Arid ecosystem resilience to total petroleum hydrocarbons disturbance: A case‐study from the State of Kuwait associated with the Second Gulf War

The world's largest hydrocarbon disturbance occurred in the deserts and offshore waters of Kuwait during the Second Gulf War in 1990–1991. In this research, remote sensing (RS) and geographic information system (GIS) techniques were utilized to explore how native desert vegetation has recovered...

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Bibliographic Details
Published in:Land degradation & development 2020-01, Vol.31 (2), p.155-167
Main Authors: Abdullah, Meshal M., Assi, Amjad T., Abdullah, Mansour T., Feagin, Rusty A.
Format: Article
Language:English
Subjects:
Annual precipitation
arid ecosystems resiliency
Arid environments
Aridity
Change detection
Contamination
Deserts
Disturbance
Ecosystem resilience
Environmental changes
Environmental restoration
geographic information system (GIS)
Geographic information systems
Geomorphology
Gulf War
hydrocarbon disturbance
Hydrocarbons
Persian Gulf War
Petroleum
Petroleum hydrocarbons
Recovery
Remote sensing
Restoration
Revegetation
Sediment pollution
Soil contamination
Soils
Spatial analysis
Substrates
Vegetation
vegetation cover
Vegetation type
War
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Summary:The world's largest hydrocarbon disturbance occurred in the deserts and offshore waters of Kuwait during the Second Gulf War in 1990–1991. In this research, remote sensing (RS) and geographic information system (GIS) techniques were utilized to explore how native desert vegetation has recovered from hydrocarbon contamination after the Second Gulf War. By using RS techniques, change detection analysis was conducted to understand the changes about the coverage and extent of the total petroleum hydrocarbon (TPH) contamination and vegetation recovery. These changes were traced from 1991 until the hydrocarbon was no longer visible on the ground surface in 1998. GIS spatial analysis was conducted to determine the major ecosystem factors that influenced the vegetation recovery along with the removal of hydrocarbon disturbance. According to the results, autogenic recovery occurred at both sites within a few years and that desert native vegetation was found to have the ability to adapt and recover from hydrocarbon pollution. Native vegetation recovered across 31% of the TPH‐contaminated areas at Umm Gudair and 34% at Wadi Al Batin. The changes in TPH contamination were significantly correlated with the soil type, vegetation type, geological substrates, geomorphological features, and annual precipitation. The vegetation recovery of dominant desert communities in the study area was influenced by soil type, geomorphological feature, and TPH‐contaminated areas. Interestingly, the results showed that these desert communities can recover in areas contaminated by TPH at a higher rate than noncontaminated sites in the study area. Such a study can provide important inputs to the restoration and revegetation programs in arid landscapes.
ISSN:1085-3278
1099-145X
DOI:10.1002/ldr.3435