Soil water dynamics in the dominant lwo soil series (Arinic lixisol) were evaluated at the Federal University of Agriculture, Alabata, Abeokuta, Nigeria. Field capacity, infiltration and water retention characterist...Soil water dynamics in the dominant lwo soil series (Arinic lixisol) were evaluated at the Federal University of Agriculture, Alabata, Abeokuta, Nigeria. Field capacity, infiltration and water retention characteristics were evaluated in situ for a period of 161 d in the dry season for two root zone depths. Results show that the Iwo soil series has a field capacity ranging from 2.6%-5.5% at 0-45 cm and 45-90 cm root zone depths, respectively. The soil is quick draining with high infiltration rate and very poor water retention capacity confirming that the soil will require a short irrigation interval of about 2-3 d since available water for plant growth in predominantly sandy soils ranges between 2%-8%. Based on the foregoing, sprinkler irrigation is best suited for the lwo soil series, it should, however, be noted that the water application rate must be less than the infiltration rate of the soil in order to prevent surface ponding and runoff. A multivariate model relating soil moisture content with soil moisture tension and soil temperature calibrated within the study had very low model accuracy of 56% and 45% for the two root zone depths, respectively, implying the need for further studies.展开更多
Based on 10 years precipitation data from Tropical Rainfall Measurement Mission (TRMM) Multi-satellite Precipitation Analysis (TMPA) 3B42 and the best track data from China Meteorological Administration (CMA), t...Based on 10 years precipitation data from Tropical Rainfall Measurement Mission (TRMM) Multi-satellite Precipitation Analysis (TMPA) 3B42 and the best track data from China Meteorological Administration (CMA), the seasonal, monthly and annual contribution of tropical cyclone (TC) precipitation to the total rainfall are analyzed over the Western North Pacific (WNP) during 1998 to 2007 from May to December. The results show that: (1) TC seasonal rainfall contribution ranges from 4% in inland regions to above 40% in ocean-regions of 15°N-25°N. TCs at higher categories contribute much more to the total precipitation. (2) On monthly scale, TCs contribute 60% to the total rainfall regionally during whole TC season, which is the maximum contribution. The peak contribution of TC rainfall averaged in multi-months of the ten years occurs in August (28%) over the whole ocean impacted by TC and in December (23%) over the whole land impacted by TC, respectively. (3) On annual scale, the maximum contribution of TC precipitation to the total rainfall are in 2004 (-30%) over ocean and in 1998 (-20%) over land, respectively. (4) The contribution of TC precipitation to the total rainfall increases 6% (decreases 6%) in El Nino (La Nifia) years compared with neutral years.展开更多
文摘Soil water dynamics in the dominant lwo soil series (Arinic lixisol) were evaluated at the Federal University of Agriculture, Alabata, Abeokuta, Nigeria. Field capacity, infiltration and water retention characteristics were evaluated in situ for a period of 161 d in the dry season for two root zone depths. Results show that the Iwo soil series has a field capacity ranging from 2.6%-5.5% at 0-45 cm and 45-90 cm root zone depths, respectively. The soil is quick draining with high infiltration rate and very poor water retention capacity confirming that the soil will require a short irrigation interval of about 2-3 d since available water for plant growth in predominantly sandy soils ranges between 2%-8%. Based on the foregoing, sprinkler irrigation is best suited for the lwo soil series, it should, however, be noted that the water application rate must be less than the infiltration rate of the soil in order to prevent surface ponding and runoff. A multivariate model relating soil moisture content with soil moisture tension and soil temperature calibrated within the study had very low model accuracy of 56% and 45% for the two root zone depths, respectively, implying the need for further studies.
基金supported by the Special Funds for Public Welfare of China(Grant No.GYHY201306077)CAS Strategic Priority Research Program(Grant No.XDA05100303)+1 种基金the National Natural Science Foundation of China(Grant Nos.41230419,91337213)the Jiangsu Provincial 2011 Program(Collaborative Innovation Center of Climate Change)
文摘Based on 10 years precipitation data from Tropical Rainfall Measurement Mission (TRMM) Multi-satellite Precipitation Analysis (TMPA) 3B42 and the best track data from China Meteorological Administration (CMA), the seasonal, monthly and annual contribution of tropical cyclone (TC) precipitation to the total rainfall are analyzed over the Western North Pacific (WNP) during 1998 to 2007 from May to December. The results show that: (1) TC seasonal rainfall contribution ranges from 4% in inland regions to above 40% in ocean-regions of 15°N-25°N. TCs at higher categories contribute much more to the total precipitation. (2) On monthly scale, TCs contribute 60% to the total rainfall regionally during whole TC season, which is the maximum contribution. The peak contribution of TC rainfall averaged in multi-months of the ten years occurs in August (28%) over the whole ocean impacted by TC and in December (23%) over the whole land impacted by TC, respectively. (3) On annual scale, the maximum contribution of TC precipitation to the total rainfall are in 2004 (-30%) over ocean and in 1998 (-20%) over land, respectively. (4) The contribution of TC precipitation to the total rainfall increases 6% (decreases 6%) in El Nino (La Nifia) years compared with neutral years.
