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W3043765849 endingPage "114571" @default.
W3043765849 startingPage "114571" @default.
W3043765849 abstract "Abstract Freeze-thaw cycles (FTCs) change soil physiochemical properties and biogeochemical processes and inevitably influence the spatial distribution of soil phosphorus (P). In this study, a field investigation was conducted on the Mollisol soil of the Guangrong watershed from 2016 to 2018 to clarify the effect of FTCs on the spatial distribution of total phosphorus (TP) at soil depths of 0–5, 5–10 and 10–20 cm. A laboratory incubation experiment was conducted to reveal the effect of FTCs on TP in soil profiles (0–30 cm) in Mollisols. The results showed that (1) the spatial autocorrelation (nugget to sill ratio) of TP decreased by 5.92% after the FTCs while the spatial variance (coefficient of variation) increased by 17.19%. The TP in 85% of the watershed area decreased after the FTCs, and the mean content of TP decreased by 9.53%. These changes were mainly influenced by land use types, topographical factors, soil properties and human activities. (2) TP increased in the intersection between farmland and forestland (0.01 g kg−1) after the FTCs, while TP decreased both in the areas near the hydrological channel (0.06 g kg−1) and at the outlet of the watershed (0.13 g kg−1). Compared with down-slope tillage, maize planting, south-facing slopes and low vegetation coverage areas, the cross-slope tillage, soybean planting, north-facing slopes and high vegetation coverage areas reduced TP losses by 56.1%, 19.5%, 115.8% and 141.9%, respectively, in the 0–20 cm soil layer. (3) The effects of FTCs on TP in soil profile were mainly influenced by the soil moisture content, FTC frequency and soil bulk density in the laboratory incubation experiment. TP variability showed a V-shaped trend as the number of FTCs increased, and decreased as the initial moisture content increased at 1.1 g cm−3 of soil bulk density. (4) An equation based on the TP and mean value of normalized difference snow index, normalized difference vegetation index, ferrous minerals index and normalized difference soil moisture index from the freezing period to the thawing period was built to roughly predict the TP after FTCs (R2 = 0.72). Generally, the TP tended to decrease during both the freezing stage and the thawing stage in the field. Areas with down-slope tillage, existing maize fields, south-facing positions, low vegetation coverage and high snow coverage should be focused on to reduce P losses during FTCs." @default.
W3043765849 created "2020-07-23" @default.
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W3043765849 date "2020-10-01" @default.
W3043765849 modified "2023-10-16" @default.
W3043765849 title "Responses of soil total phosphorus to freeze and thaw cycles in a Mollisol watershed" @default.
W3043765849 cites W1532622348 @default.
W3043765849 cites W1966056444 @default.
W3043765849 cites W1966882003 @default.
W3043765849 cites W1968287206 @default.
W3043765849 cites W1986494994 @default.
W3043765849 cites W1991060563 @default.
W3043765849 cites W1993648983 @default.
W3043765849 cites W1994221921 @default.
W3043765849 cites W1999454889 @default.
W3043765849 cites W2000148941 @default.
W3043765849 cites W2003285183 @default.
W3043765849 cites W2020394049 @default.
W3043765849 cites W2024807951 @default.
W3043765849 cites W2026702986 @default.
W3043765849 cites W2039480376 @default.
W3043765849 cites W2047120335 @default.
W3043765849 cites W2063246330 @default.
W3043765849 cites W2063669074 @default.
W3043765849 cites W2065219204 @default.
W3043765849 cites W2068642066 @default.
W3043765849 cites W2078287731 @default.
W3043765849 cites W2088626654 @default.
W3043765849 cites W2092013163 @default.
W3043765849 cites W2110329447 @default.
W3043765849 cites W2111811970 @default.
W3043765849 cites W2128078219 @default.
W3043765849 cites W2131339285 @default.
W3043765849 cites W2145247671 @default.
W3043765849 cites W2154285123 @default.
W3043765849 cites W2157067801 @default.
W3043765849 cites W2174315796 @default.
W3043765849 cites W223120834 @default.
W3043765849 cites W2256438636 @default.
W3043765849 cites W2306253115 @default.
W3043765849 cites W2337336210 @default.
W3043765849 cites W2342572455 @default.
W3043765849 cites W2346327840 @default.
W3043765849 cites W2472373273 @default.
W3043765849 cites W2509544597 @default.
W3043765849 cites W2567973877 @default.
W3043765849 cites W2578044682 @default.
W3043765849 cites W2587837857 @default.
W3043765849 cites W2727774496 @default.
W3043765849 cites W2741355802 @default.
W3043765849 cites W2763243879 @default.
W3043765849 cites W2772453165 @default.
W3043765849 cites W2777216768 @default.
W3043765849 cites W2790833170 @default.
W3043765849 cites W2791970982 @default.
W3043765849 cites W2794759897 @default.
W3043765849 cites W2801778677 @default.
W3043765849 cites W2803323174 @default.
W3043765849 cites W2810275074 @default.
W3043765849 cites W2888921070 @default.
W3043765849 cites W2899637392 @default.
W3043765849 cites W2903410069 @default.
W3043765849 cites W2909354181 @default.
W3043765849 cites W2913821876 @default.
W3043765849 cites W2915704896 @default.
W3043765849 cites W2924030619 @default.
W3043765849 cites W2925330246 @default.
W3043765849 cites W3001184068 @default.
W3043765849 cites W4238042869 @default.
W3043765849 cites W4247650231 @default.
W3043765849 cites W890974504 @default.
W3043765849 doi "https://doi.org/10.1016/j.geoderma.2020.114571" @default.
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