Hydrogeochemical Site Descriptive Modeling Development Methodology for Deep Geological Disposal of High-Level Radioactive Waste: A Review of the Swedish Forsmark Case
Ho-Rim Kim^1*, Heewon Jung², SeHyeok Park¹, Hanna Choi¹, Hanna Kim¹,
Junseop Oh³, Jeong-Hwan Lee⁵, and Seong-Taek Yun⁴
¹Korea Institute of Geoscience and Mineral Resources, Daejeon 34132, Republic of Korea
²Chungnam National University, Daejeon 34134, Republic of Korea
³Korea University, Seoul 02841, Republic of Korea
⁴Korea Radioactive Waste Agency, Republic of Korea
고준위 방사성폐기물 심층처분을 위한 수리지구화학 부지기술모델 설정 및 개발 방법론: 스웨덴 Forsmark 사례를 중심으로
김호림^1*ㆍ정희원²ㆍ박세혁¹ㆍ최한나¹ㆍ김한나³ㆍ오준섭⁴ㆍ이정환⁵ㆍ윤성택⁴
¹한국지질자원연구원, ²충남대학교, ³수원대학교, ⁴고려대학교, ⁵한국원자력환경공단
This article is an open access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

References

1. Andersson, J., 2003, Site descriptive modelling – strategy for integrated evaluation: SKB R-03-05, Svensk Karnbranslehantering AB, Stockholm, 44 p.
2. Chae, G.T., Yun, S.T., Kim, K., and Mayer, B., 2006, Hydrogeochemistry of sodium-bicarbonate type bedrock groundwater in the Pocheon spa area, South Korea: water–rock interaction and hydrologic mixing, Jour. Hydrol., 321(1-4), 326-343.
3. Choi, B.-Y., Koh, Y.-K., Yun, S.-T., and Kim, G.-Y., 2008, Conceptual modeling on the adsorption and transport of uranium using 3-D groundwater flow and reactive transport models, Econ. Environ. Geol., 41(6), 719-729.
4. Choi, J., Yu, S., Park, S., Park, J., and Yun, S.-T., 2022, Status and implications of hydrogeochemical characterization of deep groundwater for deep geological disposal of HLW in developed countries, Econ. Environ. Geol., 55(6), 737-760 (in Korean with English abstract).
5. Choi, J., Park, S., Seo, H., Ahn, H.T., Lee, J.H., Park, J., and Yun, S.T., 2023, Geochemical Modeling on Behaviors of Radionuclides (U, Pu, Pd) in Deep Groundwater Environments of South Korea. Econ. Environ. Geol., 56(6), 847-870 (in Korean with English abstract).
6. Follin, S., 2008, Bedrock hydrogeology Forsmark. Site descriptive modelling, SDM-Site Forsmark: SKB R-08-95, Svensk Karnbranslehantering AB, Stockholm, 163 p.
7. Follin, S., Stephens, M.B., Laaksoharju, M., Nilsson, A.-C., Smellie, J.A.T., and Tullborg, E.-L., 2008, Modelling the evolution of hydrochemical conditions in the Fennoscandian Shield during Holocene time using multidisciplinary information, Appl. Geochem., 23(7), 2004-2027.
8. Geier, J.E., Bath, A.H., and Stephansson, O., 2012, Comparison of site descriptive models for Olkiluoto, Finland and Forsmark, Sweden: STUK-TR 14, Radiation and Nuclear Safety Authority, Helsinki, 190 p.
9. Gimeno, M.J., Auque, L.F., Gomez, J.B., and Acero, P., 2008, Water-rock interaction modelling and uncertainties of mixing modelling. Site descriptive modelling SDM-Site Forsmark: SKB R-08-86, Svensk Karnbranslehantering AB, Stockholm, 159 p.
10. Hallbeck, L. and Pedersen, K., 2008, Explorative analysis of microbes, colloids and gases together with microbial modelling. Site descriptive modelling SDM-Site Forsmark: SKB R-08-85, Svensk Karnbranslehantering AB, Stockholm, 180 p.
11. Hyman, J.D., Karra, S., Makedonska, N., Gable, C.W., Painter, S.L., and Viswanathan, H.S., 2015, dfnWorks: A discrete fracture network framework for modeling subsurface flow and transport, Comput. Geosci., 84, 10-19.
12. IAEA, 2011, Disposal of Radioactive Waste: IAEA Safety Standards Series No. SSR-5, International Atomic Energy Agency, Vienna, 62 p.
13. Kalinowski, B.E. (ed.), 2008, Background complementary hydrogeochemical studies. Site descriptive modelling SDM-Site Forsmark: SKB R-08-87, Svensk Karnbranslehantering AB, Stockholm, 148 p.
14. Kim, J.-W., Kim, J.-S., Lee, C., Kwon, S., Ko, N.-Y., and Kim, G. Y., 2023, KAERI underground research laboratory: Overview of in-situ experiments, Rock Mech. Bull., 2(3), 100059.
15. Kim, J.H., Kim, K.H., Thao, N.T., Batsaikhan, B., and Yun, S.T., 2017, Hydrochemical assessment of freshening saline groundwater using multiple end-members mixing modeling: A study of Red River delta aquifer, Vietnam, Jour. Hydrol., 549, 703-714.
16. Kim, K.H., Yun, S.T., Yu, S., Choi, B.Y., Kim, M.J., and Lee, K.J., 2020, Geochemical pattern recognitions of deep thermal groundwater in South Korea using self-organizing map: Identified pathways of geochemical reaction and mixing, Jour. Hydrol., 589, 125202.
17. Kwon, E., Kwon, J.-S., Park, K.-W., and Ju, Y.J., 2025, A comparative review on groundwater hydrogeochemistry in countries preferring crystalline rock for deep geological disposal, Nucl. Eng. Technol., 57(6), 103463.
18. Laaksoharju, M., Skarman, C., and Skarman, E., 1999, Multivariate Mixing and Mass-balance (M3) calculations, a new tool for decoding hydrogeochemical information, Appl. Geochem., 14(7), 861-871.
19. Laaksoharju, M., Smellie, J., Tullborg, E.-L., Gimeno, M., Hallbeck, L., Molinero, J., and Waber, N., 2008, Bedrock hydrogeochemistry Forsmark. Site descriptive modelling SDM-Site Forsmark, SKB R-08-47, Svensk Karnbranslehantering AB, Stockholm, 160 p.
20. Morris, M.D., 1991, Factorial sampling plans for preliminary computational experiments, Technometrics, 33(2), 161-174.
21. NEA, 2008, Moving Forward with Geological Disposal of Radioactive Waste: NEA No. 6433, OECD Nuclear Energy Agency, Paris, 22 p.
22. Park, S., Cho, S., Kim, K.Y., and Lee, J., 2024, Strategy for rock mechanics and thermal properties site descriptive modeling for high-level waste disposal based on case studies, Tunnel Undergr. Space, 34(6), 543-563.
23. Parkhurst, D.L. and Appelo, C.A.J., 2013, Description of input and examples for PHREEQC version 3 – A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations: USGS Techniques and Methods, book 6, chap. A43, 497 p.
24. Ryu, J.-H., Cho, S.-J., Hama, K., Yoshida, H., Shin, H.-S., and Kwon, J.-S., 2012, Geochemical characterization of deep groundwater in the KAERI Underground Research Tunnel (KURT) using geochemical modeling, J. Environ. Eng., 138(3), 377-385.
25. Saltelli, A., Ratto, M., Andres, T., Campolongo, F., Cariboni, J., Gatelli, D., Saisana, M., and Tarantola, S., 2008, Global Sensitivity Analysis, The Primer, John Wiley & Sons, Chichester, 292p.
26. SKI, 1996, SITE-94: Deep repository performance assessment project: SKI Report 96:36, Swedish Nuclear Power Inspectorate, Stockholm.
27. SKB, 2000, Geoscientific programme for investigation and evaluation of sites for the deep repository: SKB TR-00-20, Svensk Karnbranslehantering AB, Stockholm.
28. SKB, 2010, Model summary report for the safety assessment SR-Site: SKB TR-10-51, Svensk Karnbranslehantering AB, Stockholm, 545 p.
29. Smellie, J., Laaksoharju, M., and Tullborg, E.-L., 2002, Hydrogeochemical site descriptive model – a strategy for the model development during site investigations: SKB R-02-49, Svensk Karnbranslehantering AB, Stockholm, 71 p.
30. Smellie, J., Tullborg, E.-L., Nilsson, A.-C., Sandstrom, B., Waber, N., Gimeno, M., and Gascoyne, M., 2008, Explorative analysis and expert judgement of major components and isotopes. Site descriptive modelling SDM-Site Forsmark: SKB R-08-84, Svensk Karnbranslehantering AB, Stockholm, 216 p.
31. Sobol', I.M., 2001, Global sensitivity indices for nonlinear mathematical models and their Monte Carlo estimates, Math. Comput. Simul., 55, 271-280.
32. Steefel, C.I., Appelo, C.A.J., Arora, B., Jacques, D., Kalbacher, T., Kolditz, O., Lagneau, V., Lichtner, P.C., Mayer, K.U., Meeussen, J.C.L., Molins, S., Moulton, D., Shao, H., Simunek, J., Spycher, N., Yabusaki, S.B., and Yeh, G.T., 2015, Reactive transport codes for subsurface environmental simulation, Comput. Geosci., 19(3), 445-478.
33. Ström, A., Andersson, J., Skagius, K., and Winberg, A., 2008, Site descriptive modelling during characterization for a geological repository for nuclear waste in Sweden, Appl. Geochem., 23, 1747-1760.
34. Waber, N., Gimmi, T., and Smellie, J., 2009, Porewater in the rock matrix. Site descriptive modelling SDM-Site Forsmark: SKB R-08-105, Svensk Karnbranslehantering AB, Stockholm, 107 p.
35. Yu, S., Lee, J., Ha, K., Cho, B., and Kim, K.-J., 2021, Deep hydrochemical investigations using a borehole drilled in granite in Wonju, South Korea, J. Nucl. Fuel Cycle Waste Technol., 19(2), 247-260.
36. Yu, S., Kwon, J.S., Do, H.K., Chae, G.T., Park, J., Park, S., Choi, J., and Yun, S.T., 2023, Hydrochemical and isotopic comparison of crystalline bedrock aquifers in two geological disposal research sites in South Korea using samples collected during and after borehole drilling, Appl. Geochem., 149, 105560.
37. Xu, T., Spycher, N., Sonnenthal, E., Zhang, G., Zheng, L., and Pruess, K., 2012, TOUGHREACT Version 2.0: A simulator for subsurface reactive transport under non-isothermal multiphase flow conditions, Comput. Geosci., 37(6), 763-774.

This Article

2026; 31(2): 1-15

Published on Apr 30, 2026
10.7857/JSGE.2026.31.2.01
Received on Feb 15, 2026
Revised on Mar 1, 2026
Accepted on Mar 17, 2026

Services

Shared

Correspondence to

Ho-Rim Kim
¹Korea Institute of Geoscience and Mineral Resources, Daejeon 34132, Republic of Korea
E-mail: honeius@kigam.re.kr