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2024 Vol.29, Issue 6 Preview Page
31 December 2024. pp. 49-59
Abstract
References

References

1

Akiyama, M., Shinkai, Y., Unoki, T., Shim, I., Ishii, I., and Kumagai, Y., 2017, The Capture of Cadmium by Reactive Polysulfides Attenuates Cadmium-Induced Adaptive Responses and Hepatotoxicity, Chem. Res. Toxicol., 30(11), 2209-2217.

10.1021/acs.chemrestox.7b00278
2

Aratani, T., Yasuhara, S., Matoba, H., and Yano, T., 1979, Continuous Removal of Heavy metals by the Lime Sulfurated Solution (Calcium Polysulfide) Process, Bull. Chem. Soc. Jpn., 52(1), 218-222.

10.1246/bcsj.52.218
3

Asmare, G., Getachew, B., Kassa, T., and Abate, W., 2021, Tannery wastewater treatment by coagulation-flocculation technique using combination of calcium polysulfide and ferrous sulphate, Am. J. Chem. Eng., 9(4), 79-83.

10.11648/j.ajche.20210904.11
4

Aspillaga, L., Bautista, D.J., Daluz, S.N., Hernandez, K., Renta, J.A., and Lopez, E.C.R., 2023, Nucleation and crystal growth: Recent advances and fufture trends, Eng. Proc., 56, 22.

10.3390/asec2023-15281
5

Cheng, S., Hong, X., Tang, H., Chu, Y., and Huang, C., 2018, Preparation of calcium polysulfide to remediate groundwater contaminated by hexavalent chromium, Proc. AMMMS, 518-524.

10.12783/dtcse/ammms2018/27335
6

Choi, H.M. and Lee, J.Y., 2009, Green remediation: Choice for low CO2 emission in soil and groundwater remediation, J. Soil Groundw. Environ., 14(1), 11-17.

7

Chrysochoou, M. and Ting, A., 2011, A kinetic study of Cr(VI) reduction by calcium polysulfide, Sci. Total Environ., 409(19), 4072-4077.

10.1016/j.scitotenv.2011.06.015
8

Chrysochoou, M., Ferreira, D.R., and Johnston, C.P., 2010, Calcium polysulfide treatment of Cr(VI)-contaminated soil, J. Hazard. Mater., 179(1-3), 650-657.

10.1016/j.jhazmat.2010.03.052
9

Chrysochoou, M., Johnston, C.P., and Dahal, G., 2011, A comparative evaluation of hexavalent chromium treatment in contaminated soil by calcium polysulfide and green-tea nanoscale zero-valent iron, J. Hazard. Mater., 201-202, 33-42.

10.1016/j.jhazmat.2011.11.003
10

Cui, Y., Liao, Y., Sun, Y., Wang, W., Wu, J., Dai, W., and Huang, T., 2024, Advanced XPS-based techniques in the characterization of catalytic materials: A mini-review, Catalysts, 14(9), 595.

10.3390/catal14090595
11

Dahlawi, S.M. and Siddiqui, S., 2017, Calcium polysulphide, its applications and emerging risk of environmental pollution—A review article, Environ. Sci. Pollut. Res., 24, 7842-7856.

10.1007/s11356-016-7842-3
12

Dupin, J.C., Gonbeau, D., Vinatier, P., and Levasseur, A., 2000, Systematic XPS studies of metal oxides, hydroxides and peroxides. Phys. Chem. Chem. Phys., 2(6), 1319-1324.

10.1039/a908800h
13

EFSA, 2010, Conclusion on the peer reviewed of the pesticide risk assessment of the active substances lime sulfur, J. EFSA, 8(11), 1890.

10.2903/j.efsa.2010.1890
14

Esalah, J.O., Weber, M.E., and Vera, J.H., 2000, Removal of lead, cadmium and zinc from aqueous solutions by precipitation with sodium Di-(n-Octyl) phosphinate, Can. J. Chem. Eng., 78(5), 945-952.

10.1002/cjce.5450780512
15

Estay, H., Barros, L., and Troncoso, E., 2021, Metal sulfide precipitation: Recent breakthroughs and future outlooks, Minerals, 11(12), 1385.

10.3390/min11121385
16

Fantauzzi, M., Elsener, B., Atzei, D., Rigoldi, A., and Rossi, A., 2015, Exploiting XPS for the identification of sulfides and polysulfides, RSC Advances, 5, 75953-75963.

10.1039/c5ra14915k
17

Finney, A.R. and Salvalaglio, M., 2023, Theoretical and computational approaches to study crystal nucleation from solution, Wiley, New York, NY.

10.26434/chemrxiv-2023-rb79v
18

Fruchter, J., 2002, Peer reviewed: In-situ treatment of chromium-contaminated groundwater, Environ. Sci. & Tech., 36(23), 464A-472A.

10.1021/es022466i
19

Go, H.W., 2023, Application of Calcium polysulfide in various media for remediation of high concentration heavy metal contaminated groundwater, MS diss., Hanbat National University.

20

Gross, S., Vittadini, A., and Dengo, N., 2016, Functionalisation of colloidal transition metal sulphides nanocrystals: A fascinating and challenging playground for the chemist, Crystals, 7(4), 110.

10.3390/cryst7040110
21

Hillis, B.G., Losey, B.P., Weng, J., Ghaleb, N., Hou, F., and Martin, J.D., 2017, From rate measurements to mechanistic data for condensed matter reactions: A case study using the crystallization of [Zn(OH2)6][ZnCl4], Crystals, 7(1), 11.

10.3390/cryst7010011
22

Hu, S., Li, D., Man, Y., Wen, Y., and Huang, C., 2021, Evaluation of remediation of Cr(VI)-contaminated soils by calcium polysulfide: Long-term stabilization and mechanism studies, Sci. Total Environ., 790, 148140.

10.1016/j.scitotenv.2021.148140
23

Huang, C.Y., Cheng, P.C., Chang, J.H., Wan, Y.C., Hong, X.M., and Cheng, S.F., 2021, Feasibility of remediation lead, Nickel, Zinc, Copper, and cadmium-contaminated groundwater by calcium sulfide, Water, 13(16), 2266.

10.3390/w13162266
24

Jo, Y.D., Kim, H.S., and Ahn, J.W., 2007, Precipitation characteristics of heavy metal ions in coal mine drainage, J. Miner. Soc. Korea, 20(2), 125-134.

25

Jung, M.C. and Jung, M.Y., 2006, Evaluation and management method of environmental contamination from abandoned metal mines in Korea, J. Korean Soc. Miner. Energy Resour. Eng., 43(5), 283-394.

26

Kapusta, P. and Sobczyk, L., 2015, Effects of heavy metal pollution from mining and smelting on enchytraeid communities under different land management and soil conditions, Sci. Total. Environ., 536(1), 517-526.

10.1016/j.scitotenv.2015.07.086
27

Kotula, P.G., Keenan, M.R., and Michael, J.R., 2003, Automated analysis of SEM X-ray spectral images: A powerful new microanalysis tool, Microscopy and Microanalysis., 9(1), 1-17.

10.1017/s1431927603030058
28

Kubier, A., Wilkin, R.T., and Pichler, T., 2019, Cadmium in Soils and Groundwater: A Review, Appl. Geochem., 108, 104388.

10.1016/j.apgeochem.2019.104388
29

Lee, G.M., Kim, G.R., Choi, S.K., and Lee, T.J., 2020, A study on adsorption of heavy metals with zeolite and FeS Media, J. Korean. Soc. Environ. Eng., 42(7), 349-359.

10.4491/ksee.2020.42.7.349
30

Lee, S.W., Kim, J.J., Park, M.J., Lee, S.H., and Kim, S.O., 2015, Human risk assessment of arsenic and heavy metal contamination and estimation of remediation concentration within abandoned metal mine area, J. miner. Soc. Korea, 28(4), 309-323.

10.9727/jmsk.2015.28.4.309
31

Leite, E.R. and Ribeiro, C., 2011, Crystallization and Growth of Colloidal Nanocrystals, Springer, New York, US.

32

Lewis, A.E., 2010, Review of Metal Sulfide Precipitation, Hydrometallurgy, 104, 222-234.

10.1016/j.hydromet.2010.06.010
33

Lewis, A. E., Seckler, M., Kramer, H., and Rosmalen, G., 2015, Industrial crystallization: Fundamentals and Applications. England.

10.1017/cbo9781107280427
34

Li, Y.Y. and Zhang, T.T., 2021, Stability properties of chromium in Cr(VI)-contaminated soil stabilized by calcium polysulfide (CaS5), Nature Environ. & Pollut. Tech., 20(1), 377-383.

10.46488/nept.2021.v20i01.044
35

Luther, G.W., Theberge, S.M., and Rickard, D.T., 1999, Evidence for aqueous clusters as intermediates during zinc sulfide formation, Geochimica et Cosmochimica Acta, 63(19-20), 3159-3169.

10.1016/s0016-7037(99)00243-4
36

McGinty, J., Yazdanpanah, N., Price, C., ter Horst, J.H., and Sefcik, J., 2020, Nucleation and crystal growth in continuous crystallization, handbook of continuous crystallization, The Royal Soc. of Chem., 1-16.

10.1039/9781788013581-00001
37

Migdisov, A.A., Willians-Jones, A.E., Lakshtanov, L.Z., and Alekhin, Y.V., 2002, Estimates of the second dissociation constant of H2S from the surface sulfidation of crystalline sulfur, Geochimina et Cosmochimica Acta, 66(10), 1713-1725.

10.1016/s0016-7037(01)00896-1
38

Mpouras, T., Papassiopi, N., Lagkouvardos, K., Mystrioti, C., and Dermatas, D., 2020, Evaluation of calcium polysulfide as a reducing agent for the restoration of a Cr(VI)-contaminated aquifer, Bull. Environ. Contam. Toxicol., 105, 45-52.

10.1007/s00128-020-02890-1
39

Pohl, A., 2020, Removal of heavy metal ions from water and wastewaters by sulfur-containing precipitation agents, Water Air Soil Pollut., 231, 503.

10.1007/s11270-020-04863-w
40

Prokkola, H., Nurmesniemi, E.-T., and Lassi, U., 2020, Removal of metals by sulphide precipitation using Na2S and HS− solution, ChemEngineering, 4(3), 51.

10.3390/chemengineering4030051
41

Qian, Y., da Silva, A., Yu, E., Anderson, C.L., Liu, Y., Theis, W., Ercius, P., and Xu, T., 2021, Crystallization of nanoparticles induced by precipitation of trace polymeric additives, Nature Communications, 12(1), 2767.

10.1038/s41467-021-22950-2
42

Sankhla, M.S. and Kumar, R., 2019, Contaminant of heavy metals in groundwater & its toxic effects on human health & environment, Int. J. Environ. Sci. Nat. Resour., 18(5), 555996.

10.19080/ijesnr.2019.18.555996
43

Simon, P., Baldovino-Medrano, V.G., and Wojcieszak, R., 2022, X-Ray photoelecrton spectroscopy (XPS): Principles and application for the analysis of photoactive materials, Springer, 249-271.

10.1007/978-3-030-63713-2_10
44

Soya, K., Mihara, N., Kuchar, D., Kubota, M., Matsuda, H., and Fukuta, T., 2008, Selective sulfidation of copper, zinc and nickel in plating wastewater using calcium sulfide, World Acad. Sci. Eng. Technol., 44, 356-362.

10.4139/sfj.59.465
45

Teh, C.Y., Budiman, P.M., Shak, K.P.Y., and Wu, T.Y., 2016, Recent advancement of coagulation-flocculation and its application in wastewater treatment, Ind. Eng. Chem. Res., 55(14), 4363-4389.

10.1021/acs.iecr.5b04703
46

Tu, C., Guan, F., Sun, Y., Guo, P., Liu, Y., Li, L., Scheckel, K.G., and Luo, Y., 2018, Stabilizing effects on a cadmium polluted coastal wetland soil using calcium polysulphide, Geoderma, 332, 190-197.

10.1016/j.geoderma.2018.07.013
47

U.S. DOE, 2007, Internet ref. https://www.ibl.gov/ERSP

48

U.S. EPA, 1999, Field applications of in situ remediation technologies: Permeable reactive barriers, DIANE Publishing.

49

U.S. EPA, 2000, Permeable Reactive Barriers for Inorganics, Washington, DC, 1-55.

50

U.S. FRTR, 2024, https://www.frtr.gov/matrix/Groundwater-Pump-and-Treat/

51

Wielinski, J., Huang, X., and Lowry, G.V., 2024, Characterizing the stoichiometry of individual metal sulfide and phosphate colloids in soils, sediments, and industrial processes by inductively coupled plasma time-of-flight mass spectrometry, Environ. Sci. Technol., 58, 12113-12122.

10.1021/acs.est.3c10186
52

Wright, K.E., Hartmann, T., and Fujita, Y., 2011, Inducing mineral precipitation in groundwater by addition of phosphate, Geochemical Transactions, 12, 8.

10.1186/1467-4866-12-8
53

XPS Database, XPS Reference Database, https://xpsdatabase.net/

54

XPS Periodic Table, Thermo Fisher Scientific., 2024, https://www.thermofisher.com/kr/ko/home/materials-science/learning-center/periodic-table/non-metal/oxygen.html

55

Yahikozawa, K., Aranani, T., Ito, R., Supo, T., and Yano, T., 1978, Kinetic studies on the lime sulfurated solution (Calcium Polysulfide) process for removal of heavy metals from wastewater, Bull. Chem. Soc. Jpn., 51(2), 613-617.

10.1246/bcsj.51.613
56

Yin, Y. and Allen, H.E., 1999, In situ chemical treatment, ground-water remediation technologies analysis center (GWRTAC), Pittsburgh, PA, 1-60.

57

Yoon, S., Jeong, S., Moon, C., and Nam, K., 2024, Removal of cadmium and zinc by calcium polysulfide in acidic groundwater: Injection ratio and precipitation mechanism, Chemosphere, 364, 143219.

10.1016/j.chemosphere.2024.143219
58

Zhang, T., Wang, T., Wang, W., Liu, B., and Liu, Y., 2020, Reduction and stabilization of Cr(VI) in soil by using calcium polysulfide: Catalysis of natural iron oxides, Environmental Research, 190, 109992.

10.1016/j.envres.2020.109992
59

Zhang, X., Wu, H., Fu, E., and Wang, Y., 2019, In-depth characterization of secondary phases in Cu2ZnSnS4 film and its application to solar cells, Nanomaterials, 9(6), 855

10.3390/nano9060855
60

Zhao, X., Joo, J.C., Kim, D., Lee, J.K., and Kim, J.Y., 2016, Estimation of the seedling vigor index of sunflowers treated with various heavy metals, J. Bioremediat. Biodegrad., 7(3),353.

10.4172/2155-6199.1000353
61

Zhao, X., Joo, J.C., Lee, J.K., and Kim, J.Y., 2019, Mathematical estimation of heavy metal accumulations in helianthus annuus L. with a sigmoid heavy metal uptake model, Chemosphere, 220, 965-973.

10.1016/j.chemosphere.2018.12.210
62

Zhong, L., Qafoku, N.P., Szecsody, J.E., Dresel, P.E., and Zhang, Z.F., 2009, Foam delivery of calcium polysulfide to the vadose zone for chromium(VI) immobilization: A laboratory evaluation, Vadose Zone J., 8(4), 976-985.

10.2136/vzj2008.0124
Information
  • Publisher :The Korean Society of Soil and Groundwater Environment
  • Publisher(Ko) :한국지하수토양환경학회
  • Journal Title :Journal of Soil and Groundwater Environment
  • Journal Title(Ko) :지하수토양환경
  • Volume : 29
  • No :6
  • Pages :49-59
  • Received Date : 2024-10-19
  • Revised Date : 2024-11-18
  • Accepted Date : 2024-11-22