Soil & Water Res., X:X | DOI: 10.17221/60/2026-SWR

Impact of urban soil surface treatments on soil water and thermal regimes in Haplic ChernozemOriginal Paper

Bunthorn Thet, Hana Raková, Miroslav Fér ORCID..., Aleš Klement ORCID..., Antonín Nikodem ORCID..., Abdul Majid ORCID..., Radka Kodešová ORCID...
1 Department of Soil Science and Soil Protection, Faculty of Agrobiology, Food and Natural Resources, Czech University of Life Sciences Prague, Prague, Czech Republic

Although it is known that land cover affects soil water and thermal regimes, the influence of different land covers on soil water content and temperature in urban areas is rarely explored. Five soil surface treatments were selected in this study: bare soil, concrete paving, bark mulch, mown grass, and unmown grass. Soil water contents and temperatures were measured at five depths (5, 10, 25, 50, and 80 cm) over one year. The highest water contents were recorded under mulching. Under grass, water contents were lower and showed greater oscillations due to precipitation and evapotranspiration, while under mown grass, values were higher than under unmown grass. Similarly, near-surface bare soil water contents also fluctuated. The water content under the concrete remained almost constant. While the soil under concrete paving, bare surfaces and even mown grass warmed up considerably during the day because of the absorption of solar radiation and cooled down at night due to the emission of stored heat, the soil under bark mulch and unmown grass cover showed smaller temperature fluctuations, mainly due to the low thermal conductivity of the surface layer and surface shading. The effects revealed throughout the entire soil profiles decreased with depth.

Keywords: bare soil; bark chips; concrete paving; grass; soil temperature; soil water content

Received: May 13, 2026; Accepted: May 28, 2026; Prepublished online: June 8, 2026 

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References

  1. Al-Shammary A.A.G., Al-Shihmani L.S.S., Fernández-Gálvez J., Caballero-Calvo A. (2024): Optimizing sustainable agriculture: A comprehensive review of agronomic practices and their impacts on soil attributes. Journal of Environmental Management, 364: 121487. Go to original source... Go to PubMed...
  2. Asaeda T., Ca V.T. (2000): Characteristics of permeable pavement during hot summer weather and impact on the thermal environment. Building and Environment, 35: 363-375. Go to original source...
  3. Byrne L.B., Bruns M.A., Kim K.C. (2008): Ecosystem properties of urban land covers at the aboveground-belowground interface. Ecosystems, 11: 1065-1077. Go to original source...
  4. Fér M., Nikodem A., Trejbalová S., Klement A., Pavlů L., Kodešová R. (2022): How various mulch materials can affect the soil hydro-physical properties. Journal of Hydrology and Hydromechanics, 70: 269-275. Go to original source...
  5. Fini A., Frangi P., Mori J., Donzelli D., Ferrini F. (2017): Nature based solutions to mitigate soil sealing in urban areas: Results from a 4-year study comparing permeable, porous, and impermeable pavements. Environmental Research, 156: 443-454. Go to original source... Go to PubMed...
  6. Goettl B., Da Ros Carvalho H., Heitman J., DeSutter T. (2025): The impact of residue and cover crop management on soil water and temperature regimes in a loam soil in North Dakota. Agrosystems, Geosciences & Environment, 8: e70223. Go to original source...
  7. Hernández J.R., Navarro-Pedreno J., Gómez Lucas I. (2016): Evaluation of plant waste used as mulch on soil moisture retention. Spanish Journal of Soil Science, 6: 133-144. Go to original source...
  8. IUSS (2014): World Reference Base for Soil Resources 2014. World Soil Resources Reports No. 106. Rome, FAO.
  9. Kader M.A., Senge M., Mojid M.A., Ito K. (2017a): Recent advances in mulching materials and methods for modifying soil environment. Soil and Tillage Research, 168: 155-166. Go to original source...
  10. Kader M.A., Senge M., Mojid M.A., Nakamura K. (2017b): Mulching type-induced soil moisture and temperature regimes and water use efficiency of soybean under rain-fed condition in central Japan. International Soil and Water Conservation Research, 5: 302-308. Go to original source...
  11. Kodešová R., Kodeš V., Mráz A. (2011): Comparison of two sensors ECH2O EC-5 and SM200 for measuring soil water content. Soil and Water Research, 6: 102-110. Go to original source...
  12. Kodešová R., Vlasáková M., Fér M., Teplá D., Jakšík O., Neuberger P., Adamovský R. (2013): Thermal properties of representative soil of the Czech Republic. Soil and Water Research, 8: 141-150. Go to original source...
  13. Kodešová R., Fér M., Klement A., Nikodem A., Teplá D., Neuberger P., Bureš P. (2014): Impact of various surface covers on water and thermal regime of Technosol. Journal of Hydrology, 519: 2272-2288. Go to original source...
  14. Maggard A.O., Will R.E., Hennessey T.C., McKinley C.R., Cole J.C. (2012): Tree-based mulches influence soil properties and plant growth. HortTechnology, 22: 353-361. Go to original source...
  15. Morgenroth J., Buchan G.D. (2009): Soil moisture and aeration beneath pervious and impervious pavements. Arboriculture & Urban Forestry, 35: 135-141. Go to original source...
  16. Ni J., Cheng Y., Wang Q., Ng C.W.W., Garg A. (2019): Effects of vegetation on soil temperature and water content: Field monitoring and numerical modelling. Journal of Hydrology, 571: 494-502. Go to original source...
  17. Niu C.Y., Musa A., Liu Y. (2015): Analysis of soil moisture condition under different land uses in the arid region of Horqin sandy land, northern China. Solid Earth, 6: 1157-1167. Go to original source...
  18. Özkan U., Gökbulak F. (2017): Effect of vegetation change from forest to herbaceous vegetation cover on soil moisture and temperature regimes and soil water chemistry. Catena, 149: 158-166. Go to original source...
  19. Pavlů L., Kodešová R., Fér M., Nikodem A., Němec F., Prokeš R. (2021): The impact of various mulch types on soil properties controlling water regime of the Haplic Fluvisol. Soil and Tillage Research, 205: 104748. Go to original source...
  20. Rafi Z.N., Kazemi F. (2021): Effects of planting combinations and mulch types on soil moisture and temperature of xeric landscapes. Urban Forestry & Urban Greening, 58: 126966. Go to original source...
  21. Schaffitel A., Schuetz T., Weiler M. (2020): A distributed soil moisture, temperature and infiltrometer dataset for permeable pavements and green spaces. Earth System Science Data, 12: 501-517. Go to original source...
  22. Thet B., Kodešová R., Fér M., Klement A., Nikodem A. (2024): How different soil surface treatments in urban areas affect soil pore structure and associated soil properties and processes. Journal of Hydrology, 645: 132233. Go to original source...
  23. Yang X.M., Reynolds W.D., Drury C.F., Reeb, M.D. (2021): Cover crop effects on soil temperature in a clay loam soil in southwestern Ontario. Canadian Journal of Soil Science, 101: 761-770. Go to original source...
  24. Zhang L., Wang Z., He Z., Ma X., Ma B., Tian J., He J. (2024): Effects of gravel-sand and plastic film mulching on soil water and temperature retention in cold and arid regions without irrigation. Science of the Total Environment, 934: 173350. Go to original source... Go to PubMed...
  25. Zhang P., Zhang Z., Xiao M., Chao J., Dai Y., Liu G., Senge M. (2023): Effects of organic mulching on moisture and temperature of soil in greenhouse production of tomato under unheated greenhouse cultivation in the cold zone of China. Food Science & Nutrition, 11: 4829-4842. Go to original source... Go to PubMed...

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