The Gulf of Thailand has been a maj

The Gulf of Thailand has been a major marine resource for Thai people for a long time. However, recent industrialization and community development have exerted considerable stress on the marine environments and provoked habitat degradation. The following pollution problems in the Gulf have been prioritized and are discussed in details: (1) Untreated municipal and industrial waste water are considered to be the most serious problems of the country due to limited waste water treatment facilities in the area. (2) Eutrophication is an emerging problem in the gulf of Thailand. Fortunately, the major species of phytoplankton that have been reported as the cause of red tide phenomena were non-toxic species such as Noctiluca sp. and Trichodesmium sp. (3) Few problems have been documented from trace metals contamination in the Gulf of Thailand and public health threat from seafood contamination does not appear to be significant yet. (4) Petroleum hydrocarbon residue contamination is not a problem, although a few spills from small oil tankers have been recorded. A rapid decrease in mangrove forest, coral reefs, and fisheries resources due to mismanagement is also discussed.
The dependence of the energy sector on water resources is a two-way process. For instance, the energy production process often relies on the availability of water, and the production of clean water requires energy. This water–energy nexus is well appreciated by the experts of various disciplines (Hightower and Pierce, 2008). Furthermore, the use of water in fossil fuel based energy production as well as for domestic and industrial applications result in water pollution; the remediation of water pollution again requires energy in order to reuse or to discharge clean water back into natural water reserve (Grant, 2012). The story of the energy–pollution nexus is similar, but is much less discussed in an integrated manner (Kumar and Morawska, 2013). For example, the production of energy from the combustion of carbon-based or renewable fuels is bound to generate both climate (i.e., greenhouse gases, GHG, such as carbon dioxide, CO2; nitrogen oxide, N2O; methane, CH4) and health emissions (e.g., particulate matter, PM; sulphur dioxide, SO2; and nitrogen dioxide, NO2; carbon monoxide, CO). The effect of these emissions on climate change ( Vardoulakis and Heaviside, 2012), public health ( Rückerl et al., 2011 and Heal et al., 2012) and integrity of built infrastructure ( Kumar and Imam, 2013 and Tiwary and Kumar, 2014) have been well established. Since energy generates both air and water pollution during its production and consumption, we argue that it might be possible to investigate an integrated nexus that can help in understanding dynamic interrelations and quantitative indicators for water and the pollution (air and water) produced per unit of energy produced/consumed in urban environments (see Fig. 1). A framework for such a nexus would provide insight into the implications of the energy demand, economics and industrial growth, beyond the existing discrete indicators of sector specific energy demand and environmental impacts such as water–energy nexus ( Yang and Goordrich, 2014), energy–pollution nexus ( Kumar and Morawska, 2013) or food–water–energy nexus ( Rasul, 2014). We envision that the water–energy–pollution nexus can incorporate the key elements of urban environments in local or regional settings. Hence, the integrated nexus can be used to assess the true impact of energy production/consumption on the natural environment and quality of life in urban settlements. We believe that this could also open a way forward in achieving a holistic framework for global sustainability.