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Devastating Consequences: How a Single Oil Spill Can Disrupt the Global Energy Supply

Close-up of the desalination and liquid natural gas export infrastructures in Qatar. Credit: Thomas Anselain, Essam Heggy, Thomas Dobbelaere & Emmanuel Hanert

A maritime area three times the size of the city of London holds the highest risk for oil spills in the Gulf which can have devastating consequences locally and globally.

Over the last year, the world’s energy market has been highly volatile. The warmer-than-average winter in Europe helped avoid a gas crisis this year, but the forecast for the next winter is unclear as instabilities persist. More than 20% of global liquefied natural gas exports originate from a single port in Qatar.

A new research paper pinpoints the location of what the authors call a “high vulnerability zone,” where an oil spill could cause liquified natural gas export facilities and desalination plants on the coast to be completely shut down for several days.  (In the presence of an oil spill, tankers cannot navigate through thick oil slicks. Further, desalination plants, which rely on the intake of seawater, cannot perform normal operations with a heavily polluted water source.) The paper was published on January 12 in the journal Nature SustainabilityNature Sustainability is a scientific journal that focuses on research related to sustainable development, which aims to meet the needs of the present without compromising the ability of future generations to meet their own needs. The journal publishes original research articles, reviews, and perspectives across a wide range of topics, including sustainable use of natural resources, reducing environmental impacts, and addressing global challenges such as climate change, biodiversity loss, and pollution.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>Nature Sustainability by a team of researchers at the University of Louvain, the University of Southern California (USC) Viterbi School of Engineering, and the Qatar Environment and Energy Research Institute.

This shutdown, the researchers explain, could cause significant disruption in the global gas supply and cause an unprecedented water shortage for inhabitants of the Qatari Peninsula, while simultaneously compromising containment efforts.

Awareness of such a vulnerability is imperative, say the researchers. Qatar’s export capacity is expected to increase by approximately 64% in the next five years. Thus, this key port will continue to be a crucial hotspot for the global energy supply chain. The researchers also note that the increasing number of tanker accidents in the Gulf adds a level of concern, particularly related to how such accidents could impact critical coastal infrastructures that export a vital source of energy for the planet and ensure the safety of desalinated water for one of the world’s most arid climates.

The paper uses advanced numerical modeling to corollate maritime data transports, atmospheric circulation, ocean currents, waves, and seafloor topographic map data acquired over a period of five years to locate specific, offshore areas of the Qatar Peninsula that are vulnerable to oil spills and assess potential disruptions to the global supply of liquid natural gas.

The study suggests that tankers crossing this area are the principal risks for oil spills and, not the numerous oil rigs in the northern part of the Peninsula. Should there be a spill in this area, the researchers contend, Qatar would have only a few days to contain the oil spills before such spills would reach the country’s main liquified gas export facility and main desalination plant. The authors indicate that these events could potentially cause disruptions or even a total shutdown for day for the desalination plants, pushing the nation to rely on its small freshwater reserve and sending liquified natural gas prices to higher values.  

To put the size of the issue in context, experts believe that the largest liquid natural gas tankers from Qatar provide enough energy to heat the entire city of London for one week.

The study advocates for increased remote sensing using satellite and airborne images in the Gulf’s most vulnerable areas to provide early warning for spills and better model their evolution. The above actions are crucial, say the researchers, to guide mitigation efforts to avoid negative consequences both locally and globally.

Co-author Essam Heggy of the USC<span class="st">Founded in 1880, the <em>University of Southern California</em> is one of the world's leading private research universities. It is located in the heart of Los Angeles.</span>” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>USC Arid Climate and Water Research Center argues that the Middle East’s vulnerability to environmental and climatic hazards is largely underestimated. “Global containment of major oil spills has always been challenging, but it is even harder in the shallow water of the Gulf where any intervention has to account for the complex circulation currents, a harsh operational environment, and the presence of highly-sensitive ecosystems on which three million humans rely for drinking water.”  He added, “I hope serious resources are put into resolving this vulnerability.”

Co-author Emmanuel Hanert of the University of Louvain stated, “Oil spill vulnerability in the Gulf could exacerbate both the global energy crisis and the local water crisis in Gulf countries.”  He added, “Energy and water security are deeply intertwined, and both are at risk of being disrupted by a major oil spill. We identified sea areas in the Gulf where an oil spill would be the most dangerous to desalination and liquified natural gas export facilities. Satellite surveillance should focus on detecting oil spills as early as possible and hence limit their impact.”

Reference: “Qatar Peninsula’s vulnerability to oil spills and its implications for the global gas supply” by Thomas Anselain, Essam Heggy, Thomas Dobbelaere and Emmanuel Hanert, 12 January 2023, Nature Sustainability.
DOI: 10.1038/s41893-022-01037-w

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Source: SciTechDaily