Your search keyword '"Horton, Radley M."' showing total 8 results

1. Uncertainty in Twenty-First-Century CMIP5 Sea Level Projections

Author

Little, Christopher M., Horton, Radley M., Kopp, Robert E., Oppenheimer, Michael, and Yip, Stan

Published

2015

2. Reducing spread in climate model projections of a September ice-free Arctic

Author

Liu, Jiping, Song, Mirong, Horton, Radley M., and Hu, Yongyun

Published

2013

3. Mitigation and adaptation emissions embedded in the broader climate transition.

Author

Lesk, Corey, Csala, Denes, Hasse, Robin, Sgouridis, Sgouris, Levesque, Antoine, Mach, Katharine J., Greenford, Daniel Horen, Matthews, H. Damon, and Horton, Radley M.

Subjects

GREENHOUSE gas mitigation, CLIMATOLOGY, CLIMATE change, CARBON emissions, COASTAL development, FOSSIL fuels, CARBON taxes, FOSSIL fuel industries

Abstract

Climate change necessitates a global effort to reduce greenhouse gas emissions while adapting to increased climate risks. This broader climate transition will involve largescale global interventions including renewable energy deployment, coastal protection and retreat, and enhanced space cooling, all of which will result in CO2 emissions from energy and materials use. Yet, the magnitude of the emissions embedded in these interventions remains unconstrained, opening the potential for underaccounting of emissions and conflicts or synergies between mitigation and adaptation goals. Here, we use a suite of models to estimate the CO2 emissions embedded in the broader climate transition. For a gradual decarbonization pathway limiting warming to 2 °C, selected adaptation-related interventions will emit ~1.3 GtCO2 through 2100, while emissions from energy used to deploy renewable capacity are much larger at ~95 GtCO2. Together, these emissions are equivalent to over 2 y of current global emissions and 8.3% of the remaining carbon budget for 2 °C. Total embedded transition emissions are reduced by ~80% to 21.2 GtCO2 under a rapid pathway limiting warming to 1.5 °C. However, they roughly double to 185 GtCO2 under a delayed pathway consistent with current policies (2.7 °C warming by 2100), mainly because a slower transition relies more on fossil fuel energy. Our results provide a holistic assessment of carbon emissions from the transition itself and suggest that these emissions can be minimized through more ambitious energy decarbonization. We argue that the emissions from mitigation, but likely much less so from adaptation, are of sufficient magnitude to merit greater consideration in climate science and policy. [ABSTRACT FROM AUTHOR]

Published

2022

4. Total and Extreme Precipitation Changes over the Northeastern United States.

Author

Huang, Huanping, Winter, Jonathan M., Osterberg, Erich C., Horton, Radley M., and Beckage, Brian

Subjects

PRECIPITATION anomalies, PRECIPITATION forecasting, LONG-range weather forecasting, METEOROLOGICAL stations

Abstract

The northeastern United States has experienced a large increase in precipitation over recent decades. Annual and seasonal changes of total and extreme precipitation from station observations in the Northeast were assessed over multiple time periods spanning 1901-2014. Spatially averaged, both annual total and extreme precipitation across the Northeast increased significantly since 1901, with changepoints occurring in 2002 and 1996, respectively. Annual extreme precipitation experienced a larger increase than total precipitation; extreme precipitation from 1996 to 2014 is 53% higher than from 1901 to 1995. Spatially, coastal areas receive more total and extreme precipitation on average, but increases across the changepoints are distributed fairly uniformly across the domain. Increases in annual total precipitation across the 2002 changepoint are driven by significant total precipitation increases in fall and summer, while increases in annual extreme precipitation across the 1996 changepoint are driven by significant extreme precipitation increases in fall and spring. The ability of gridded observed and reanalysis precipitation data to reproduce station observations was also evaluated. Gridded observations perform well in reproducing averages and trends of annual and seasonal total precipitation, but extreme precipitation trends show significantly different spatial and domain-averaged trends than station data. The North American Regional Reanalysis generally underestimates annual and seasonal total and extreme precipitation means and trends relative to station observations, and also shows substantial differences in the spatial pattern of total and extreme precipitation trends within the Northeast. [ABSTRACT FROM AUTHOR]

Published

2017

5. Enhancing Climate Resilience at NASA Centers: A Collaboration between Science and Stewardship.

Author

Rosenzweig, Cynthia, Horton, Radley M., Bader, Daniel A., Brown, Molly E., DeYoung, Russell, Dominguez, Olga, Fellows, Merrilee, Friedl, Lawrence, Graham, William, Hall, Carlton, Higuchi, Sam, Iraci, Laura, Jedlovec, Gary, Kaye, Jack, Loewenstein, Max, Mace, Thomas, Milesi, Cristina, Patzert, William, Stackhouse, Paul W., and Toufectis, Kim

Subjects

*CLIMATOLOGY, *EARTH scientists, *CLIMATE research

Abstract

A partnership between Earth scientists and institutional stewards is helping the National Aeronautics and Space Administration (NASA) prepare for a changing climate and growing climate-related vulnerabilities. An important part of this partnership is an agency-wide Climate Adaptation Science Investigator (CASI) Workgroup. CASI has thus far initiated 1) local workshops to introduce and improve planning for climate risks, 2) analysis of climate data and projections for each NASA Center, 3) climate impact and adaptation toolsets, and 4) Center-specific research and engagement. Partnering scientists with managers aligns climate expertise with operations, leveraging research capabilities to improve decision-making and to tailor risk assessment at the local level. NASA has begun to institutionalize this ongoing process for climate risk management across the entire agency, and specific adaptation strategies are already being implemented. A case study from Kennedy Space Center illustrates the CASI and workshop process, highlighting the need to protect launch infrastructure of strategic importance to the United States, as well as critical natural habitat. Unique research capabilities and a culture of risk management at NASA may offer a pathway for other organizations facing climate risks, promoting their resilience as part of community, regional, and national strategies. [ABSTRACT FROM AUTHOR]

Published

2014

6. Impact of declining Arctic sea ice on winter snowfall.

Author

Jiping Liu, Curry, Judith A., Huijun Wang, Mirong Song, and Horton, Radley M.

Subjects

SNOW, ATMOSPHERIC circulation, ARCTIC oscillation, CLIMATOLOGY

Abstract

While the Arctic region has been warming strongly in recent decades, anomalously large snowfall in recent winters has affected large parts of North America, Europe, and east Asia. Here we demonstrate that the decrease in autumn Arctic sea ice area is linked to changes in the winter Northern Hemisphere atmospheric circulation that have some resemblance to the negative phase of the winter Arctic oscillation. However, the atmospheric circulation change linked to the reduction of sea ice shows much broader meridional meanders in midlatitudes and clearly different interannual variability than the classical Arctic oscillation. This circulation change results in more frequent episodes of blocking patterns that lead to increased cold surges over large parts of northern continents. Moreover, the increase in atmospheric water vapor content in the Arctic region during late autumn and winter driven locally by the reduction of sea ice provides enhanced moisture sources, supporting increased heavy snowfall in Europe during early winter and the northeastern and midwestern United States during winter. We conclude that the recent decline of Arctic sea ice has played a critical role in recent cold and snowy winters. [ABSTRACT FROM AUTHOR]

Published

2012

7. Climate Hazard Assessment for Stakeholder Adaptation Planning in New York City.

Author

Horton, Radley M., Gornitz, Vivien, Bader, Daniel A., Ruane, Alex C., Goldberg, Richard, and Rosenzweig, Cynthia

Subjects

*CLIMATE change, *CLIMATOLOGY, *PRIVATE companies

Abstract

This paper describes a time-sensitive approach to climate change projections that was developed as part of New York City's climate change adaptation process and that has provided decision support to stakeholders from 40 agencies, regional planning associations, and private companies. The approach optimizes production of projections given constraints faced by decision makers as they incorporate climate change into long-term planning and policy. New York City stakeholders, who are well versed in risk management, helped to preselect the climate variables most likely to impact urban infrastructure and requested a projection range rather than a single 'most likely' outcome. The climate projections approach is transferable to other regions and is consistent with broader efforts to provide climate services, including impact, vulnerability, and adaptation information. The approach uses 16 GCMs and three emissions scenarios to calculate monthly change factors based on 30-yr average future time slices relative to a 30-yr model baseline. Projecting these model mean changes onto observed station data for New York City yields dramatic changes in the frequency of extreme events such as coastal flooding and dangerous heat events. On the basis of these methods, the current 1-in-10-year coastal flood is projected to occur more than once every 3 years by the end of the century and heat events are projected to approximately triple in frequency. These frequency changes are of sufficient magnitude to merit consideration in long-term adaptation planning, even though the precise changes in extreme-event frequency are highly uncertain. [ABSTRACT FROM AUTHOR]

Published

2011

8. Variability of North Pacific Sea Ice and East Asia–North Pacific Winter Climate.

Author

Jiping Liu, Zhanhai Zhang, Horton, Radley M., Wang, Chunyi, and Ren, Xiaobo

Subjects

PRECIPITATION variability, GLOBAL temperature changes, CLIMATE change, PRECIPITATION anomalies, CLIMATOLOGY, METEOROLOGY, COOLING

Abstract

Sea ice variability in the North Pacific and its associations with the east Asia–North Pacific winter climate were investigated using observational data. Two dominant modes of sea ice variability in the North Pacific were identified. The first mode features a dipole pattern between the Sea of Okhotsk and the Bering Sea. The second mode is characterized by more uniform ice changes throughout the North Pacific. Using the principal components of the two dominant modes as the indices (PC1 and PC2), analyses show that the positive phases of PC1 feature a local warming (cooling) in the Sea of Okhotsk (the Bering Sea), which is associated with the formation of the anomalous anticyclone extending from the northern Pacific to Siberia, accompanied by a weakening of the east Asian jet stream and trough. The associated anomalous southeasterlies/easterlies reduce the climatological northwesterlies/westerlies, leading to warm and wet conditions in northeast China and central Siberia. The positive phases of PC2 are characterized by a strong local warming in the northern Pacific that coincides with the anomalous cyclone occupying the entire North Pacific, accompanied by a strengthening of the east Asia jet stream and trough. The associated anomalous northerlies intensify the east Asian winter monsoon (EAWM), leading to cold and dry conditions in the east coast of Asia. The intensified EAWM also strengthens the local Hadley cell, which in turn strengthens the east Asian jet stream and leads to a precipitation deficit over subtropical east Asia. The linkages between PC1 and PC2 and large-scale modes of climate variability were also discussed. It is found that PC1 is a better indicator than the Arctic Oscillation of the recent Siberian warming, whereas PC2 may be a valuable predictor of EAWM. [ABSTRACT FROM AUTHOR]

Published

2007