Evaluating the Cost-Effectiveness of Green Infrastructure for Mitigating Diffuse Agricultural Contaminant Losses

Matthews, Yvonne; Holland, Paula; Matheson, Fleur E.; Craggs, Rupert J.; Tanner, Chris C.

Evaluating the Cost-Effectiveness of Green Infrastructure for Mitigating Diffuse Agricultural Contaminant Losses

Yvonne Matthews, Paula Holland, Fleur E. Matheson, Rupert J. Craggs and Chris C. Tanner ()
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Paula Holland: National Institute of Water and Atmospheric Research (NIWA), Gate 10 Silverdale Rd, Hamilton 3216, New Zealand
Fleur E. Matheson: National Institute of Water and Atmospheric Research (NIWA), Gate 10 Silverdale Rd, Hamilton 3216, New Zealand
Rupert J. Craggs: National Institute of Water and Atmospheric Research (NIWA), Gate 10 Silverdale Rd, Hamilton 3216, New Zealand
Chris C. Tanner: National Institute of Water and Atmospheric Research (NIWA), Gate 10 Silverdale Rd, Hamilton 3216, New Zealand

Land, 2024, vol. 13, issue 6, 1-24

Abstract: New Zealand’s agricultural sector faces the challenge of maintaining productivity while minimizing impacts on freshwaters. This study evaluates the cost-effectiveness of various green infrastructure systems designed to reduce diffuse agricultural sediment and nutrient loads. Utilizing a quantitative economic and contaminant reduction modeling approach, we analyze the impacts of five interceptive mitigation systems: riparian grass filter strips, constructed wetlands, woodchip bioreactors, filamentous algal nutrient scrubbers, and detainment bunds. Our approach incorporates Monte Carlo simulations to address uncertainties in costs and performance, integrating hydrological flow paths and contaminant transport dynamics. Mitigation systems are assessed individually and in combination, using a greedy cyclical coordinate descent algorithm to find the optimal combination and scale of a system for a particular landscape. Applying the model to a typical flat pastoral dairy farming landscape, no single system can effectively address all contaminants. However, strategic combinations can align with specific freshwater management goals. In our illustrative catchment, the mean cost to remove the full anthropogenic load is NZD 1195/ha for total nitrogen, NZD 168 for total phosphorus, and NZD 134 for suspended solids, but results will vary considerably for other landscapes. This study underscores the importance of tailored deployment of green infrastructure to enhance water quality and support sustainable agricultural practices.

Keywords: Nature Based Solutions; economic optimisation; edge-of-field mitigation; water quality; riparian buffers; constructed wetlands; algal turf scrubber; denitrifying bioreactor; detainment bunds (search for similar items in EconPapers)
JEL-codes: Q15 Q2 Q24 Q28 Q5 R14 R52 (search for similar items in EconPapers)
Date: 2024
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