Incentivizing interdependent resource management: watersheds, groundwater, and coastal ecology
by Burnett, Kimberly, Roumasset, James, Wada, Christopher, UHERO, June 9, 2014
Managing water resources independently may result in substantial economic losses when those resources are interdependent with each other and with other environmental resources. We first develop general principles for using resources with spillovers, including corrective taxes (subsidies) for incentivizing private resource users. We then analyze specific cases of managing water resources, in particular the interaction of groundwater with upstream or downstream resource systems.
LINK: Working Paper
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Groundwater Economics without Equations
From UHERO, June 6, 2014
In many parts of the world, irrigation and groundwater consumption are largely dependent on groundwater. Minimizing the adverse effects of water scarcity requires optimal as well as sustainable groundwater management. A common recommendation is to limit groundwater extraction to maximum sustainable yield (MSY). Although the optimal welfare-maximizing path of groundwater extraction converges to MSY in some cases, MSY generates waste in the short and medium term due to ambiguity regarding the transition to the desired long-run stock level and failure to account for the full costs of the resource. However, the price that incentivizes optimal consumption often exceeds the physical costs of extracting and distributing groundwater, which poses a problem for public utilities facing zero excess-revenue constraints. We discuss how the optimal price can be implemented in a revenue-neutral fashion using an increasing block pricing structure. The exposition is non-technical. More advanced references on groundwater resource management are also provided.
Link: Working Paper
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The Good, Bad, and Ugly of Watershed Management
From UHERO, June 4, 2014
Efficient management of groundwater resource systems requires careful consideration of relationships — both positive and negative — with the surrounding environment. The removal of and protection against “bad” and "ugly" natural capital such as invasive plants and feral animals and the enhancement of “good” capital (e.g. protective fencing) are often viewed as distinct management problems. Yet environmental linkages to a common groundwater resource suggest that watershed management decisions should be informed by an integrated framework. We develop such a framework and derive principles that govern optimal investment in the management of two types of natural capital — those that increase recharge and those that decrease recharge — as well as groundwater extraction itself. Depending on the initial conditions of the system and the characteristics of each type of natural capital, it may make sense to remove bad capital exclusively, enhance good capital exclusively, or invest in both activities simultaneously until their marginal benefits are equal.
Link: Working Paper
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Optimal Joint Management of Interdependent Resources: Groundwater vs. Kiawe (Prosopis pallida)
From UHERO June 4, 2014
Local and global changes continue to influence interactions between groundwater and terrestrial ecosystems. Changes in precipitation, surface water, and land cover can affect the water balance of a given watershed, and thus affect both the quantity and quality of freshwater entering the ground. Groundwater management frameworks often abstract from such interactions. However, in some cases, management instruments can be designed to target simultaneously both groundwater and an interdependent resource such as the invasive kiawe tree (Prosopis pallid), which has been shown to reduce groundwater levels. Results from a groundwater-kiawe management model suggest that at the optimum, the resource manager should be indifferent between conserving a unit of groundwater via tree removal or via reduced consumption. The model’s application to the Kona Coast (Hawai‘i) showed that kiawe management can generate a large net present value for groundwater users. Additional data will be needed to implement full optimization in the resource system.
Link: Working Paper
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