Abstract
The transport mechanisms of water, heat, and salt in unsaturated frozen soil, as well as its response to future climate change are in urgent need of study. In this study, western Jilin Province in north-eastern China was studied to produce a model of coupled water-heat-salt in unsaturated frozen soil using CoupModel. The water, heat, and salt dynamics of unsaturated frozen soil under three representative concentration pathway (RCP) scenarios were simulated to analyze the effects of future climate change on unsaturated frozen soil. The results show that water, heat, and salt migration are tightly coupled, and the soil salt concentration in the surface layer (10 cm) exhibits explosive growth after freezing and thawing. The future (2020–2099) meteorological factors in the study area were predicted using the Statistical Downscaling Model (SDSM). For RCP2.6, RCP4.5, and RCP8.5 scenarios, future temperatures during the freeze-thaw period increased by 2.68°C, 3.18°C, and 4.28°C, respectively; precipitation increased by 30.28 mm, 28.41 mm, and 32.17 mm, respectively; and evaporation increased by 93.57 mm, 106.95 mm, and 130.57 mm, respectively. Climate change will shorten the freeze-thaw period, advance the soil melting time from April to March, and enhance water and salt transport. Compared to the baseline period (1961–2005), future soil salt concentrations at 10 cm increased by 1547.54 mg/L, 1762.86 mg/L, and 1713.66 mg/L under RCP2.6, RCP4.5, and RCP8.5, respectively. The explosive salt accumulation is more obvious. Effective measures should be taken to prevent the salinization of unsaturated frozen soils and address climate change.
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References
Adane Z, Zlotnik V A, Rossman N R, Wang T, Nasta P (2019). Sensitivity of potential groundwater recharge to projected climate change scenarios: A site-specific study in the nebraska sand hills, USA. Water (Basel), 11(5): 950–968
Bao S D (2008). Soil Agro-Chemistrical Analysis. Beijing: China Agriculture Press
Bosson E, Selroos J O, Stigsson M, Gustafsson L G, Destouni G (2013). Exchange and pathways of deep and shallow groundwater in different climate and permafrost conditions using the Forsmark site, Sweden, as an example catchment. Hydrogeology Journal, 21(1): 225–237
Brooks R H, Corey A T (1964). Hydraulic properties of porous media and their relation to drainage design. Transactions of the ASAE, 7(1): 26–28
CanESM2 output data (2019). CanESM2 predictors: CMIP5 experiments. 2019. Available online at the website of climate-scenarios. canada.ca (accessed May 20, 2020)
Cary J W, Mayland H F (1972). Salt and water movement in unsaturated frozen soil. Soil Science Society of America Journal, 36(4): 549–555
Cary J W, Papendick R I, Campbell G S (1979). Water and salt movement in unsaturated frozen soil: principles and field observations1. Soil Science Society of America Journal, 43(1): 3–8
China Hourly Meteorological Database (2019). National Meteorological Information Center. National Meteorological Science Data Center. 2019. Available online at the website of data.cma.cn/data/detail/dataCode/A.0012.0001.html (accessed May 20, 2020)
CoupModel (2019). Basic description of platform-CoupModel. COUP manual. 2019. Available online at the website of www.coupmodel.com/basic-description-of-platform (accessed April 15, 2020)
Deb S K, Shukla M K, Shrama P (2010). Numerical analysis of coupled liquid water, water vapor, and heat transport in a sandy loam soil. In: 19th World Congress of Soil Science, Soil Solutions for a Changing World 2010, Brisbane, Australia. Symposium 2.1.1 Optimizing Water Use With Soil Physics, 121–124
Ding D, Xing J, Wang S X, Chang X, Hao J M (2019). Impacts of emissions and meteorological changes on China’s ozone pollution in the warm seasons of 2013 and 2017. Frontiers of Environmental Science & Engineering, 13(5): 76
Dong L J, Dong X H, Zeng Q, Wei C, Yu D, Bo H J, Guo J (2019). Long-term runoff change trend of Yalong River basin under future climate change scenarios. Climate Change Research: 1–15
Flerchinger G N, Saxton K E (1989a). Simultaneous heat and water model of a freezing snow-residue-soil system I. theory and development. Transactions of the ASAE. American Society of Agricultural Engineers, 32(2): 0565–571
Flerchinger G N, Saxton (1989b). Simultaneous heat and water model of a freezing snow-residue-soil system II. field verification. Transactions of the ASAE. American Society of Agricultural Engineers, 32(2): 0573–578
Frampton A, Destouni G (2015). Impact of degrading permafrost on subsurface solute transport pathways and travel times. Water Resources Research, 51(9): 7680–7701
Gustafsson D, Lewan E, Jansson P E (2004). Modeling water and heat balance of the boreal landscape—comparison of forest and arable land in Scandinavia. Journal of Applied Meteorology, 43(11): 1750–1767
Hansson K, Šimůnek J, Mizoguchi M, Lundin L C, van Genuchten M T (2004). Water flow and heat transport in frozen soil: numerical solution and freeze-thaw applications. Vadose Zone Journal, 3(2): 693–704
Harlan R L (1973). Analysis of coupled heat-fluid transport in partially frozen soil. Water Resources Research, 9(5): 1314–1323
Hu H P, Yang S X, Lei Z D (1992). A numercial simulation for heat and moisture transfer during soil freezing. Journal of Hydraulic Engineering, (07): 1–8
Huang X F, Zeng D C (1993). A numercial simulation for water-salt-heat movement during soil freezing and thawing. Journal of Beijing Agricultural Engineering University, 13(03): 43–50
Jansson P E, Karlberg L (2004a). COUP manual- coupled heat and mass transfer model for soil-plantatmosphere systems. Technical Manual for the CoupModel: 1–453
Jansson P E, Karlberg L (2004b). Coupled heat and mass transfer model for soil-plant-atmosphere systems. Royal Institute of Technology, Department of Civil and Environmental Engineering, Stockholm
Jansson P E, Karlberg L (2011). Coupled heat and mass transfer model for soil-plant-atmosphere systems. Royal Institute of Technology, Department of Civil and Environmental Engineering, Stockholm
Khoshkhoo Y, Jansson P E, Irannejad P, Khalili A, Rahimi H (2015). Calibration of an energy balance model to simulate wintertime soil temperature, soil frost depth, and snow depth for a 14 year period in a highland area of Iran. Cold Regions Science and Technology, 119: 47–60
Klemedtsson L, Jansson P E, Gustafsson D, Karlberg L, Weslien P, Von Arnold K, Ernfors M, Langvall O, Lindroth A (2008). Bayesian calibration method used to elucidate carbon turnover in forest on drained organic soil. Biogeochemistry, 89(1): 61–79
Kurylyk B L, Watanabe K (2013). The mathematical representation of freezing and thawing processes in variably-saturated, non-deformable soils. Advances in Water Resources, 60: 160–177
Lai Y M, Pei W S, Zhang M Y, Zhou J Z (2014). Study on theory model of hydro-thermal-mechanical interaction process in saturated freezing silty soil. International Journal of Heat and Mass Transfer, 78: 805–819
Liu C H (2016). Soil water and nitrogen spatial distribution characteristics and behavior simulation in soda saline-alkali soil area in western of Jilin Province. Dissertation for Doctoral Degree. Changchun: Jilin University
Nassar I N, Horton R (1989). Water transport in unsaturated nonisothermal salty soil: I. Experimental results. Soil Science Society of America Journal, 53(5): 1323–1329
Ren J Q, Liu Y X, Wang D N, Mu J, Li X Y, Cui J L, Guo C M (2019). The change of frost depth of seasonally frozen soil and its response to climate in Jilin Province. Journal of Glaciology and Geocryology, 41(05): 1–10
Richards L A (1931). Capillary conduction of liquids through porous mediums. Physics, 1(5): 318–333
Rouabhi A, Jahangir E, Tounsi H (2018). Modeling heat and mass transfer during ground freezing taking into account the salinity of the saturating fluid. International Journal of Heat and Mass Transfer, 120: 523–533
Scherler M, Hauck C, Hoelzle M, Salzmann N (2013). Modeled sensitivity of two alpine permafrost sites to RCM-based climate scenarios. Journal of Geophysical Research. Earth Surface, 118(2): 780–794
Šimůnek J, van Genuchten M T, Šejna M (2008). Modeling subsurface water flow and solute transport with HYDRUS and related numerical software packages. In: Proceedings of the International Workshop on Numerical Modelling of Hydrodynamics for Water Resources-Numerical Modelling of Hydrodynamics for Water Resources, 95–114
Sinha E, Michalak A M, Calvin K V, Lawrence P J (2019). Societal decisions about climate mitigation will have dramatic impacts on eutrophication in the 21st century. Nature Communications, 10(1): 939–949
Tang J, Liang S, Zhang H, Wu J X, Lou Y (2014). Study on the characteristics of water-salt transfer and enzyme activity variations during freeze-thaw period of the saline alkaline paddy soil in western Jilin Province. Journal of Jilin University (Earth Science Edition), 44(2): 636–644
Taylor G S, Luthin J N (1978). A model for coupled heat and moisture transfer during soil freezing. Canadian Geotechnical Journal, 15(4): 548–555
Tounsi H, Rouabhi A, Jahangir E (2020). Thermo-hydro-mechanical modeling of artificial ground freezing taking into account the salinity of the saturating fluid. Computers and Geotechnics, 119: 103382–103395
Wan H L, Bian J M, Wu J J, Sun X Q, Wang Y, Jia Z (2019). Prediction of seasonal frost heave behavior in unsaturated soil in Northeastern China using interactive factor analysis with split-plot experiments and GRNN. Water (Basel), 11(8): 1587–1617
Wang M (2016). Study on characteristics and prevention measures of subgrade frost heave of carbonate-saline soil. Thesis for Master Degree. Changchun: Changchun Institute of Technology
Wang Y, Bian J M, Zhao Y S, Tang J, Jia Z (2018). Assessment of future climate change impacts on nonpoint source pollution in snowmelt period for a cold area using SWAT. Scientific Reports, 8(1): 2402–13
Watanabe K, Toride N, Sakai M, Simunek J (2007). Numerical modeling of water, heat, and solute transport during soil freezing. Journal of the Japanese Society of Soil Physics, 106: 21–32
Wu D Y, Lai Y M, Zhang M Y (2017). Thermo-hydro-salt-mechanical coupled model for saturated porous media based on crystallization kinetics. Cold Regions Science and Technology, 133: 94–107
Wu M S, Wu J W, Tan X, Huang J S, Jansson P E, Zhang W X (2019). Simulation of dynamical interactions between soil freezing/thawing and salinization for improving water management in cold/arid agricultural region. Geoderma, 338: 325–342
Wu S H, Jansson P E (2013). Modelling soil temperature and moisture and corresponding seasonality of photosynthesis and transpiration in a boreal spruce ecosystem. Hydrology and Earth System Sciences (HESS) & Discussions (HESSD), 17: 705–720
Wu S H, Jansson P E, Zhang X Y (2011). Modelling temperature, moisture and surface heat balance in bare soil under seasonal frost conditions in China. European Journal of Soil Science, 62(6): 780–796
Yue H S (1994). Primary study on model for coupled heat-moisture-salt transfer in soil during freezing-thawing preocesses. Journal of Glaciolgy and Geocryology, 16(4): 308–313
Zeng G J, Zhang M Y, Li Z P, Pei W S (2015). Study of moisture migration and frost heave model of freezing saturated soil. Yantu Lixue, 36(04): 1085–1092
Zhang J, Lai Y M, Li J F, Zhao Y H (2020). Study on the influence of hydro-thermal-salt-mechanical interaction in saturated frozen sulfate saline soil based on crystallization kinetics. International Journal of Heat and Mass Transfer, 146: 118868–118881
Zhang N X (2008). A study on properties of saline-alkali soil in northeast Songnen plain. Thesis for Master Degree. Xi’an: Chang’an University
Zhao D D (2019). The change of wetland distribution and the simulated response to climatic change in the Great Xing’an Mountains. Dissertation for Doctoral Degree. Lanzhou: Northeast Normal University
Zhao Y, Si B C, He H L, Xu J, Peth S, Horn R (2016). Modeling of coupled water and heat transfer in freezing and thawing soils, Inner Mongolia. Water (Basel), 8(10): 424–441
Zhao Y S, Lin L, Hong M (2019). Nitrobenzene contamination of groundwater in a petrochemical industry site. Frontiers of Environmental Science & Engineering, 13(2): 29
Acknowledgements
This research was funded by the National Key R&D Program of China (Grant No. 2018YFC1800400). We would like to thank all of the members of the Key Laboratory of Groundwater Resources and Environment, Ministry of Education, Jilin University for their critical technical assistance. There are no conflicts of interest to declare.
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Highlights
• A model coupling water-heat-salt of unsaturated frozen soil was established.
• Future temperature, precipitation, and evaporation increase in freeze-thaw period.
• Soil water, heat, and salt transport are closely coupled during freeze-thaw period.
• Freeze-thaw cycles and future climate change can exacerbate salinization.
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Wan, H., Bian, J., Zhang, H. et al. Assessment of future climate change impacts on water-heat-salt migration in unsaturated frozen soil using CoupModel. Front. Environ. Sci. Eng. 15, 10 (2021). https://doi.org/10.1007/s11783-020-1302-5
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DOI: https://doi.org/10.1007/s11783-020-1302-5