• Exploring Climate‐Smart Land Management for Atlantic Europe

      Schulte, Rogier P. O.; O'Sullivan, Lilian; Coyle, Cait; Farrelly, Niall; Gutzler, Carsten; Lanigan, Gary; Torres‐Sallan, Gemma; Creamer, Rachel E.; Dairy Research Trust; Department of Agriculture, Food and the Marine (Wiley, 2016-09)
      Core Ideas Managing soil organic carbon is an essential aspect of climate‐smart agriculture. Combining component research, we derive a soil carbon management concept for Ireland. Optimized soil carbon management is differentiated in accordance with soil type. Existing policy tools can be tailored to incentivize climate‐smart land management. Soils can be a sink or source of carbon, and managing soil carbon has significant potential to partially offset agricultural greenhouse gas emissions. While European Union (EU) member states have not been permitted to account for this offsetting potential in their efforts to meet the EU 2020 reduction targets, this policy is now changing for the period 2020 to 2030, creating a demand for land management plans aimed at maximizing the offsetting potential of land. In this letter, we derive a framework for climate‐smart land management in the Atlantic climate zone of the EU by combining the results from five component research studies on various aspects of the carbon cycle. We show that the options for proactive management of soil organic carbon differ according to soil type and that a spatially tailored approach to land management will be more effective than blanket policies.
    • Functional Land Management: Bridging the Think-Do-Gap using a multi-stakeholder science policy interface

      O’Sullivan, Lilian; Wall, David; Creamer, Rachel; Bampa, Francesca; Schulte, Rogier P. O.; National Development Plan 2007–2013; European Union; 13S468; 635201; 677407 (Springer Science and Business Media LLC, 2017-11-24)
      Functional Land Management (FLM) is proposed as an integrator for sustainability policies and assesses the functional capacity of the soil and land to deliver primary productivity, water purification and regulation, carbon cycling and storage, habitat for biodiversity and recycling of nutrients. This paper presents the catchment challenge as a method to bridge the gap between science, stakeholders and policy for the effective management of soils to deliver these functions. Two challenges were completed by a wide range of stakeholders focused around a physical catchment model—(1) to design an optimised catchment based on soil function targets, (2) identify gaps to implementation of the proposed design. In challenge 1, a high level of consensus between different stakeholders emerged on soil and management measures to be implemented to achieve soil function targets. Key gaps including knowledge, a mix of market and voluntary incentives and mandatory measures were identified in challenge 2.