Fundamental Earth System Processes

The earth system processes of the humid tropics are somewhat less understood than other biomes around the globe. The hydrologic processes of the humid tropics are characterized by greater magnitude, interannual variability, and spatial gradients than are generally found elsewhere, each of which can be obstacles to prediction (Bonell & Bruijnzeel, 2005; Wohl et al., 2012). As temperatures and atmospheric water carrying capacity in the tropics increase due to climate change, some hydrological processes are expected to quicken and potentially exacerbate the aforementioned characteristics (Wohl et al., 2012). At a global scale, precipitation and evapotranspiration are expected to increase with increasing air temperatures; however, it is unclear what trends will emerge from complex atmosphere–land surface interactions at continental and regional scales (Wang & Dickinson, 2012). The distinct hydrologic character of the tropics and unknown features of future climate present difficultly for modeling and prediction, which is compounded by the relative lack of research investigation within the humid tropics in comparison with systems of temperate regions (Wohl et al., 2012). For instance, little is definitively known regarding the functioning and hydrologic contributions of tropical montane cloud forests (Bruijnzeel and Proctor, 1995) or the sensitivity of tropical forests to drought (Samanta et al., 2010). Understanding earth system processes in the tropics is particularly critical given the important role the tropics play in the global earth system. Modeling exercises have shown profound teleconnections between tropical forests and distant geographic regions; for instance, land clearing in the Amazon basin was shown to result in significant temperature increases in Western Europe and Central Asia (Rockström et al., 2009). Responsible FEW system management hinges on understanding these fundamental earth system processes, particularly as vital ecosystems in the humid tropics are subjected to climatic and anthropogenic changes.

Agricultural Expansion and Deforestation

Much of the global need for increased food production is being met via agricultural intensification and expansion in the humid tropics, often at the expense of tropical forest (Foley et al., 2011). In addition, agricultural land is expanding to meet the demand for biofuels in countries such as Brazil, Indonesia, and Malaysia (Gibbs et al., 2010). Food, energy, and the natural environment are intertwined via competition for land and water. Single-sector analysis may lead to ignorance of the impacts of one sector on others (for instance, biofuel development with an energy-only perspective may have undesirable impacts on food prices or forest cover), and a full FEW system analysis must be undertaken. The stakes for the humid tropics are high, as deforestation cannot be easily or quickly reversed should surprises arise.

However, agricultural expansion operates in a highly complex FEW system, hindering thorough understanding and management. While biofuels theoretically offer a route to simultaneously increase energy supply and curb climate change, it can take several decades for carbon savings to be realized in locations where biofuel crops replace carbon-storing forests (Gibbs et al., 2008). In addition, the ecological community is still only beginning to understand the ability of tropical forests to recover from disturbance. How quickly forests recover from land clearing and how biodiversity losses affect forests’ ability to withstand future disturbances are ongoing fields of inquiry (Cole, Bhagwat, & Willis, 2014; Sakschewski et al., 2016). Further insight is vital to ensure that large swaths of tropical forest, and all their accompanying services, do not catastrophically switch to a state of savanna—a FEW system tragedy comparable with the shrinking of the Aral Sea due to unsustainable irrigation practices and hydropower development in Central Asia (Cai, McKinney, & Rosegrant, 2003; Hirota, Holmgren, Van Nes, & Scheffer, 2011). Answers to what degree agricultural expansion is sustainable, or even advantageous for the present, require that carbon-payback time and forest resilience concepts, among others, be applied to evaluate tropical FEW systems.

Hydropower Versus Fish and GHG Emissions

Due to typically high runoff within humid regions, there is great potential for hydropower in much of the humid tropics. In fact, Brazil, one of the more developed tropical countries, trails only the United States and China in developed hydropower capacity, and hydropower provides nearly 80% of the nation’s electricity (Soito & Freitas, 2011). However, building dams for hydropower is a complicated FEW nexus issue. In addition to energy provision, positive benefits of dams include water storage for irrigation (a critical element of food provision infrastructure) and periods of drought, flood regulation, and recreation. Conversely, dam construction often inhibits fish migration (also critical to food provision, via fisheries), disrupts sediment transport, and eliminates other ecosystem services (Gunkel, 2009). Tropical cold-water fish are an important source of nutrition and food security in many regions. According to Winemiller et al. (2016), as many as 450 new hydroelectric dams are planned or in construction on the Amazon, Congo, and Mekong rivers, and species extinction and basin-wide declines in fisheries may accompany these new hydropower projects. Moreover, 54% of global installed hydropower capacity—an amount totaling 507 Gigawatts—directly competes with irrigation, meaning that increased hydroelectricity production might reduce food security in many regions, although hydropower development can also support irrigation through timely availability of irrigation supplies (Zeng, Cai, Ringler, & Zhu, 2017). Thus, research and practice should encompass the full scope of FEW system impacts of dam construction and operation.

Furthermore, the validity of hydropower as a form of “green” energy has come into question in recent years. Carbon dioxide and methane emissions are both natural products of decomposition within a lake, and recent findings suggest that emissions from reservoirs are substantially higher than previously believed (Fearnside & Pueyo, 2012; Winemiller et al., 2016). GHG emissions are particularly high for shallow, tropical reservoirs, where decomposition occurs more rapidly (Gunkel, 2009). In fact, for some tropical reservoirs, the initial surge in GHG emissions due to decomposition of the inundated upstream vegetation may outweigh the GHG savings of fossil fuel reduction for several decades (Gunkel, 2009). At this stage, a great deal more data is needed to confidently quantify GHG emissions of tropical reservoirs (Rosa, dos Santos, Matvienko, dos Santos, & Sikar, 2004), and to do so in comparison with their natural state alternatives. Emerging insights must be continuously tested and incorporated into FEW system analysis to ensure that tropical dam construction, an enormous investment, is not misguided regarding its potential benefits.

Cross-Sectoral Technological and Policy Innovations

Improvements in technology and system design are building blocks for synergistic solutions to FEW demands. In much of the humid tropics, fruits and other food require a great deal of energy to be stored and transported at their necessary temperature and humidity (Wardlaw, 1939). Harnessing renewable energy sources such as solar powered refrigeration may allow tropical food economies to flourish without placing such a burden on the energy market (Sarbu & Sebarchievici, 2013). Meanwhile, in water scarce tropical regions such as islands and deserts, wind or solar powered desalination and water pumping may alleviate trade-offs between water and energy by supplying water while putting less pressure on exhaustible energy resources (Kalogirou, 2005; Omer, 2001). Given the intermittent nature of wind and solar energy production, they may be especially suitable to applications such as desalination and pumping, which may be more tolerant to intermittent energy supply than a region’s electrical grid (Webber, 2015). Technological development, guided by FEW system analysis insights, may lead to significant gains in FEW security for tropical communities.

There are opportunities for institutional reforms in the context of FEW systems in the tropics. In particular, policies can be redesigned or initialized to balance economic interests and ecological sustainability in tropical agricultural landscapes (Drescher et al., 2016) and to account for social equity (Calvet-Mir, Corbera, Martin, Fisher, & Gross-Camp, 2015), especially for underrepresented groups (Biggs et al., 2015). Given that the majority of additional food production to satisfy the world food demand will come from the tropics, international food market and prices will also play a role in the environmental sustainability of the tropics.