1 / 12

Environment, Climate, and Earth Science

Environment, Climate, and Earth Science. Forrest M. Hoffman and Monty Vesselinov, Co-Leads. Grand Challenges in Earth Science. FE: Double hydrocarbon extraction efficiency from unconventional reservoirs and diminish environmental impacts GTO: Discover and exploit hidden geothermal resources

edwardwright
Download Presentation

Environment, Climate, and Earth Science

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Environment, Climate, and Earth Science Forrest M. Hoffman and Monty Vesselinov, Co-Leads

  2. Grand Challenges in Earth Science • FE: Double hydrocarbon extraction efficiency from unconventional reservoirs and diminish environmental impacts • GTO: Discover and exploit hidden geothermal resources • CCUS (Carbon capture utilization and storage): Maximize carbon storage efficiency while managing subsurface pressures, and maximizing hydrocarbon recovery (site-specific and operational parameters can impact carbon storage efficiency by an order of magnitude) • BER: Will the tropics remain a carbon sink under climate change?

  3. Grand Challenges in Earth Science • BER: Is there increased wood density in the warming Arctic, and will it increase rapidly enough to counteract loss of permafrost carbon? What’s the balance of carbon release between CO2 and CH4? • BER: Can we reduce uncertainty in aerosol and cloud processes to improve climate prediction? • BER: Can we accurately predict glacier loss and sea level rise? • BER: How will watershed hydrology and nutrient/solute/metal biogeochemistry change with climate? Role of hot-spots/hot-moments? • BER: How can we use models to predict fluxes across interfaces, including terrestrial-aquatic interfaces?

  4. Grand Challenges in Earth Science • Can we improve localization and yield forecast for sustainable energy production with more accurate climate models? • Can we improve bioenergy crop yield forecasting? (Using, e.g. historical yield, satellite and in situ sensor data). • Can we improve earthquake, tsunami, wildfire, and/or --geothermal energy-- volcanic eruption prediction? (Using, e.g. seismic) • Can we improve urban growth models for short-, medium-, and long-term predictions?

  5. Common Themes • Data are disparate or diverse, missing, too short, or at the wrong spatial or temporal scale • Big data challenges vs. small data challenges, and their connections • Detailed (physics, chemistry, biology) theory is uncertain; new hypotheses and algorithms could be applied • Model evaluation and benchmarking can characterize biases to constrain future projections • Emergent constraints can be useful to constrain future projections based on contemporary observations of states or variability

  6. Paths Forward • Models: Surrogate, hybrid AI/process, subgrid scale • Data: Reduction, spatial/temporal extrapolation, subgrid scale • Forecasting: Short- to medium-range (info theory), extreme events, stochasticity

  7. Environment, Climate, and Earth Science Summary for Day 2 Discussion

  8. Grand Challenges in Earth Science (1/3) • Subsurface characterization and simulation • FE: How can we double hydrocarbon extraction efficiency from unconventional reservoirs and diminish environmental impacts? • GTO: How do we optimally discover and exploit hidden geothermal resources? • CCUS: How do we maximize carbon storage efficiency? • BER: Can we couple continental-scale surface and subsurface interactions?

  9. Grand Challenges in Earth Science (2/3) • Predictive understanding of terrestrial ecosystem responses to environmental change and Earth system feedbacks • BER: Will the tropics remain a carbon sink under environmental change? • BER: Is wood density increasing in the Arctic and to what degree will it counteract the loss of permafrost carbon? • BER: How will watershed hydrology and nutrient biogeochemistry change as a result? • BER: What are the Earth system feedbacks (water, energy, carbon, nutrients)?

  10. Grand Challenges in Earth Science (3/3) • Human impacts and environmental sustainability • BER: Can we provide realistic, high resolution predictions of weather and climate at urban scales through direct simulation and/or downscaling? • BER: Can we accurately predict glacier loss, sea level rise, assess risk and vulnerability? • BETO: Can we improve bioenergy crop yield forecasting and resulting energy production? • BER: Can we predict water availability and quality under environmental change for human impacts, agriculture, and energy production and use?

  11. Common Themes from Earth Science Challenges • Data are disparate or diverse, missing, too short, or at the wrong spatial or temporal scale • Big data challenges vs. small data challenges, and their connections • Detailed (physics, chemistry, biology) theory is uncertain; new hypotheses and algorithms could be applied • Model evaluation and benchmarking can characterize biases to constrain future projections • Emergent constraints can be useful to constrain future projections based on contemporary observations of states or variability

  12. Potential Paths Forward in Earth Science • Models: Surrogate models, hybrid AI/process models, subgrid scale parameterizations • Data: Reduction, spatial/temporal extrapolation, subgrid scale characterization, model–data integration • Forecasting: Short- to medium-range (info theory), extreme events vs. mean state, stochasticity, parameter/structural uncertainty and sensitivity

More Related