Geo-Engineering Challenges to Marine Biodiversity { Richard Norris; SIO-UCSD Major challenges to Marine Biodiversity Direct human impacts (immediate effects) • Reduce biodiveristy & resilience • Both top-down and bottom-up impacts • Reduce mobility in face of climate change Human environments typically: • species poor • short food-chains homogeneous • disturbed • have imported energy and nutrients Major challenges to Marine Biodiversity Indirect human impacts (long-range impacts) due to Global change • Acidification • Stratification • Altered PPT patterns • Storm and sea-level impacts on coasts Keeping Perspective Consider the nature of impacts that would exist under a business-as-usual scenario Partial solutions may be preferable to no solution …But there are worries that partial solutions will sap political will to act Three types of Geo-engineering Albedo enhancement Reflectors, Cloud production and Ground-based albedo enhancement Land-based Carbon Sequestration CO2 into oil wells, saline aquifers, Enhanced weathering Ocean-based Carbon Sequestration Ocean dumping of CO2, Biochar, Nutrient fertilization, Enhanced weathering Can also think about just two categories Methods that change the chemistry of systems • These typically address the acidification issue as well as climate change Those that do not…. • Usually only deal with temperature Albedo-enhancing Geoengineering Consequences Common themes—no reduction of: • CO2 absorption in ocean • acidification • environmental loading of other waste products of fossil fuel burning—NOx, SOx, trace metals (many of them heavy metals) • NOx already a problem in coastal water ways • Carbon-particulates (ash) Reflectors in space Changes albedo at the top of the atmosphere • Because these are in space, the main impacts on ecosystems come from potential changes in weather systems, ppt, land-sea contrasts, and continued acidification • Diminished UV may also affect composition of surface ocean phytoplankton Reflectors in space Impacts from changes in weather • Severity related to shifting ‘natural’ processes into new frequency, geographic position, or stable states. • Mucking around with the PDO, NAO and other multi-decadal cycles • e.g. Mantua et al. 1997, Bull Am, Met. Soc • Of course, all these happen anyway with global change. Cloud Seeding with Salt Spray Increasing cloudiness: • Changes community structure toward low-light intensity communities with potential impacts on export production; Clouds may affect air-sea temperature contrast • Storm intensity & evaporation weakened (Mahmud 2009 Singapore J Trop. Geography) • Implications for nutrient exchange between thermocline and surface. • Create a permanent, local el-Niño? Shepard et al. 2009 after Latham et al, 2008 Some other impacts of cloud ‘whitening’ Water removal could affect: • Larval abundance and viability (like desalination plants) Permanent installations • Act as giant open-ocean habitats (Fish Aggregation Devices) for highly-migratory fishes and marine mammals SO2 addition to atmosphere Acid rain • • • Sure, but the ocean is big and relatively well mixed More of a problem for poorly buffered terrestrial systems BUT, deposition on snow or ice could create a runoff acid pulse to coastal waters—problematic for Arctic, Antarctic… www.swisseduc.ch/glaciers SO2 addition to atmosphere Ozone destruction • increases UV influence in surface ocean • but ocean absorbs UV efficiently • Experiments show some diatoms (Pseudonitzschia) do well in high UV waters (Mengelt & Prezelin (2005) Mar-Ecol. Prog Series) • UV also reduced overall phytoplankton production (Llabres & Agusti 2010 Aquatic Microb. Bio; Finkel et al. 2010; J. Plank. Res) • Could be a problem for seabirds, seal colonies (walrus, fir seals, elephant seals…) These seem unlikely to have a major impact on marine communities • Unless they alter weather • Water runoff • Sediment and nutrient transport by wind, streams or dissolved ground water flows. Ocean-based C-Sequestration Major impacts from land-based enhanced weathering: • Could change the flows of dissolved compounds (like bicarbonate ion) and cations into ocean water. • Waste streams are likely to be concentrated • Have many of the same impacts as saline outfall from desalination plants • Could offset ocean acidification • But this depends upon where outfall is delivered • Local alkalinity spikes might contribute to ‘whitings’ Trace metals are the problem • Peridotite is not a completely benign substance • due to imbalances in Mg/Ca ratios • High concentrations of Ni, Co, Cr; low Mo • A “serpentine barrens” of the sea? US Forest Service Enhanced Weathering Dumping effluent from enhanced weathering like other waste streams • Tend to produce reduced biodiversity & short food chains Ocean-based Carbon Sequestration Consumption of other bio-limiting nutrients • Causes Fe-fertilization to ‘rob’ downstream communities of nutrients Shortening food chains • Changes in marine community structure depending upon type of phytoplankton production • increased primary production would likely shorten food chains and reduce biodiversity. Nutrient Fertilization O2 consumption • Impacts of doubling c-flux to the sea floor on benthic communities • Ocean O2 (Keeling et al. 2010, Ann Rev Mar. Sci; Shaffer et al. 2009 Nature Geosci) • Models already predict up to ~60% volume of ocean affected by ocean hypoxia in coming millennia • A return to the Cretaceous? Ocean-based Carbon Sequestration Biochar storage in the ocean • Potential habitat for wood-loving taxa; • if stored as wood or biomass has short lifecycle owing to ship worms (>> Century) askNature.org Geo-engineering-final thoughts • CO2 removal either by political will or technology deals with most problems • CO2 dumping in ocean could be problematic if not neutralized by carbonate or buried. • From a biodiversity perspective, solutions that leave acidification in place are the most dangerous (e.g. albedo enhancement) • But, in short-term, direct human impacts are the major threat