Climate balancing: sea-level rise vs. surface temperature change rates

Climate balancing: sea-level rise vs. surface temperature change rates

UNIVERSITY PARK, Pa. -- Engineering our way out of global climate warming may not be as easy as simply reducing the incoming solar energy, according to a team of University of Bristol and Penn State climate scientists. Designing the approach to control both sea level rise and rates of surface air temperature changes requires a balancing act to accommodate the diverging needs of different locations.

"Basic physics and past observations suggest that reducing the net influx of solar energy will cool the Earth," said Peter J. Irvine, graduate student, University of Bristol, UK, and participant in the Worldwide Universities Network Research Mobility Programme to Penn State. "However, surface air temperatures would respond much more quickly and sea levels will respond much more slowly."

Current solar radiation management approaches include satellites that block the sun, making the Earth's surface more reflective or mimicking the effects of volcanoes by placing aerosol particles in the upper atmosphere.

"These solar radiation management approaches could be cheaper than reducing carbon dioxide emissions," said Klaus Keller, associate professor of geosciences, Penn State. "But they are an imperfect substitute for reducing carbon dioxide emissions and carry considerable risks."

How well they work at reducing sea level rise or surface air temperatures depends on how they are implemented.

"Strategies designed to reverse sea-level rise differ from the strategies designed to limit the rate of temperature changes," said Ryan Sriver, research associate in geosciences, Penn State.

To stop or reverse sea-level rise, the incoming solar radiation would have to be decreased rapidly, but this approach would produce rapid cooling. Adopting a more gradual approach would reduce the risks due to rapid cooling, but would allow for considerable sea-level rise.

The researchers note that people living close to sea level are likely more concerned about sea-level rise than about the rates of surface temperature changes. In contrast, those living far from the oceans, are likely more concerned about rates of surface temperature changes that can influence agricultural or energy usage.

The researchers used a model to analyze the tension between controlling sea level rise and rates of surface temperature changes. They ran 120 scenarios with differing combinations of solar radiation management (SRM) including one called "business as usual," which has no SRM.

They note that their model includes many approximations. For example, it does not include a mechanistic representation of ice sheets. They also did not consider scenarios that combine solar radiation management and reducing carbon dioxide emissions.

They report in the current issue of Nature Climate Change that the forcing required to stop sea-level rise could cause a rapid cooling with a rate similar to the peak business-as-usual warming rate.

"While abrupt cooling may sound like a good idea, it could be more damaging than the increasing temperatures caused by increasing carbon dioxide," said Keller.

"The rate of cooling can be a problem if it exceeds the capacity of the plants and animals to adapt," said Sriver.

Another consideration when implementing solar radiation management approaches is that these approaches can require a long-term commitment. The researchers showed that "termination of solar radiation management was found to produce warming rates up to five times greater than the maximum rates under the business-as-usual scenario, whereas sea-level rise rates were only 30 percent higher."

To avoid such harsh changes, should SRM be discontinued, requires a slow phase out over many decades. This places a commitment on future generations.

The National Science Foundation, Penn State Center for Climate Risk Management and the Worldwide Universities Network at the University of Bristol partially funded this work.

How will the Earth system change in the future?

How will the Earth system change in the future?

As the world consumes ever more fossil fuel energy, greenhouse gas concentrations will continue to rise and Earth's average temperature will rise with them. The Intergovernmental Panel on Climate Change (or IPCC) estimates that Earth's average surface temperature could rise between 2°C and 6°C by the end of the 21st century.

Earth

Earth is a complex, dynamic system we do not yet fully understand. The Earth system, like the human body, comprises diverse components that interact in complex ways. We need to understand the Earth's atmosphere, lithosphere, hydrosphere, cryosphere, and biosphere as a single connected system. Our planet is changing on all spatial and temporal scales. The purpose of NASA's Earth science program is to develop a scientific understanding of Earth's system and its response to natural or human-induced changes, and to improve prediction of climate, weather, and natural hazards.

This is a composite image of the North African Continent. A dust storm can be seen blowing off the coast of Morocco in the northwest corner.
Image: MODIS band combination 1,4,3.

A major component of NASA’s Earth Science Division is a coordinated series of satellite and airborne missions for long-term global observations of the land surface, biosphere, solid Earth, atmosphere, and oceans. This coordinated approach enables an improved understanding of the Earth as an integrated system. NASA is completing the development and launch of a set of Foundational missions, new Decadal Survey missions, and Climate Continuity missions.

The Foundational missions are those missions in development at the time the decadal survey was published and include Aquarius, NPOESS Preparatory Project (NPP),Landsat Data Continuity Mission (LDCM), and Global Precipitation Measurement (GPM). The Decadal Survey missions are those guided by the decadal survey produced by the National Research Council of the National Academy of Sciences and published in 2007. These missions include Soil Moisture Active-Passive (SMAP), Ice, Cloud and land Elevation Satellite (ICESat-II), Hyperspectral Infrared Imager (HyspIRI), Active Sensing of CO₂ Emissions Over Nights, Days, and Seasons (ASCENDS), Surface Water and Topography (SWOT), Geostationary Coastal and Air Pollution Events (GEO-CAPE), and Aerosol-Clouds-Ecosystems (ACE). Earth Venture, also a recommendation of the decadal survey, consists of low cost, competed suborbital and orbital missions as well as instruments for Missions of Opportunity.The Climate Continuity missions include Orbiting Carbon Observatory-2 (OCO-2), Stratospheric Aerosol and Gas Experiment – III (SAGE III), Gravity Recovery and Climate Experiment Follow-on (GRACE-FO), and Pre-Aerosol, Clouds, and Ocean Ecosystem (PACE).

Over the coming decades, NASA and the Agency's research partners will continue to pioneer the use of both spaceborne and aircraft measurements to characterize, understand, and predict variability and trends in Earth's system for both research and applications. Earth is the only planet we know to be capable of sustaining life. It is our lifeboat in the vast expanse of space. Over the past 50 years, world population has doubled, grain yields have tripled and economic output has grown sevenfold. Earth science research can ascertain whether and how the Earth can sustain this growth in the future. Also, over a third of the US economy - $3 trillion annually - is influenced by climate, weather, and natural hazards, providing economic incentive to study the Earth.

NASA Earth System Science conducts and sponsors research, collects new observations, develops technologies and extends science and technology education to learners of all ages. We work closely with our global partners in government, industry, and the public to enhance economic security, and environmental stewardship, benefiting society in many tangible ways. We conduct and sponsor research to answer fundamental science questions about the changes we see in climate, weather, and natural hazards, and deliver sound science that helps decision-makers make informed decisions. We inspire the next generation of explorers by providing opportunities for learners of all ages to investigate the Earth system using unique NASA resources, and our Earth System research is strengthening science, technology, engineering and mathematics education nationwide.

Ecosystem Science

Ecosystem Science

The Ecosystem Science Group conducts fundamental research to develop an understanding of mechanisms of terrestrial response to environmental change at multiple scales for the projection of the fate and function of terrestrial biomes in the future.

The Ecosystem Science Group conducts research to understand and predict environmental change impacts on carbon, water and nutrient cycles of terrestrial ecosystems and their feedbacks to climate and how changes in ecosystem structure and land use alter those biogeochemical feedbacks. It designs, constructs and operates targeted, large-scale, field experiments to predict vulnerability of terrestrial ecological systems to projected changes in climate and atmospheric composition and how those responses might alter both the delivery of ecosystem goods anCumulative Effects of Decadal CO₂ Enrichment on Forest Soil Microbial Processes and Communitiesd services and the feedbacks from ecosystems to the atmosphere and climate. It also establishes measurements and experiments to obtain the knowledge required to reduce or eliminate critical uncertainties, and to identify and fill gaps in the representation of fundamental processes within existing ecological model at multiple scales.

Ecosystem Simulation Science advanced by our group organizes and extrapolates process understanding of ecological mechanisms for regional analysis and prognostic calculation of global terrestrial  biome functions

The Environmental Sciences Division

The Environmental Sciences Division (ESD) is an interdisciplinary research and development organization with more than 60 years of achievement in local, national, and international environmental research. Our vision is to expand scientific knowledge and develop innovative strategies and technologies that will strengthen the nation's leadership in creating solutions to help sustain the Earth’s natural resources. Scientists in ESD conduct research, develop technology, and perform analyses to understand and assess responses of environmental systems at the environment-human interface and the consequences of alternative energy and environmental strategies. We seek to understand how natural and anthropogenic factors (e.g., global and regional change, environmental stress, and energy production and use) interact to influence environmental systems and society. Our methods integrate field and laboratory methods with new theory, modeling, data systems, policy analysis, and evaluation to create solutions to complex environmental challenges.

We have six core areas of research that frame our objectives in advancing environmental science, technology, and policy:

Earth and Aquatic Sciences

Create and apply new knowledge across multiple scales to aid decision-makers on the stewardship of air, water, and land resources

• Atmospheric and Aerosol Sciences
• Ecological Assessment
• Environmental Chemistry & Technology
• Field- Scale Research
• Subsurface Science
• Sustainability & Technology Deployment

Ecosystem Science

Understanding mechanisms of organism-to-community responses to environmental changes at multiple scales to project the fate and function of ecosystems

• Ecosystem Simulation Science
• Experimental Terrestrial Ecology
• Nutrient Biogeochemistry
• Terrestrial Water-Carbon Cycles

Environmental Data Science & Systems

Provide data management and analysis for large, integrated environmental databases to the nation’s research community and policymakers

• Atmospheric Radiation Measurements (ARM) Archive
• Carbon Dioxide Information Analysis Center
• ORNL Distributed Active Archive Center for Biogeochemical Dynamics(ORNL DAAC)
• USA National Phenology Network (USA-NPN)
• National Biological Information Infrastructure (NBII) Metadata Clearinghouse

Renewable Energy Systems

Develop methods and models; conduct analyses; and produce tools that address key issues at the intersection of science, technology, society, and policy

• BioEnergy Resource & Engineering Systems
• Energy Analysis
• Landscape Ecology & Regional Analysis
• Multi-Scale Energy-Environmental Systems
• Society-Technology Interactions

Human Health Risk & Environmental Analysis

Conduct analyses for decision-makers to assess (1) emerging technologies and products and (2) methods for identifying and managing the hazards of energy and national security projects, as well as the disposition of their related wastes

• Environmental Analysis
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Energy-Water-Ecosystem Engineering

Sustainable energy production and water availability in healthy ecosystems through technology development, systems analysis, and decision support.

• Application Areas
  – Hydropower Technology RD&D
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  – Water Supply and Competing Water Use Analysis

• Science-to-Energy Challenges
  – Joint optimization of ecological health and water-dependent energy production
  – Organism, population, and commnunity response to energy infrastructure perturbations
  – Role of climate variability in robust energy-water infrastructure design
  – Use of hydrodynamic modeling, advanced materials and sensors for water power cost-of-energy improvements