Wednesday, March 13, 2024

Methane emissions from U.S. oil and gas operations cost the nation $10 billion per year

STANFORD UNIVERSITY

Oil and gas operations across the United States are emitting more than 6 million tons per year of methane, the main component of natural gas and the most abundant greenhouse gas after carbon dioxide, according to Stanford-led research published March 13 in Nature.

These emissions, which result from both intentional vents and unintentional leaks, amount to $1 billion in lost commercial value for energy producers. The annual cost rises to $10 billion when researchers account for harm to the economy and human well-being caused by adding this amount of heat-trapping methane to Earth’s atmosphere.

The new emission and cost estimates are roughly three times the level predicted by the U.S. government. The results are based on approximately 1 million aerial measurements of U.S. wells, pipelines, storage, and transmission facilities in six of the nation’s most productive regions, including the Permian and Forth Worth in Texas and New Mexico; California’s San Joaquin basin; Colorado’s Denver-Julesburg basin; Pennsylvania’s section of the Appalachian basin; and Utah’s Uinta basin. In all, the infrastructure surveyed in this study accounts for 52% of U.S. onshore oil production and 29% of gas production.

Troubling trends

Emissions in three of the six regions were well above expected values. The New Mexico portion of the Permian Basin was by far the highest emitter, with nearly 10% of total methane volume produced in 2019 going straight to the atmosphere. Surveys of some other regions, however, revealed emission rates well below U.S. EPA Greenhouse Gas Inventory estimates based on national averages, suggesting that good practices can reduce emissions.

“Costs aside, the main message here is that some regions show emissions at rates well above those the government itself uses to estimate methane losses,” said senior study author Adam Brandt, an associate professor of Energy Science & Engineering at the Stanford Doerr School of Sustainability. “We hope this will spur government methane inventories toward greater incorporation of remote sensing data at the heart of those estimates.”

Methane breaks down faster than carbon dioxide, but it is about 80 times more powerful than CO2 when it comes to trapping heat during its first 20 years in our atmosphere. In that time frame, climate damage from the 6 million tons of annual methane emissions found in this study is roughly equivalent to a full year of carbon emissions from all fossil fuel use in Mexico.

Because methane can trap so much heat in the short term, accurate assessments of methane leaks are key to predicting the impacts of climate change that will be felt in our lifetime and verifying emissions reductions at a time when the U.S. and more than 100 other countries have pledged to cut emissions 30% below 2020 levels by 2030.

Eyes in the sky

By showing that leaks cost industry more than a billion dollars a year, the researchers hope to gain producers’ attention and motivate them to voluntarily stop emissions at their own facilities as a cost-saving measure. Additionally, the researchers say total costs from methane leaks and vents in the six-region study area are likely much higher, as the survey covered less than half of the facilities in the area.

The authors found fewer than two percent of emitters are responsible for 50 to 80% of emissions in all surveyed regions except for Colorado’s Denver-Julesburg basin and Utah’s Uinta basin. In terms of types of production facilities most likely to leak, the study noted that midstream infrastructure was responsible for about half of total emissions, which is higher than previous estimates. Midstream infrastructure includes gathering and transmission pipelines, compressor stations, and gas processing plants that shuttle gas from the wells to cities and towns.

“Solving the methane challenge is not quite as easy as simply finding and fixing a handful of leakers, as these stark numbers might suggest, but it does mean that efforts concentrated on relatively few operations could have considerable benefits,” said lead study author, Evan Sherwin, a research scientist at Lawrence Berkeley National Laboratory who worked on the research as a postdoctoral scholar in Brandt’s lab at Stanford.

Measurement matters

The research combined direct aerial measurements with an emissions simulation tool developed in Brandt’s group at Stanford by study co-author Jeffrey Rutherford, PhD ’22, to estimate the emissions that would be too small for the aircraft to reliably detect. The companies Kairos Aerospace and Carbon Mapper provided two different but complementary approaches to measuring methane emissions from specific facilities via airplane-borne sensors.

Total estimated leaked emissions range from just less than one percent to as much as 9.6% of total volume, with an average of 3% across the surveyed regions. The federal government estimates that methane emissions from oil and gas facilities nationwide average roughly 1% of gas production. Sherwin noted that in the surveyed regions of Pennsylvania and Colorado, the team’s estimates were on par with or lower than estimates from the U.S. Environmental Protection Agency.

“Climate change mitigation starts with better tracking of emissions, of course, but also accurate tracking of reduction efforts going forward,” Brandt said. “The method introduced here offers a path to combining measurements at several scales to greatly improve inventories that should lead us to much better tracking of those important reductions critical to national mitigation commitments.”

NOTE: Brandt and team have made their code available for download. Carbon Mapper data can be downloaded from the organization’s website. Anonymized data are also available, in certain cases, by request from Kairos Aerospace.

Brandt is also faculty director of the Stanford Natural Gas Initiative and a senior fellow at the Stanford Precourt Institute for Energy. Rutherford is now employed at Highwood Emissions Management. Additional Stanford co-authors include Energy Science & Engineering PhD students Zhan Zhang and Yuanlei (Yulia) Chen. Other coauthors are affiliated with Kairos Aerospace, Carbon Mapper, University of Arizona, and NASA Jet Propulsion Laboratory.

This study was funded by the Stanford Natural Gas Initiative, NASA’s Carbon Monitoring System and Advanced Information System Technology programs, Carbon Mapper, RMI, the Environmental Defense Fund, the California Air Resources Board, the University of Arizona, the U.S. Climate Alliance, Arizona State University’s Global Airborne Observatory, and the Mark Martinez and Joey Irwin Memorial Public Projects Fund with the support of the Colorado Oil and Gas Conservation Commission, the Colorado Department of Public Health and Environment. Portions of this research were carried out under a contract with NASA.

To read all stories about Stanford science, subscribe to the biweekly Stanford Science Digest.

JOURNAL

Nature

DOI

10.1038/s41586-024-07117-5

ARTICLE TITLE

US oil and gas system emissions from nearly one million aerial site measurements

ARTICLE PUBLICATION DATE

13-Mar-2024

Climate Engine launches new website to facilitate drought and vegetation monitoring

Climate Engine is partnering with the Bureau of Land Management (BLM) to guide drought planning on BLM-managed lands with support from NOAA’s National Integrated Drought Information System (NIDIS)

DESERT RESEARCH INSTITUTE

IMAGE:
FIGURE 1. THE NEW BLM CLIMATE & REMOTE SENSING DATA REPORTS WEBSITE AT REPORTS.CLIMATEENGINE.ORG PROVIDES TIMELY AND CONSISTENT DROUGHT AND SITE CHARACTERIZATION REPORTS, INCREASING ACCESSIBILITY TO DROUGHT AND SATELLITE-BASED VEGETATION DATA FOR RESOURCE MANAGERS.
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CREDIT: DRI/CLIMATE ENGINE

ClimateEngine.org is an innovative tool that provides satellite and climate data in a user-friendly manner to facilitate water conservation, wildfire risk management, agricultural productivity monitoring, and ecological restoration. Created through a partnership between researchers at Desert Research Institute, the University of California Merced, Google, the National Oceanic and Atmospheric Administration, the Bureau of Land Management, and other federal partners, Climate Engine allows users to create maps and time series plots for visualizing complex climate data. Now, the team is launching a new publicly accessible platform designed to produce comprehensive and detailed reports for all BLM-managed lands in the contiguous United States. The reports combine scalable drought summaries and near real-time vegetation conditions to help inform planning and decision-making.

“The goal of this new platform is to lower the barrier to using timely drought and satellite-based vegetation datasets for resource managers,” said Eric Jensen, geospatial data scientist at DRI. “We have worked closely with the BLM Aquatic Resources, Assessment, Inventory, and Monitoring, and Rangeland Management Programs to identify relevant drought indicators, make it easy for managers to pinpoint the land unit they’re interested in, and download a simple report that they can use for reporting and decision-making processes.”

The website provides both drought and site characterization reports that assess drought indicators and satellite-based vegetation cover and productivity over time, with data extending back to 1986 based on the Landsat satellite archive. All reports are publicly free to view and download, which builds transparency into the decision-making process.

“The BLM manages around 245 million acres of land, more than any other federal agency. Having these data not only readily available, but in a usable form, will directly contribute to our mission of responsibly managing environmental, cultural, and historical resources across the country,” said Paula Cutillo, National Water Resource Specialist with the BLM. “The sustained and unprecedented drought currently impacting the Western U.S. challenges sustainable resource management, and we are increasingly considering drought severity, water availability, and drought resilience when making land use decisions. We need all of this information to make balanced, forward-looking decisions in a changing climate.”

The Climate Engine team partnered with NOAA’s National Integrated Drought Information System (NIDIS) to provide multiple drought indicators at higher spatial resolution than what is available through the U.S. Drought Monitor. Users of the new site will see both long-term (up to 5 years) and short-term (up to 9 months) drought information that combines several drought monitoring indices into a single map at decision-relevant scales. Longer-term drought can impact groundwater and reservoir levels, while shorter-term impacts may include drier soils and reduced plant growth. These tools can allow for more precise and directed drought response and management plans. Satellite-based vegetation data is provided through the Rangeland Analysis Platform, with support by the USDA Agricultural Research Service. All data included in the reports are presented in clear, visually appealing maps and graphs, and drought reports are updated every five days.

“NIDIS has promoted the use of Climate Engine within BLM since 2018, and we believe that this new tool will further empower decision makers to use the best available data for their land planning decisions,” said Steve Ansari, U.S. Drought Portal Manager and physical scientist with NOAA’s National Centers for Environmental Information. “These drought reports provide a nearly real-time snapshot of drought conditions at each land unit and are capable of capturing a lot more detail at a scale that supports BLM decisions.”

Future updates and improvements to the platform will include expanded vegetation production reports to further support land use planning and decisions, developing additional drought indicators, and including information about fire history as well as wildfire risk.

Users can refer to detailed guidelines for using the reports, including tutorials and information about the datasets and metrics used, trouble-shooting tips, and answers to frequently asked questions at Support.ClimateEngine.org.

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About Climate Engine

ClimateEngine.org is a collaboration between DRI, University of Merced, Google, and federal partners. The science team includes: DRI researchers Justin Huntington, Britta Daudert, Jody Hansen, Eric Jensen, Thomas Ott, Kristen O’Shea, Charles Morton, and Dan McEvoy as well as UC Merced researchers Katherine Hegewisch and John Abatzaglou. Find out more about the initiative, partnerships, and updates at ClimateEngine.org and Twitter @ClimateEngOrg, and see the initiative's peer-reviewed publication.

About DRI

We are Nevada’s non-profit research institute, founded in 1959 to empower experts to focus on science that matters. We work with communities across the state –and the world– to address their most pressing scientific questions. We’re proud that our scientists continuously produce solutions that better human and environmental health.

Scientists at DRI are encouraged to follow their research interests across the traditional boundaries of scientific fields, collaborating across DRI and with scientists worldwide. All faculty support their own research through grants, bringing in nearly $5 to the Nevada economy for every $1 of state funds received. With more than 600 scientists, engineers, students, and staff across our Reno and Las Vegas campuses, we conducted more than $47 million in sponsored research focused on improving peoples’ lives in 2023 alone.

At DRI, science isn’t merely academic – it’s the key to future-proofing our communities

Media Contact:

Elyse DeFranco
Science Writer, DRI
E: elyse.defranco@dri.edu

The future is likely less skiable, thanks to climate change

Snow scarcity may push popular ski hubs to more remote areas and threaten livelihoods of local populations

PLOS

Global reduction of snow cover in ski areas under climate change — IMAGE:
CLIMATE CHANGE IS PREDICTED TO ALTER SNOWFALL PATTERNS, IMPACTING SKI AREAS WITH ECONOMIC AND ECOLOGICAL CONSEQUENCES. IN THIS STUDY, RESEARCHERS PREDICTED TRENDS IN NATURAL SNOW COVER DAYS THIS CENTURY UNDER THREE DIFFERENT CLIMATE CHANGE SCENARIOS: (LOW CO2 EMISSIONS (SSP1-2.6), HIGH EMISSIONS (SSP3-7.0) AND VERY HIGH EMISSIONS (SSP5-8.5). THE RESULTS SUGGEST SIGNIFICANT DECREASES IN SNOW COVER DAYS ACROSS ALL SKI AREAS (FROM AN AVERAGE OF 216 SNOW COVER DAYS IN THE PAST TO 141 SNOW COVER DAYS IN A HIGH EMISSION SCENARIO), WITH A PARTICULARLY FAST DECREASE IN LOWER ELEVATIONS. THE AUTHORS EXPECT AN EXPANSION OF INFRASTRUCTURE TOWARD HIGHER ELEVATIONS, THREATENING BIODIVERSITY AMONG HIGH-ALTITUDE SPECIES.
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CREDIT: ANNE-LISE PARIS, (WWW.IN-GRAPHIDI.COM), PLOS, CC-BY 4.0 (HTTPS://CREATIVECOMMONS.ORG/LICENSES/BY/4.0/)

Annual snow cover days in all major skiing regions are projected to decrease dramatically as a result of climate change, with 1 in 8 ski areas losing all natural snow cover this century under high emission scenarios. These results are published in a new study in the open-access journal PLOS ONE by Veronika Mitterwallner from the University of Bayreuth, Germany and colleagues.

Popular skiing destinations experience the impacts of climate change, which include reduced snowfall in regions around the world. Despite the social, economic, and ecological significance of the skiing industry, little research exists on how ski area distributions are affected by climate change globally. Existing studies are small-scale and focused on Europe, North America, and Australia.

Mitterwallner and colleagues examined the impact of climate change on annual natural snow cover in seven major skiing regions: the European Alps, Andes Mountains, Appalachian Mountains, Australian Alps, Japanese Alps, Southern Alps (located in New Zealand), and Rocky Mountains.

The researchers identified specific skiing locations within these seven regions using OpenStreetMap. As the largest global ski market, the European Alps accounted for 69% of these areas. The researchers also used the public climate database CHELSA, enabling them to predict annual snow cover days for each ski area for 2011-2040, 2041-2070, and 2071-2100 under low, high, and very high carbon emissions scenarios.

Under the high emissions scenario, 13% of ski areas are predicted to lose all natural snow cover by 2071-2100 relative to their historic baselines. Twenty percent will lose more than half of their snow cover days per year. By 2071–2100, average annual snow cover days were predicted to decline most in the Australian Alps (78%) and Southern Alps (51%), followed by the Japanese Alps (50%), Andes (43%), European Alps (42%), and Appalachians (37%), with the Rocky Mountains predicted to experience the least decline at 23% relative to historic baselines.

The researchers state that diminishing snow cover may prompt ski resorts to move or expand into less populated areas, potentially threatening alpine plants and animals already under climate-induced strain. Resorts favoring faux snow may rely on “technical snowmaking” practices like artificial snow production, but regardless, the authors predict that the economic profitability of ski resorts will fall globally.

The authors add: “This study demonstrates significant future losses in natural snow cover of current ski areas worldwide, indicating spatial shifts of ski area distributions, potentially threatening high-elevation ecosystems.”

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In your coverage please use this URL to provide access to the freely available article in PLOS ONE: https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0299735

Citation: Mitterwallner V, Steinbauer M, Mathes G, Walentowitz A (2024) Global reduction of snow cover in ski areas under climate change. PLoS ONE 19(3): e0299735. https://doi.org/10.1371/journal.pone.0299735

Author Countries: Germany, Switzerland

Funding: Funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) – 491183248. Funded by the Open Access Publishing Fund of the University of Bayreuth. The funders had no role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.