as compared with bulk materials, which greatly affects the interface reactions and biological effects of MNPs. This paper thus reviewed the relationships between the specific surface area, the surface functional groups, the surface energy or the surface charge density of MNPs at different particle sizes and their environmental behaviors such as adsorption, aggregation and dissolution. The biological effects and the underlying mechanisms of MNPs at different particle sizes were deeply analyzed under different environmental conditions (e.g. dissolved organic matter (DOM), illumination, pH value and ionic strength). Some suggestions were put forward to improve the existing research.

Key words： nanoparticles metal-based particle size environmental behaviors biological responses

Published: 22 April 2021

CLC number:

TB303

Fund:Basic Research Project of Yunnan Province(202001AT070042), Ten Thousand People Plan of Yunnan Province(YNWR-QNBJ-2019-065), National Natural Science Foundation of China (41703111), Regional Fund (41967039), Provincial Talent Cultivation Project at KMUST (KKSY201622012).

About author:: Cong Tangraduated from Shaanxi University of Science and Technology in June 2018 with a bachelor of science degree. She is now a postgraduate student in the Faculty of Environmental Science and Engineering, Kunming University of Science and Technology, conducting research under the guidance of Associate Professor Yang Liu. At present, the main research area is the environmental behavior of copper oxide nanoparticles with different particle sizes.
Yang Liuis an associate professor of Faculty of Environmental Science and Engineering at Kunming University of Science and Technology. Bachelor graduated from College of Water Resources & Civil Engineering, China Agricultural University in July 2009, and master's degree was obtained at the same place in September 2011. In 2015, she received her PhD in environmental sciences, Faculty of Science, Leiden University, the Netherlands since August 2017. She has been working in the Department of Environmental Science, Faculty of Environmental Science and Engineering, Kunming University of Science and Technology. She is an associate professor and supervisor for postgraduate students. In
2019, she was selected as the “Ten Thousand Person Program” of Yunnan Province. Mainly engaged in evaluation and prediction of ecological toxicity effects of pollutants, toxicity mechanism of mixed pollutants, environmental behavior and health risk assessment of nanomaterials, interaction between natural organic matter and pollutants, and biological effects of free radicals in biochar. In recent years, nearly 20 articles have been published in the field of environmental science, including Environmental Science & Technology, Environmental Pollution, Water Research, Chemosphere, Frontiers of Environmental Science & Engineering, etc.

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Cite this article:

TAN Cong,LIU Yang,HE Ying, et al. Relationships Between the Properties of Metal-based Nanoparticles with Different Particle Sizes and Their Environmental Behaviors and Biological Responses[J]. Materials Reports, 2021, 35(7): 7121-7126.

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http://www.mater-rep.com/EN/10.11896/cldb.19110024 OR http://www.mater-rep.com/EN/Y2021/V35/I7/7121

1 Song X N, Wang H B, Wu X L, et al. Chemical Industry and Enginee-ring Progress, 2005, 24(1), 47(in Chinese).
宋晓岚, 王海波, 吴雪兰, 等. 化工进展, 2005, 24(1), 47.
2 Liu W P, Qiu D F, Lu H M. Industrial Minerals & Processing, 2003(12), 1(in Chinese).
刘维平, 邱定蕃, 卢惠民. 化工矿物与加工, 2003(12), 1.
3 Piccinno F, Gottschalk F, Seeger S, et al. Journal of Nanoparticle Research, 2012, 14(9), 1109.
4 Zhang Y Q, Zhu Y L. Materials Review, 2012, 26(s1), 23(in Chinese).
张艳奇, 朱友利.材料导报, 2012, 26(专辑19), 23.
5 Porter A E, Gass M, Muller K, et al. Nature Nanotechnology, 2007, 2(11), 713.
6 Moore M N. Environment International, 2006, 32(8), 967.
7 Choi O, Hu Z Q. Environmental Science & Technology, 2008, 42(12), 4583.
8 Dehner C A, Barton L, Maurice P A, et al. Environmental Science & Technology, 2011, 45(3), 977.
9 Badwaik V D, Vangala L M, Pender D S, et al. Nanoscale Research Letters, 2012, 7(1), 623.
10 Lamber R, Wetjen S, Jaeger N I. Physical Review B, Condensed Matter, 1995, 51(16), 10968.
11 Ayyub P, Palkar V R, Chattopadhyay S, et al. Physical Review B, Condensed Matter, 1995, 51(9), 6135.
12 Barnard A S, Yeredla R R, Xu H F. Nanotechnology, 2006, 17(12), 3039.
13 Xiao H X, Long C S. Acta Physica Sinica, 2013(10), 111(in Chinese).
肖红星, 龙冲生. 物理学报, 2013(10), 111.
14 Li G S, Cai P X, Gan L P, et al. Journal of East China University of Science and Technology(Natural Science Edition), 2006, 32(1), 47(in Chinese).
李根深, 蔡平雄, 甘路平, 等. 华东理工大学学报(自然科学版),2006, 32(1), 47.
15 Qi H F, Liu D B, Luo F, et al. Rare Metal Materials and Engineering,2015, 44(4), 887(in Chinese).
祁洪飞, 刘大博, 罗飞, 等. 稀有金属材料与工程, 2015, 44(4), 887.
16 Liu Z H. Studies and applications of the separation and preconcentration of trace elements with nanometer titanium dioxide and determination by atomic absorption spectrometry. Master's Thesis, Xiangtan University, China, 2007(in Chinese).
刘正华. 纳米二氧化钛在分离富集-原子吸收光谱法测定痕量元素中的研究与应用. 硕士学位论文, 湘潭大学, 2007.
17 Xia X Y.Particle size on dissolution of thermodynamics and kinetics of nanoparticles. Master's Thesis, Taiyuan University of Technology, China, 2014(in Chinese).
夏晓艳. 粒度对纳米颗粒溶解热力学与动力学的影响. 硕士学位论文, 太原理工大学, 2014.
18 Rustad J R, Felmy A R. Geochimica Et Cosmochimica Acta, 2005, 69(6), 1405.
19 Jayalath S, Wu H, Larsen S C, et al. Langmuir, 2018, 34(9), 3136.
20 Mélanie A, Jérôme R, Proux O, et al. Langmuir, 2008, 24(7), 3215.
21 Suttiponparnit K, Jiang J, Sahu M, et al. Nano Scale Research Letters, 2011, 6(1), 27.
22 Zhang W, Yao Y, Sullivan N, et al. Environmental Science & Technology, 2011, 45(10), 4422.
23 Peretyazhko T S, Zhang Q, Colvin V L. Environmental Science & Technology, 2014, 48(20), 11954.
24 Barton L E, Grant K E, Kosel T, et al. Environmental Science & Technology, 2011, 45(8), 3231.
25 Wijenayaka L A, Rubasinghege G, Baltrusaitis J, et al. The Journal of Physical Chemistry C, 2012, 116(23), 12566
26 Venugopal E, Aswal V K, Kumaraswamy G. Langmuir, 2013, 29(31), 9643.
27 Yao Y, Wei Y, Chen S H. Surface Science, 2015, 636, 19.
28 Nanda K K, Maisels A, Kruis F E, et al. Physical Review Letters, 2003, 91(10),106102.
29 Vitos L, Ruban A V, Skriver H L, et al. Surface Science, 1998, 411(1-2), 186.
30 Cui J Q, Zhang Y, Lu X C, et al. Materials Reports B: Research Papers, 2009, 23(12), 95(in Chinese).
崔举庆, 张洋, 陆现彩, 等. 材料导报:研究篇, 2009, 23(12), 95.
31 Anschutz A J, Lee P R. Geochemical Transactions, 2005, 6(3), 60.
32 Pettibone J M, Cwiertny D M, Scherer M, et al. Langmuir the ACS Journal of Surfaces & Colloids, 2008, 24(13), 6659.
33 Prabhu B M, Ali S F, Murdock R C, et al. Nanotoxicology, 2010, 4(2), 150.
34 Guangchao C, Martina V, Yinlong X, et al. Materials, 2017, 10(9),1013.
35 Chen Y F. Journal of Taiyuan Normal University(Natural Science Edition, 2012(1), 136(in Chinese).
陈燕飞.太原师范学院学报(自然科学版), 2012(1), 136.
36 Yu J Q. Environmental Pollution and Control, 1996(4), 28(in Chinese).
郁建栓. 环境污染与防治, 1996(4), 28.
37 Handy R, Von-Der-Kammer F J, Hassellov M, et al. Ecotoxicology, 2008, 17(4), 287.
38 Lanzl C A, Baltrusaitis J, Cwiertny D M. Langmuir, 2012, 28(45), 15797.
39 Rippner D A, Green P G, Young T M, et al. Environmental Pollution, 2018, 234, 692.
40 Angela I, Imbi K, Kaja K, et al. PLOS ONE, 2014, 9(7), e102108.
41 Santo N, Fascio U, Torres F, et al. Water Research, 2014, 53, 339.
42 Xiao Y L, Vijver M G, Chen G, et al. Environmental Science & Techno-logy, 2015, 49(7), 4657.
43 Lin D H, Ji J, Tian X L, et al. Chinese Science Bulletin, 2009, 54(23), 3590(in Chinese).
林道辉, 冀静, 田小利, 等. 科学通报, 2009, 54(23), 3590.
44 Lu X J, Li N, Jiang J X, et al. Acta Scientiae Circumstantiae,2018, 38(9), 376(in Chinese).
陆香君, 李宁, 蒋锦晓, 等. 环境科学学报, 2018, 38(9), 376.
45 Kong I C, Raliya R,Ko K, et al. Environmental Engineering Science, 2018, 35(3), 231.
46 Liu T, Xiang L, Yu Z X. China Environmental Science, 2015, 35(5), 1480(in Chinese).
刘涛, 向垒, 余忠雄, 等. 中国环境科学, 2015, 35(5), 1480.
47 Gajewicz A, Schaeublin N, Rasulev B, et al. Nanotoxicology, 2015, 9(3), 313.
48 Lin D, Ji J, Long Z, et al. Water Research (Oxford), 2012, 46(14), 4477.
49 Thabitha R, Hwang H M. Journal of Environmental Sciences, 2013(9), 1925.
50 Wang Z, Li J, Zhao J, et al. Environmental Science & Technology, 2011, 45(14), 6032.
51 Ghosh S, Mashayekhi H, Pan B, et al. Langmuir, 2008, 24(21), 12385.
52 Lovern S B, Klaper R. Environmental Toxicology and Chemistry,2006, 25(4), 1132.
53 Wang L F. Interactions between natural organic matter (NOM) and metal ions/nanoparticles and their effects in membrane fouling process.Ph.D.Thesis, University of Science and Technology of China, China, 2016(in Chinese).
王龙飞. 天然有机质与金属离子/纳米颗粒的相互作用及其对膜污染过程的影响. 博士学位论文,中国科学技术大学,2016.
54 Li J. The toxic mechanism of CuO nanoparticles to microcystis aeruginosa as affected by dissolved organic matter. Master's Thesis, Ocean University of China, China, 2011(in Chinese).
李静, 溶解有机质影响下CuO纳米颗粒对铜绿微囊藻的致毒机制. 硕士学位论文,中国海洋大学,2011.
55 Adams L K, Lyon D Y, Alvarez P J J. Water Research, 2006, 40(19), 3527.
56 Song W H, Liu Y, Gao M L. Journal of Tianjin Normal University(Natural Science Edition), 2009, 29(3), 51(in Chinese).
宋文华, 刘艳, 高敏苓, 等. 天津师范大学学报(自然科学版), 2009, 29(3), 51.
57 Zhao X, Toyooka T, Ibuki Y. Science of the Total Environment, 2013, 458-460, 54.
58 Wilke C M, Wunderlich B, Gaillard J F, et al. Environmental Science & Technology, 2018, 52(5), 3185.
59 Oukarroum A, Samadani M, Dewez D. Water, Air & Soil Pollution, 2014, 225(8), 1.
60 Park M V D Z, Neigh A M, Vermeulen J P, et al. Biomaterials, 2011, 32(36), 9810.
61 Gregory J. Journal of Colloid and Interface Science, 1975, 51(1), 44.
62 Zhang R C, Zhang H B, Tu C, et al. Environmental Chemistry, 2014, 33(11), 1821(in Chinese).
张瑞昌, 章海波, 涂晨, 等. 环境化学, 2014, 33(11), 1821.
63 Han L. The toxic effects and mechanism of man-made nanoparticles of ZnO to flounder cells FG and zebrafish embryos. Master's Thesis, Ocean University of China, China, 2012(in Chinese).
韩利. 人工纳米氧化锌颗粒对牙鲆FG细胞和斑马鱼胚胎的毒性及其毒性作用机制. 硕士学位论文, 中国海洋大学, 2012.
64 Feris K, Otto C, Tinker J, et al. Langmuir the ACS Journal of Surfaces & Colloids, 2010, 26(6), 4429.