Regional and farm level droughts characteristics for southwestern Uganda during 1981–2017

Moses A. Ojara , Sylvia Namumbya , Bob Alex Ogwang , Paul T.S. Limbu
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Abstract

An increase in drought events associated with rising temperatures indicates that Uganda is facing a growing challenge from climate variability. Despite these challenges, there is a lack of comprehensive information on how climate variability affects soils, particularly drought characteristics. In an effort to address this limitation, this study utilised high-quality, in-situ climate data and soil Available Water Capacity (AWC) specific to south-western Uganda. The study employed the Palmer Drought Severity Index (PDSI) and the Standardised Precipitation-Evapotranspiration Index (SPEI) to assess drought occurrences over the period 1981–2017. Notably, the results from the 3-month SPEI indicated higher frequencies across all drought categories. Meanwhile, the 12-month SPEI exhibited more stabilised negative and positive truncations for drought and wet events, respectively. Analysing the temporal evolution of monthly PDSI values for five major soil mapping units revealed distinct patterns. Moderate droughts were observed over Lixic Ferralsols between 1981 and 1992 and between 1998 and 2008. Extreme drought events occurred during the first 5–7 months of 2017. Luvisols exhibited prolonged negative truncation levels, indicating a water deficit during several periods: 1982–1984, 1990–1994, 1998–2000, 2010, and 2012–2014. Histosols experienced drought conditions from 1982 to 1986, interspersed with wet events in 1988, 1997, 1999–2002, and 2005. The study emphasises the differential response of soil units to drought and wet conditions. As a result, the research recommends implementing water management practices such as irrigation, mulching, conservation tillage, zero tillage, and drainage for all soils to enhance resilience and sustainable agricultural practices in the region.

1981-2017 年期间乌干达西南部地区和农场一级的干旱特征
与气温上升相关的干旱事件的增加表明,乌干达正面临着气候多变性带来的日益严峻的挑战。尽管面临这些挑战,但有关气候多变性如何影响土壤,尤其是干旱特征的综合信息却十分匮乏。为了解决这一局限性,本研究利用了高质量的原地气候数据和乌干达西南部的土壤可用水量(AWC)。研究采用帕尔默干旱严重程度指数(PDSI)和标准化降水-蒸散指数(SPEI)来评估 1981-2017 年间的干旱发生情况。值得注意的是,3 个月 SPEI 的结果显示所有干旱类别的发生频率都较高。同时,12 个月 SPEI 对干旱和湿润事件分别表现出更稳定的负截断和正截断。对五个主要土壤制图单元的月 PDSI 值的时间演变进行分析,发现了不同的模式。1981 年至 1992 年以及 1998 年至 2008 年期间,Lixic 肥粒土出现了中度干旱。极端干旱事件发生在 2017 年的前 5-7 个月。Luvisols 表现出长期的负截断水平,表明在 1982-1984 年、1990-1994 年、1998-2000 年、2010 年和 2012-2014 年的几个时期出现了缺水。Histosols 在 1982 年至 1986 年期间经历了干旱,其间在 1988 年、1997 年、1999 年至 2002 年和 2005 年经历了潮湿。研究强调了土壤单位对干旱和潮湿条件的不同反应。因此,研究建议对所有土壤实施水管理措施,如灌溉、覆盖、保护性耕作、零耕作和排水,以增强该地区的恢复能力和可持续农业实践。
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来源期刊
Soil security
Soil security Soil Science
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