Critical analysis of the governance of the Sainte Luce Locally Managed Marine Area (LMMA), southeast Madagascar

The Marine Protected Area Governance (MPAG) framework is applied to critically assess the governance of the Sainte Luce Locally Managed Marine Area (LMMA), southeast Madagascar. Madagascar experiences rapid population growth, widespread poverty, corruption and political instability, which hinders natural resource governance. Community-based natural resource management (CBNRM) has been repeatedly employed to circumvent the lack of state capacity. This includes the LMMA model, which has rapidly proliferated, represented by MIHARI, Madagascar's LMMA network. The lobster fishing is the primary source of income for households in the impoverished community of Sainte Luce, one of the key landing sites in the regional export industry. However, fishers, industry actors and available data suggest a significant decline of local and regional stocks, likely due to over-exploitation driven by poverty and migration. In 2013, SEED Madagascar a UK NGO, worked to establish community-based fishery management in Sainte Luce, setting up a local management committee, which introduced a periodic no take zone (NTZ). Despite the community's efforts and some significant achievements, the efficacy of management is limited. To date, limited state support and the lack of engagement by actors throughout the value chain have hampered effective governance. The study reinforces the finding that resilient governance relies on a diversity of actors and the incentives they collectively employ. Here and elsewhere, there is a limit to what can be achieved by bottom-up approaches in isolation. Resilient management of marine resources in Madagascar relies on improving the capacity of community, state, NGO and industry actors to collectively govern resources

Contractor Drilling with Pounder II

Project Manager Dr Richard Carter, Institute of Water and Environment, Cranfield University at Silsoe.This report contributes to the findings, implications, and future plans of a project, initiated by Cranfield University (Silsoe, UK) entitled “Private Sector Participation in Low Cost Water Well Drilling”.The project was funded by DFID from July 1998 to June 2001, with additional funding partners (Government of Uganda, DANIDA, SIDA, UNICEF, Water Aid, and an anonymous donor) joining at various stages throughout this three-year period

Simulating alternative sustainable water futures

In the United States of America, urban areas of the arid Southwest are prone to drought risk and changing precipitation patterns; future water supplies are uncertain. A collaborative working group of researchers and practitioners developed alternative future scenarios for 2060—sustainable water futures—that incorporate standard and novel water-adaptation strategies for the Phoenix metropolitan area (hereafter “Phoenix”) in central Arizona, USA. The authors adapted WaterSim-6, a water policy and planning model, to explore differences in water demand and supply for three scenarios as influenced by (1) runoff from the rivers that supply surface water to Phoenix, (2) population growth, (3) water use efficiency, (4) annual rainfall, and (5) land-cover land-use changes. Centralized water-management strategies (direct and indirect potable water reuse and reclaimed supplies) and decentralized strategies (rainwater harvesting and greywater use) were explored. We observed decreased reliance on surface water supplies, offset by increased municipal groundwater pumping in the Strategic scenario, but by alternative water supplies (non-potable water sources including greywater, reclaimed water, and rainwater harvested) in the Desert Wetland and Almost Zero Waste (AZW) scenarios. Even under modest policy implementation and service-connection adoption rates associated with our Strategic scenario, by 2060 alternative supplies from non-potable sources could offset 30% or more of outdoor water demand. Aggressive policy implementations associated with the AZW scenario suggest that up to 80% of outdoor water demand could likewise be met. The WaterSim platform combined with co-produced future scenarios illuminates tradeoffs in support of decision making for long-term sustainability of a water-limited region