Your search keyword '"Oliver W Frauenfeld"' showing total 68 results

1. The thermal effect of snow cover on ground surface temperature in the Northern Hemisphere

Author

Xiaoqing Peng, Oliver W Frauenfeld, Yuan Huang, Guanqun Chen, Gang Wei, Xuanjia Li, Weiwei Tian, Guangshang Yang, Yaohua Zhao, and Cuicui Mu

Subjects

permafrost, snow cover, observations, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

Snow cover is critical to the ground thermal regime because it affects surface conditions and the energy balance. Prior work inherently included confounding effects from vegetation and the soil when estimating the snow’s effect by using the differences between air and ground surface or soil temperature. Here we use the Kudryavtsev model including a snow module to isolate the effect of only the snow cover during winter, based on observational sites across the Northern Hemisphere. We find that snow’s damping of annual mean ground surface temperature averages 5.06 ± 3.15 °C and ranges 0 °C–10 °C, while damping of the annual ground surface temperature amplitude is 7.95 ± 4.95 °C, ranging 0 °C–20 °C. Greater insulation occurs in the high-latitudes. The insulating effect is primarily driven by snow depth, but also the combination of air temperature and its amplitude, snow depth, and duration. Snow cover duration and low air temperature enhance snow’s insulating ability. These observational results that isolate the damping effect of only the snow could play a significant role in better understanding the energy change between air and the ground.

Published

2024

2. Response of African elephants (Loxodonta africana) to seasonal changes in rainfall.

Author

Michael Garstang, Robert E Davis, Keith Leggett, Oliver W Frauenfeld, Steven Greco, Edward Zipser, and Michael Peterson

Subjects

Medicine, Science

Abstract

The factors that trigger sudden, seasonal movements of elephants are uncertain. We hypothesized that savannah elephant movements at the end of the dry season may be a response to their detection of distant thunderstorms. Nine elephants carrying Global Positioning System (GPS) receivers were tracked over seven years in the extremely dry and rugged region of northwestern Namibia. The transition date from dry to wet season conditions was determined annually from surface- and satellite-derived rainfall. The distance, location, and timing of rain events relative to the elephants were determined using the Tropical Rainfall Measurement Mission (TRMM) satellite precipitation observations. Behavioral Change Point Analysis (BCPA) was applied to four of these seven years demonstrating a response in movement of these elephants to intra- and inter-seasonal occurrences of rainfall. Statistically significant changes in movement were found prior to or near the time of onset of the wet season and before the occurrence of wet episodes within the dry season, although the characteristics of the movement changes are not consistent between elephants and years. Elephants in overlapping ranges, but following separate tracks, exhibited statistically valid non-random near-simultaneous changes in movements when rainfall was occurring more than 100 km from their location. While the environmental trigger that causes these excursions remains uncertain, rain-system generated infrasound, which can travel such distances and be detected by elephants, is a possible trigger for such changes in movement.

Published

2014

3. Changes in the 1963–2013 shallow ground thermal regime in Russian permafrost regions

Author

Dmitry A Streletskiy, Artem B Sherstiukov, Oliver W Frauenfeld, and Frederick E Nelson

Subjects

permafrost, soil temperature, Arctic, active layer, climate change, monitoring, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

Spatial variability and temporal trends of the shallow ground thermal regime and permafrost active-layer thickness (ALT) were estimated over 1963–2013 using daily soil temperature data available from stations of the Russian Hydrometeorological Service. Correlation analysis was used to evaluate the role of changing climatic conditions on the ground thermal regime. ALT data collected by the Circumpolar Active Layer Monitoring program in Russia were used to expand the geography of ALT observations over 1999–2013, and to identify ‘hot spots’ of soil temperature and ALT change. Results indicate that a substantially higher rate of change in the thermal regime of permafrost-affected soils prevailed during 1999–2013, relative to the last fifty years. Results indicate that the thermal regime of the upper permafrost in western Russia is strongly associated with air temperature, with much weaker relationships in central and eastern Russia. The thermal regime of permafrost-affected soils shows stronger dependence on climatic conditions over the last fifteen years relative to the historical 50-year period. Geostatistical analysis revealed that the cities of Norilsk and Susuman are hot spots of permafrost degradation. Of six settlements selected for detailed analysis in various parts of the permafrost regions, all but one (Chukotka), show substantial changes in the shallow ground thermal regime. Northern locations in the continuous permafrost region show thickening of the active layer, while those farther south experienced development of residual thaw layers above the permafrost and decreases in the duration of the freezing period.

Published

2015

4. Observed Retrogressive Thaw Slump Evolution in the Qilian Mountains.

Author

Xingyun Liu, Xiaoqing Peng, Yongyan Zhang, Oliver W. Frauenfeld, Gang Wei, Guanqun Chen, Yuan Huang, Cuicui Mu, and Jun Du

Published

2024

5. Assessment of Temperature Changes on the Tibetan Plateau During 1980–2018

Author

Xiaoqing Peng, Oliver W. Frauenfeld, Haodong Jin, Ran Du, Lina Qiao, Yaohua Zhao, Cuicui Mu, and Tingjun Zhang

Subjects

Astronomy, QB1-991, Geology, QE1-996.5

Abstract

Abstract Surface air temperatures affect a diverse set of physical and biological systems in many parts of the world. For regional‐scale studies, gridded surface air temperature data sets are frequently used as input variables. Here we evaluate 10 commonly used gridded air temperature products with spatial resolutions ranging from 0.1° × 0.1° to 5.0° × 5.0°, relative to observations from in situ weather stations on the Tibetan Plateau. Gridded temperatures are consistently lower, with mean annual air temperature biases ranging from −4.68 °C to −1.72 °C, and root mean square error (RMSE) from 3.24 °C to 6.11 °C. The mean biases of mean seasonal air temperatures for spring, summer, autumn, and winter are −3.21 °C, −2.98 °C, −2.89 °C, and −2.98 °C, respectively, and RMSEs of 4.81 °C, 4.39 °C, 4.3 °C, and 4.7 °C. Of all 10 products, the China meteorological forcing data set compares best with observations. Annual and season temperatures all increase significantly during 1980–2018 on the Tibetan Plateau, with winter dominating the warming rate.

Published

2021

6. Performance and changes of <scp>high‐resolution</scp> (1 km) surface air temperature in Northern Hemisphere permafrost regions

Author

Haodong Jin, Xiaoqing Peng, Oliver W. Frauenfeld, Yaohua Zhao, Xuanjia Li, Weiwei Tian, Cong Chen, Benben Liang, Xiaodong Li, and Cuicui Mu

Subjects

Atmospheric Science

Published

2022

7. Using InSAR for Surface Deformation Monitoring and Active Layer Thickness Retrieval in the Heihe River Basin on the Northeast Qinghai‐Tibet Plateau

Author

Sijia Peng, Xiaoqing Peng, Oliver W. Frauenfeld, Guangshang Yang, Weiwei Tian, Jie Tian, and Jinhui Ma

Subjects

Geophysics, Earth-Surface Processes

Published

2023

8. Quantitative Impact of Organic Matter and Soil Moisture on Permafrost

Author

Ran Du, Xiaoqing Peng, Oliver W. Frauenfeld, Haodong Jin, Kun Wang, Yaohua Zhao, Dongliang Luo, and Cuicui Mu

Subjects

Atmospheric Science, Geophysics, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous)

Published

2023

9. A Comprehensive Dataset for Earth System Models in a Permafrost Region: Meteorological, Permafrost, and Carbon Observations (2011–2020) in Northeastern Qinghai-Tibet Plateau

Author

Cuicui Mu, Xiaoqing Peng, Ran Du, Hebin Liu, Haodong Jin, Benben Liang, Mei Mu, Wen Sun, Chenyan Fan, Xiaodong Wu, Oliver W. Frauenfeld, and Tingjun Zhang

Abstract

It’s important to understand the role of permafrost in the future climate and water resources management, for huge storage of soil organic carbon and ground ice in the permafrost. To date, large uncertainties still exist in permafrost simulations for many reasons. One reason is being a lack of long-term meteorological, permafrost and carbon observations. Here, we therefore present datasets for air temperatures, precipitation, soil temperature and moisture, active layer thickness, ground temperatures at different depths, soil organic carbon contents, and ecosystem carbon emission rates for the Qilian Mountains of the Northeastern Qinghai-Tibetan Plateau during 2011–2020. The data come from 5 automatic meteorological stations, 21 boreholes with depths from 11.5 to 149.3 m, and 12 active layer monitoring sites, which are used to obtain the hydrothermal and thermal states, and climate change in the study area. Soil organic carbon contents is available from 10 deep boreholes, down to a depth of 20 m. Ecosystem respiration rates are obtained from the prevalent vegetation types of alpine wet meadow, meadow, and steppe for the growing seasons. This decade’s high-quality datasets are expected to serve as useful inputs for earth system models, and are for researchers working in those disciplines including geophysics, ecology, and hydrology in alpine environments. The datasets are available from the National Tibetan Plateau/Third Pole Environment Data Center and can be downloaded from http://dx.doi.org/10.11888/Cryos.tpdc.272840 (Mu and Peng, 2022).

Published

2022

10. Comprehensive Assessment of Seasonally Frozen Ground Changes in the Northern Hemisphere Based on Observations

Author

Cong Chen, Xiaoqing Peng, Oliver W. Frauenfeld, Yaohua Zhao, Guangshang Yang, Weiwei Tian, Xuanjia Li, Ran Du, and Xiaodong Li

Subjects

Atmospheric Science, Geophysics, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous)

Published

2022

11. The contribution of changing surface thermodynamics on twentieth and twenty-first century air temperatures over Eurasian permafrost

Author

Oliver W. Frauenfeld and Daniel J. Vecellio

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Atmospheric circulation, Twenty-First Century, Climate change, 010502 geochemistry & geophysics, Permafrost, 01 natural sciences, Latitude, Internal variability, Climatology, Hotspot (geology), Spring (hydrology), Environmental science, 0105 earth and related environmental sciences

Abstract

The high latitudes are a hotspot for past and future climate change as forced climate signals have begun to emerge from internal variability in recent decades. New tools, such as initial condition large ensembles, provide a simulated range of possible climate realities that allow for separating the externally forced and internally variable components of the climate system. In addition, interactions between environmental variables and atmospheric circulation patterns can be detected in an unforced climate scenario and removed to isolate thermodynamic influences on the climate system. In the Arctic, this separation between dynamic and thermodynamic influences can be used to examine the impact of permafrost degradation on surface air temperatures (SAT). While impacts from permafrost degradation and subsequent carbon release have been thoroughly studied, geophysical influences have not received as much attention. This study employs the Community Earth System Model’s Large Ensemble to simulate and analyze these geophysical impacts over three time periods: 1976–2005, 2021–2050, and 2071–2100. As soil is thawing earlier and freezing later, we focus on spring and autumn to determine permafrost’s thermodynamic influence on SAT across Eurasia. We find that large internal variability, primarily due to atmospheric dynamics, affects spring SATs through 2100 while variability in autumn SATs will decrease over time due to increasing thermodynamic surface factors. These thermodynamic surface influences are most prominent in areas of continuous and discontinuous permafrost and lesser in non-permafrost regions, likely the result of a changing seasonal surface energy budget resulting from degradation and loss of permafrost.

Published

2021

12. Surface and sub-surface drivers of autumn temperature increase over Eurasian permafrost

Author

Daniel J. Vecellio and Oliver W. Frauenfeld

Subjects

Atmospheric Science, Global and Planetary Change

Published

2022

13. Effective sea ice area based on a thickness threshold

Author

Victoria L. Ford, Rodrigo J. Bombardi, Oliver W. Frauenfeld, and Christopher J. Nowotarski

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Climate change, Magnitude (mathematics), 010502 geochemistry & geophysics, 01 natural sciences, Arctic ice pack, Ice thickness, Atmosphere, Arctic, Climatology, Sea ice, human activities, Geology, 0105 earth and related environmental sciences

Abstract

As Arctic sea ice declines in response to climate change, a shift from thick multiyear ice to a thinner ice cover is occurring. With this transition, ice thicknesses approach a threshold below which ice no longer insulates the atmosphere from oceanic surface fluxes. While this is well known, there are no estimates of the magnitude of this threshold, nor of the proportion of sea ice area that is below this threshold as ice thins. We determine this threshold by simulating the atmospheric response to varying thicknesses, ranging from 0.0 to 2.0 m and determine that threshold to be 0.40–0.50 m. The resulting “effective” ice area is 4–14% lower than reported total ice area, as 0.39–0.97 × 106 km2 of the total ice area falls below the threshold throughout the twentieth century, including during notable ice minima. The atmosphere above large non-insulating ice-covered regions is susceptible to more than 2 °C of warming despite ice presence. Observed mean Arctic Ocean ice thickness is projected to fall below this threshold as early as the mid-2020s. Studies on ocean–atmosphere interactions in relation to sea ice area should focus on this insulating sea ice area, where ice is at least 0.40–0.50 m thick, and treat ice regions below 0.40–0.50 m thickness with caution.

Published

2021

14. Permafrost response to land use and land cover change in the last millennium across the Northern Hemisphere

Author

Ran Du, Oliver W. Frauenfeld, Tingjun Zhang, and Xiaoqing Peng

Subjects

Land use, Northern Hemisphere, Soil Science, Environmental Chemistry, Environmental science, Physical geography, Land cover, Development, Permafrost, General Environmental Science

Published

2020

15. Comparisons of Statistical Downscaling Methods for Air Temperature Over the Qilian Mountains

Author

Haodong Jin, Xiaodong Li, Oliver W. Frauenfeld, Yaohua Zhao, Cong Chen, Ran Du, Jun Du, and Xiaoqing Peng

Subjects

Atmospheric Science

Abstract

Air temperature is an important indicator of climate change, as well as for understanding changes in hydrology, ecology, and other natural systems. However, meteorological stations that provide reliable temperature observations are usually sparse in areas of complex terrain, thus limiting our ability to quantify high spatial resolution temperature variability in these regions. Here, we apply three statistical downscaling methods to daily air temperature output from the sixth Coupled Model Intercomparison Project (CMIP6), validated with 22 meteorological stations over the Qilian Mountains. Based on different downscaling methods, we find RMSE and MAE are reduced as much as 59–66%, with the ratio of RMSE and MAE to the annual average temperature of stations decreasing from 147.9% to 61.0% and 143.3% to 64.7%, respectively, depending on the method. Compared to the original data, annual temperature based on the best downscaling methods differed by −2.85±3.61°C during the historical 1850–2014 period and, for the 2015–2100 projections, by 2.13±3.30°C for SSP1-2.6, −2.13±3.29°C for SSP2-4.5, −2.11±3.24°C for SSP3-7.0, and −2.12±3.23°C for SSP5-8.5. The downscaled annual air temperatures show a warming trend ranging 0.15­0.22°C/10yr for the historical experiment, 0.08°C­0.14°C/10yr for SSP1-2.6, 0.24­0.35°C/10yr for SSP2-4.5, 0.43­0.63°C/10yr for SSP3-7.0, and 0.52­0.76°C/10yr for SSP5-8.5 in the Qilian Mountain. These results indicate that the accuracy of the downscaled temperatures is improved compared to the original data. However, we also find that, compared with the downscaled data, the original projections have been overestimated.

Published

2022

16. An integrated index of cryospheric change in the Northern Hemisphere

Author

Xiaoqing Peng, Tingjun Zhang, Oliver W. Frauenfeld, Kang Wang, and Cuicui Mu

Subjects

Global and Planetary Change, Oceanography

Published

2022

17. A Holistic Assessment of 1979–2016 Global Cryospheric Extent

Author

Cuicui Mu, Haodong Jin, Ran Du, Tingjun Zhang, Oliver W. Frauenfeld, and Xiaoqing Peng

Subjects

Environmental sciences, Ecology, Earth and Planetary Sciences (miscellaneous), Environmental science, Cryosphere, GE1-350, climate, cryosphere, Environmental planning, QH540-549.5, General Environmental Science

Abstract

The cryosphere plays a major role in earth's climate system. Most cryospheric assessments focus on one or more of its components and their response to climate change. However, to date, there has not been a comprehensive evaluation of the entire global cryosphere. We therefore determine such a holistic estimate and quantify changes to the hemispheric and global cryosphere due to climate change, by synthesizing sea ice, snow cover, and frozen ground extents into one global cryospheric extent data set. The 1981–2010 climatology of daily global cryospheric extent ranges from 45.7 ± 0.7 × 106 to 87.2 ± 2.0 × 106 km2 (9.0%–17.1%), from 13.3 ± 0.8 × 106–66.3 ± 1.7 × 106 km2 (5.2%–26.0%) in the Northern Hemisphere (NH), and from 17.9 ± 0.3 × 106 to 33.6 ± 0.4 × 106 km2 (7.0%–13.2%) in the Southern Hemisphere (SH). The monthly maximum cryospheric extent of 85.84 ± 1.91 × 106 km2 occurs in December, whereas minimum occurs in July with 45.92 ± 0.70 × 106 km2. During 1979–2016, global cryospheric area extent lost approximately 87 ± 11 × 103 km2/yr, with a decrease of 102 ± 9.7 × 103 km2/yr in the NH that was partly offset by an increase of 14.6 ± 4.4 × 103 km2/yr in the SH. The first day of cryospheric cover was delayed by 3.6 days at a rate of 0.95 days/decade, and the last day advanced by 5.7 days, at a rate of 1.5 days/decade. The duration and number of cryospheric cover days decreased by 8.7 days and 7.6 days over the study period, respectively. These variations of global cryospheric extent are correlated with rising air temperatures. Our findings highlight the importance of assessing the cryosphere as a whole, and provide a way to quantitatively estimate its overall changes.

Published

2021

18. Soil freeze depth variability across Eurasia during 1850–2100

Author

Tingjun Zhang, Xiaoqing Peng, Oliver W. Frauenfeld, Ran Du, Benben Liang, and Qing Wei

Subjects

Atmospheric Science, Global and Planetary Change, geography, Plateau, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Energy balance, Climate change, Representative Concentration Pathways, 02 engineering and technology, Snow, 01 natural sciences, 020801 environmental engineering, Hydrology (agriculture), Climatology, Environmental science, Ecosystem diversity, Precipitation, 0105 earth and related environmental sciences

Abstract

Soil freeze depth (SFD) is an important indicator of cryospheric and climate change. Changes in SFD have important effects on hydrology, the energy balance, carbon exchange, and ecosystem diversity. However, quantifying and predicting SFD at large scales remains a challenge due to sparse long-term observations. This study employs the Stefan solution combined with 16 of the coupled model inter-comparison project phase 5 (CMIP5) models over the historical period (1850–2005) and three representative concentration pathways (RCP 2.6, 4.5, and 8.5) for 2006–2100, the Climatic Research Unit dataset (1901–2013), and hundreds of soil temperature, air temperature, precipitation, and snow depth sites to analyze the spatiotemporal variability of SFD in Eurasia under historical and projected climate change. During 1850–2005, a statistically significant SFD decrease of 0.49 ± 0.04 cm/decade is observed. Spatially, the biggest decreases are generally in Siberia and on the Tibetan Plateau. There is a projected decrease in 2006–2100 SFD of 4.58 ± 0.26, 1.85 ± 0.21, and 0.45 ± 0.18 cm/decade for RCP 8.5, 4.5, 2.6, respectively. These variations in SFD provide key insights into spatiotemporal changes in climate, and facilitate improved understanding of variation in frozen ground across Eurasia.

Published

2019

19. The Role of Permafrost in Eurasian Land‐Atmosphere Interactions

Author

Christopher J. Nowotarski, Oliver W. Frauenfeld, and Daniel J. Vecellio

Subjects

Atmosphere, Atmospheric Science, Thesaurus (information retrieval), Geophysics, Space and Planetary Science, Earth science, Earth and Planetary Sciences (miscellaneous), Environmental science, Permafrost

Published

2019

20. A Global Gridded Dataset of the Characteristics of the Rainy And Dry Seasons

Author

James L. Kinter, Rodrigo J. Bombardi, and Oliver W. Frauenfeld

Subjects

Atmospheric Science, Climatology, Environmental science, Precipitation, Demise

Abstract

The Rainy and Dry Seasons (RADS) dataset, a new compilation of precipitation statistics available to the public, is described. The dataset contains the dates of onset and demise of the rainy season (one date per year), the duration of the rainy and dry seasons, and the accumulated precipitation during the rainy and dry seasons. The methodology for detecting the characteristics of the rainy season is based solely on precipitation data. RADS was developed from multiple global gridded daily precipitation datasets [Tropical Rainfall Measuring Mission (TRMM), 1998–2015; Climate Prediction Center Unified Gauge-Based Analysis of Global Daily Precipitation (CPC_UNI), 1979–present; and Modern-Era Retrospective Analysis for Research and Applications, version 2 (MERRA-2), 1980–present] and therefore shares the spatial resolution, temporal range, and limitations of the original precipitation datasets. This is the first free public dataset of the characteristics of the rainy and dry seasons created using a consistent methodology across the globe, including all major monsoonal regions. We expect that the RADS dataset will contribute to our understanding of the sources of variability of the timing of rainy seasons (on local to regional scales) and monsoons (on large scales) and their impacts on water resource management and other aspects of geosciences and human activities.

Published

2019

21. Evaluation and quantification of surface air temperature over Eurasia based on CMIP5 models

Author

Tingjun Zhang, Oliver W. Frauenfeld, Kang Wang, Jing Luo, Wen Sun, and Xiaoqing Peng

Subjects

Atmospheric Science, Surface air temperature, Environmental Chemistry, Environmental science, Atmospheric sciences, Permafrost, General Environmental Science

Published

2019

22. Assessment of Temperature Changes on the Tibetan Plateau During 1980–2018

Author

Lina Qiao, Xiaoqing Peng, Yaohua Zhao, Cuicui Mu, Oliver W. Frauenfeld, Haodong Jin, Tingjun Zhang, and Ran Du

Subjects

QE1-996.5, geography, Plateau, geography.geographical_feature_category, Astronomy, General Earth and Planetary Sciences, Environmental science, QB1-991, Geology, Physical geography, Environmental Science (miscellaneous)

Abstract

Surface air temperatures affect a diverse set of physical and biological systems in many parts of the world. For regional‐scale studies, gridded surface air temperature data sets are frequently used as input variables. Here we evaluate 10 commonly used gridded air temperature products with spatial resolutions ranging from 0.1° × 0.1° to 5.0° × 5.0°, relative to observations from in situ weather stations on the Tibetan Plateau. Gridded temperatures are consistently lower, with mean annual air temperature biases ranging from −4.68 °C to −1.72 °C, and root mean square error (RMSE) from 3.24 °C to 6.11 °C. The mean biases of mean seasonal air temperatures for spring, summer, autumn, and winter are −3.21 °C, −2.98 °C, −2.89 °C, and −2.98 °C, respectively, and RMSEs of 4.81 °C, 4.39 °C, 4.3 °C, and 4.7 °C. Of all 10 products, the China meteorological forcing data set compares best with observations. Annual and season temperatures all increase significantly during 1980–2018 on the Tibetan Plateau, with winter dominating the warming rate.

Published

2021

23. Arctic precipitation recycling and hydrologic budget changes in response to sea ice loss

Author

Victoria L. Ford and Oliver W. Frauenfeld

Subjects

Global and Planetary Change, Oceanography

Published

2022

24. The role of peat on permafrost thaw based on field observations

Author

Ran Du, Xiaoqing Peng, Wen Sun, Cong Chen, Oliver W. Frauenfeld, Haodong Jin, Benben Liang, and Yaohua Zhao

Subjects

Peat, Soil water, Environmental science, Soil science, Permafrost carbon cycle, Snow, Permafrost, Water content, Earth-Surface Processes, Spatial heterogeneity, Active layer

Abstract

Rising temperatures result in permafrost degradation in cold regions, but with considerable spatial heterogeneity due to local factors including peat. Peat plays an important role in the permafrost carbon cycle by impacting the soil thermal and hydrologic characteristics. Here we use field observations to describe the role of peat on permafrost thaw based on comparisons at two sites: EBoTA characterized by primarily peat, and PT5 with more mineral soils. Compared to PT5, soil temperature at the EBoTA site was lower in the warm season, but higher in the cold season. Freezing onset was generally 0–19 days later at the PT5 site compared to EBoTA throughout the soil column, except at the 0.1 m depth where it occurred 11 days earlier. The average thawing onset at PT5 was 18–96 days earlier. There were 20–119 more freezing days and 19–118 fewer thawing days at EBoTA than at PT5, and the zero annual amplitude and active layer thickness were lower at EBoTA. Finally, the mean annual ground temperature was greater at PT5, and was even above 0 °C in three recent years. These results illustrate peat’s thermal insulation effect on permafrost due to its low thermal conductivity and high moisture content. Snow depth increases also amplify the insulation effect. These field observations therefore not only verify, but also quantify the protective role of peatlands on permafrost.

Published

2022

25. Response of peat-rich permafrost to a warming climate on the northeast Tibetan Plateau

Author

Ran Du, Oliver W. Frauenfeld, Haodong Jin, Yaohua Zhao, Cong Chen, Xiaoqing Peng, Kang Wang, Benben Liang, Sijia Peng, and Wen Sun

Subjects

Total organic carbon, Atmospheric Science, Global and Planetary Change, geography, Peat, Plateau, geography.geographical_feature_category, Climate change, Forestry, Permafrost, Active layer, Atmosphere, Environmental science, Physical geography, Agronomy and Crop Science, Water content

Abstract

Permafrost degradation leads to the release of organic carbon to the atmosphere, and in turn, affects climate change. The amount of organic carbon released to the atmosphere depends on the thawing rate of peat-rich permafrost. However, the exact mechanism of peat-rich permafrost thawing is still unclear. Here we choose two locations on the northeast Tibetan Plateau: the peat-rich EBoTA (“peatland”) site, and the mineral-rich PT5 (“mineral”) site. We use the Geophysical Institute Permafrost Laboratory model to reveal the response of permafrost to warming climate from 1850 to 2100 applying different shared socioeconomic pathways (SSPs). Monthly soil temperature increased during the historical and future periods at both sites, but a slower trend is evident at the peatland site relative to the mineral site. Seasonally, the warming trend is faster in winter than that in summer at both sites. Active layer deepening at the mineral site is 3–12 times that of the peatland site. In addition, permafrost will persist until 2100 in all but one of the SSPs at the peatland site. At the mineral site, all permafrost will degrade to seasonally frozen ground, with only taliks remaining for all future scenarios. These changes indicated a slower response of peat-rich permafrost to climate change, due to peat's low thermal conductivity and high soil moisture. These results could be useful in permafrost carbon studies.

Published

2021

26. Spatiotemporal Changes in Active Layer Thickness under Contemporary and Projected Climate in the Northern Hemisphere

Author

Dongliang Luo, Hang Su, Tingjun Zhang, Huijun Jin, Bin Cao, Oliver W. Frauenfeld, Qingbai Wu, Xiaoqing Peng, and Kang Wang

Subjects

Atmospheric Science, Coupled model intercomparison project, 010504 meteorology & atmospheric sciences, Northern Hemisphere, Climate change, Cru, Representative Concentration Pathways, Edaphic, 010502 geochemistry & geophysics, Permafrost, 01 natural sciences, Climatology, Environmental science, Climate model, 0105 earth and related environmental sciences

Abstract

Variability of active layer thickness (ALT) in permafrost regions is critical for assessments of climate change, water resources, and engineering applications. Detailed knowledge of ALT variations is also important for studies on ecosystem, hydrological, and geomorphological processes in cold regions. The primary objective of this study is therefore to provide a comprehensive 1971–2000 climatology of ALT and its changes across the entire Northern Hemisphere from 1850 through 2100. To accomplish this, in situ observations, the Stefan solution based on a thawing index, and the edaphic factor (E factor) are employed to calculate ALT. The thawing index is derived from (i) the multimodel ensemble mean of 16 models from phase 5 of the Coupled Model Intercomparison Project (CMIP5) over 1850–2005, (ii) three representative concentration pathways (RCP2.6, RCP4.5, and RCP8.5) for 2006–2100, and (iii) Climatic Research Unit (CRU) gridded observations for 1901–2014. The results show significant spatial variability in in situ ALT that generally ranges from 40 to 320 cm, with some extreme values of 900 cm in the Alps. The differences in the ALT climatology between the three RCPs and the historical experiments ranged from 0 to 200 cm. The biggest increases, of 120–200 cm, are on the Qinghai–Tibetan Plateau, while the smallest increases of less than 20 cm are in Alaska. Averaged over all permafrost regions, mean ALT from CMIP5 increased significantly at 0.57 ± 0.04 cm decade−1 during 1850–2005, while 2006–2100 projections show ALT increases of 0.77 ± 0.08 cm decade−1 for RCP2.6, 2.56 ± 0.07 cm decade−1 for RCP4.5, and 6.51 ± 0.07 cm decade−1 for RCP8.5.

Published

2017

27. Northern Hemisphere Greening in Association With Warming Permafrost

Author

Tingjun Zhang, Lina Qiao, Shijin Wang, Xiaoqing Peng, Ran Du, Cuicui Mu, and Oliver W. Frauenfeld

Subjects

Atmospheric Science, Ecology, Northern Hemisphere, Paleontology, Soil Science, Climate change, Forestry, Aquatic Science, Permafrost, Normalized Difference Vegetation Index, Active layer, Greening, medicine, Environmental science, Physical geography, Precipitation, medicine.symptom, Vegetation (pathology), Water Science and Technology

Abstract

Vegetation is closely tied to climate change, hydrological processes, the carbon cycle, and the energy balance. However, in cold regions, both climate and vegetation changes are also closely coupled to permafrost. The association between amplified warming and greening in Northern Hemisphere permafrost regions is not clearly understood. We therefore produce an extended 1982-2015 normalized difference vegetation index record based on concatenated Global Inventory Modeling and Mapping Studies and Moderate-Resolution Imaging Spectroradiometer data to quantify the spatiotemporal patterns of vegetation variability. We also establish spatiotemporal permafrost warming patterns based on a thawing index, active layer thickness, soil temperature, the first thaw date, and thawing days. Next, we establish the association between vegetation and warming permafrost. We find that normalized difference vegetation index increases in approximately 70% of Northern Hemisphere permafrost regions during the growing season (April-October) and in 72% of the region during autumn. Warming permafrost shows a positive relationship with greening. A higher thawing index, greater active layer thickness, higher soil temperature, and also increased precipitation are linked with the observed greening. An earlier first thaw date and an increased number of thawing days also correlate with vegetation greening. These findings underscore the sensitivity of vegetation to warming permafrost. Continued permafrost warming will result in further greening of Northern Hemisphere cold regions (and vice versa), with important implications for the permafrost soil-vegetation-atmosphere carbon cycles, and the water, nutrient, and energy budgets.

Published

2020

28. The Permafrost Young Researchers Network (PYRN) is getting older:The past, present, and future of our evolving community

Author

George Tanski, Elin Högström, Hugues Lantuit, Florence Magnin, Alexandre Nieuwendam, Jens Strauss, Anne Morgenstern, Julia Stanilovskaya, Simon Dumais, Justine Ramage, J.K. Heslop, Jannik Martens, Caroline Coch, Alevtina Evgrafova, Boris Radosavljevic, Ingo Hartmeyer, Alexey A Maslakov, Silvie Harder, Erin Trochim, Elena Kuznetsova, Gleb Kraev, Philip P. Bonnaventure, A. V. Lupachev, Helena Bergstedt, Jennifer M. Frederick, Josefine Lenz, Denis Frolov, Oliver W. Frauenfeld, Samuel Weber, Andrea Schneider, Michael Fritz, Daniel J. Vecellio, Alexandre R. Bevington, Margareta Johansson, Frédéric Bouchard, Marc Oliva, Vrije Universiteit Amsterdam [Amsterdam] (VU), University of Salzburg, Government of British Columbia, University of Lethbridge, Géosciences Paris Saclay (GEOPS), Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), University of Potsdam, Laval University [Québec], University of Bern, Texas A&M University [College Station], Division of Hydrologic Sciences, Desert Research Institute (DRI), Alfred Wegener Institute [Potsdam], Alfred-Wegener-Institut, Helmholtz-Zentrum für Polar- und Meeresforschung (AWI), Lomonosov Moscow State University (MSU), McGill University Health Center [Montreal] (MUHC), Environnements, Dynamiques et Territoires de la Montagne (EDYTEM), Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS), Institut des Géosciences de l’Environnement (IGE), Institut de Recherche pour le Développement (IRD)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA), Earth and Climate, Université Laval [Québec] (ULaval), and Centre National de la Recherche Scientifique (CNRS)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])

Subjects

Outreach, 010504 meteorology & atmospheric sciences, [SDE.MCG]Environmental Sciences/Global Changes, Geography, Planning and Development, 0507 social and economic geography, Survey result, Permafrost, 01 natural sciences, IPY, Education, [SHS.HISPHILSO]Humanities and Social Sciences/History, Philosophy and Sociology of Sciences, SDG 17 - Partnerships for the Goals, Political science, Research community, VDP::Matematikk og Naturvitenskap: 400::Geofag: 450, Science communication, Social media, [SDU.STU.GL]Sciences of the Universe [physics]/Earth Sciences/Glaciology, Biological sciences, 0105 earth and related environmental sciences, VDP::Mathematics and natural science: 400::Geosciences: 450, Ecology, business.industry, International Polar Year, 05 social sciences, Permafrost Young Reseachers Netwrok, Public relations, [SDE.ES]Environmental Sciences/Environmental and Society, Early-career scientists, Thriving, [SDE]Environmental Sciences, General Earth and Planetary Sciences, PYRN, business, Permafrost Young Researchers Network, 050703 geography

Abstract

Source at https://doi.org/10.1017/S0032247418000645. A lasting legacy of the International Polar Year (IPY) 2007–2008 was the promotion of the Permafrost Young Researchers Network (PYRN), initially an IPY outreach and education activity by the International Permafrost Association (IPA). With the momentum of IPY, PYRN developed into a thriving network that still connects young permafrost scientists, engineers, and researchers from other disciplines. This research note summarises (1) PYRN’s development since 2005 and the IPY’s role, (2) the first 2015 PYRN census and survey results, and (3) PYRN’s future plans to improve international and interdisciplinary exchange between young researchers. The review concludes that PYRN is an established network within the polar research community that has continually developed since 2005. PYRN’s successful activities were largely fostered by IPY. With >200 of the 1200 registered members active and engaged, PYRN is capitalising on the availability of social media tools and rising to meet environmental challenges while maintaining its role as a successful network honouring the legacy of IPY.

Published

2019

29. Response of changes in seasonal soil freeze/thaw state to climate change from 1950 to 2010 across china

Author

Hang Su, Xiaoqing Peng, Oliver W. Frauenfeld, Dongxia Yue, Bin Cao, Huijuan Wang, Zhe Huang, Kang Wang, and Tingjun Zhang

Subjects

Hydrology, geography, Plateau, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Moisture, Climate change, Land cover, 010502 geochemistry & geophysics, Atmospheric sciences, Permafrost, 01 natural sciences, Active layer, Geophysics, Ground temperature, Environmental science, Common spatial pattern, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Variations in seasonal soil freeze/thaw state are important indicators of climate change and influence ground temperature, hydrological processes, surface energy, and the moisture balance. Previous studies mainly focused on the active layer and permafrost, while seasonally frozen ground research in nonpermafrost regions has received less attention. In this study, we investigate the response of changes in seasonal soil freeze/thaw state to changes in air temperatures by combining observations from more than 800 stations with gridded mean monthly air temperature data across China. The results show that mean annual air temperature (MAAT) increased statistically significantly by 0.29 ± 0.03°C/decade from 1967 to 2013, with greater warming on the Qinghai-Tibetan Plateau. There is a statistically significant decrease in the freeze/thaw cycle (FTC) at 0.39 ± 0.05 cycles/decade. In addition, there are strong negative correlations between FTC and MAAT. Estimating the soil freeze/thaw state classification based on the number of days in the month, we find that changes of mean annual area extent of seasonal soil freeze/thaw state decreased significantly for completely frozen (CF) ground, while the area extent of partially frozen (PF) and unfrozen (UF) ground both increased. Changes in mean monthly area extent of seasonal soil freeze/thaw state indicate that the extent of CF and UF area was decreasing and increasing, respectively. But for the extent of PF areas, both increasing and decreasing trends were observed. Quantifying the spatial pattern of the seasonal soil freeze/thaw, we find that CF and PF areas are located in northern China and the Tibetan Plateau from December to March, and UF areas are located in southern China. The variations of mean annual area extent departure of soil freeze/thaw states are consistent with MAAT changes in different land cover types across China.

Published

2016

30. Multi‐decadal variability of soil moisture–temperature coupling over the contiguous United States modulated by Pacific and Atlantic sea surface temperatures

Author

Oliver W. Frauenfeld, Trent W. Ford, and Steven M. Quiring

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Moisture, 0208 environmental biotechnology, Ocean current, 02 engineering and technology, 01 natural sciences, 020801 environmental engineering, Atlantic Equatorial mode, North Atlantic oscillation, Climatology, Soil water, Atlantic multidecadal oscillation, Water content, Pacific decadal oscillation, Geology, 0105 earth and related environmental sciences

Abstract

Regions of strong land–atmosphere coupling are often depicted as static in time. However, the mechanisms through which the land surface impacts atmospheric conditions vary on sub-daily to multi-decadal timescales. Therefore, characterizing the long-term variability of land–atmosphere interactions may provide a means of predicting when surface-induced extreme temperature events will be more or less likely to occur. We evaluate the coupling strength between soil moisture, as represented by in situ observations and 1-month Standardized Precipitation Index (SPI), and subsequent monthly maximum temperature (TMAX) over the contiguous United States. We find that the utility of SPI as a proxy for soil moisture anomalies is limited to the summer, as the correlations between SPI and TMAX are not significantly related in the other seasons. We examine the variability in summer SPI–TMAX coupling in four regions of the United States. In general, we find the strongest relationships between SPI and TMAX in the Southern Great Plains. However, our results demonstrate that the coupling strength varies considerably over time in most regions of the United States. The long-term variability in SPI–TMAX coupling strength is strongly related to the Pacific Decadal Oscillation in the northwest and midwest United States, and the Atlantic Multidecadal Oscillation in the southeast United States The results of this study suggest that land–atmosphere coupling in the contiguous United States is modulated by multi-decadal oscillations in Pacific and Atlantic sea surface temperatures.

Published

2016

31. Impacts of urbanization on future climate in China

Author

Oliver W. Frauenfeld and Liang Chen

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Climate change, Representative Concentration Pathways, 010501 environmental sciences, Urban area, 01 natural sciences, Weather Research and Forecasting Model, Greenhouse gas, Urban climate, Climatology, Urbanization, Environmental science, Precipitation, 0105 earth and related environmental sciences

Abstract

Urbanization plays an important role in human-induced climate change at the regional scale through altered land-atmosphere interactions over urban areas. In this study, the impacts of future urbanization in China on climate are investigated. The Weather Research and Forecasting model is used to downscale future projections using Representative Concentration Pathways (RCP) 4.5 simulations from the Community Earth System Model. Results for 2050 show decreased latent and increased sensible heat fluxes over the urban area, therefore leading to higher surface temperatures and less humidity. Future climate projections reveal that urbanization produces strong warming effects, up to 1.9 °C at regional and local/urban scales, which is comparable to the magnitude of greenhouse gas forcing under the RCP 4.5 scenario. Greater urban warming effects are projected during night and summer, which can be attributed to the high heat capacity of built-up areas. The impacts of urbanization on precipitation show varying effects primarily in summer—both increases and decreases depending on spatial scale—related to both local moisture deficits and large-scale circulation changes. Urbanization could strengthen the East Asian summer monsoon in southern China in summer, and slightly weaken it in eastern China in winter. Due to these significant impacts, we suggest that urbanization should be included in model projections to provide a more realistic and complete depiction of future climate.

Published

2015

32. Vegetation response to precipitation across the aridity gradient of the southwestern United states

Author

Vijay P. Singh, Dagbegnon Clement Sohoulande Djebou, and Oliver W. Frauenfeld

Subjects

geography, geography.geographical_feature_category, Ecology, Arid, Normalized Difference Vegetation Index, Shrubland, Water balance, Climatology, Vegetation type, medicine, Environmental science, Aridity index, Precipitation, medicine.symptom, Vegetation (pathology), Ecology, Evolution, Behavior and Systematics, Earth-Surface Processes

Abstract

Atmospheric water demand affects a variety of factors, including primary production and the terrestrial water balance. Precipitation gradients from arid to humid regions also impact the water balance and play a large role in vegetation dynamics. Focusing on a 23-year period (1989–2011), we examine precipitation during the growing season in conjunction with the Normalized Difference Vegetation Index (NDVI) series for 21 satellite scenes spanning across the southwestern United States. We classify the satellite scenes into three different groups, based on the United Nations Aridity Index (AI). Group 1 is categorized as relatively humid with AI ≥ 0.65, group 2 is intermediate with 0.50 ≤ AI 3 mm and >13 mm) changed during this time. We also use cross-correlation analyses to establish the lagged behavior of the three types of vegetation in relation to precipitation amount and number of events. The vegetation response is similar between precipitation amount and number of precipitation events. However, in the arid region, we find distinct responses to precipitation depending on the vegetation type. The magnitude and significance of the vegetation response to precipitation patterns increase with environmental aridity. There is thus a meaningful disparity of vegetation behavior in time and space.

Published

2015

33. Climatology of Storm Characteristics in Costa Rica using the TRMM Precipitation Radar

Author

Steven M. Quiring, Alexander G. Peterson, Anita D. Rapp, Oliver W. Frauenfeld, and E. Brendan Roark

Subjects

Convection, Atmospheric Science, Intertropical Convergence Zone, Storm, Atmospheric sciences, law.invention, Diurnal cycle, law, Climatology, Precipitation types, Environmental science, Precipitation, Radar, geographic locations, Convective precipitation

Abstract

Tropical Rainfall Measuring Mission Precipitation Radar precipitation features are analyzed to understand the role of storm characteristics on the seasonal and diurnal cycles of precipitation in four distinct regions in Costa Rica. The distribution of annual rainfall is highly dependent on the stratiform precipitation, driven largely by seasonal increases in stratiform area. The monthly distribution of stratiform rain is bimodal in most regions, but the timing varies regionally and is related to several important large-scale features: the Caribbean low-level jet, the ITCZ, and the Chorro del Occidente Colombiano (CHOCO) jet. The relative importance of convective precipitation increases on the Caribbean side during wintertime cold air surges. Except for the coastal Caribbean domain, most regions show a strong diurnal cycle with an afternoon peak in convection followed by an evening increase in stratiform rain. Along the Caribbean coast, the diurnal cycle is weaker, with evidence of convection associated with the sea breeze, as well as a nocturnal increase in storms. The behavior of extreme precipitation features with rain volume in the 99th percentile is also analyzed. They are most frequent from May to November, with notable differences between features at the beginning/end of the rainy season versus those in the middle, as well as between wet and dry seasons. Convective rain exceeds stratiform in winter and midsummer extreme features, while stratiform rain is larger at the beginning and end of the wet season. Given projected changes in precipitation and extreme events in Costa Rica for future climate change scenarios, the results indicate the importance of understanding both changes in total precipitation and in the storm characteristics.

Published

2014

34. Weather type classification of wildfire ignitions in the central Gulf Coast, United States

Author

Oliver W. Frauenfeld, Christopher F. Labosier, Charles W. Lafon, and Steven M. Quiring

Subjects

Atmospheric Science, Geography, North Atlantic oscillation, Range (biology), Climatology, Westerlies, Occurrence data, Classification scheme, National forest, Synoptic climatology, Teleconnection

Abstract

Limited research has been performed examining the relationships between southeast US wildfire and weather type patterns using modern techniques and data sets. The purpose of this article is to examine the relationship between wildfire ignitions in the central Gulf Coast, United States and weather type occurrences in an effort to identify regional patterns associated with wildfire ignitions. Wildfire occurrence data are obtained for nine national forests in the central Gulf Coast for the period 1970 to 2011. The Spatial Synoptic Classification scheme (SSC) is used to classify daily weather type variations for each national forest. Years with high numbers of ignitions experience statistically higher numbers of dry tropical (DT) weather types than years with low numbers of ignitions in five of nine national forests. These differences range from 17 to 160% more DT days during periods of high ignitions. Statistically significant positive Spearman rank correlations exist between annual number of ignitions and annual number of DT days in a given forest. While understanding such relationships on an annual scale is useful, it says nothing about the actual timing of weather types leading up to an ignition. An analysis of weather type activity 30, 90, and 180 days prior to ignitions reveals that the median ratio of DT days to moist moderate (MM) and moist tropical (MT) days is statistically higher for periods leading up to a fire. Positive phases of the North Atlantic Oscillation (NAO) result in an increased number of DT days. This confirms previous studies that have suggested the strength of the westerlies increases during the positive phase of the NAO, driving DT weather types eastward from their southwest US/Mexico source region. We can therefore also conclude that the positive phase of the NAO is linked with increased wildfire activity in the central Gulf Coast, United States.

Published

2014

35. Impacts of Vegetation and Precipitation on Throughfall Heterogeneity in a Tropical Pre-Montane Transitional Cloud Forest

Author

H. R. Mahan, N. G. Teale, Anita D. Rapp, Sarah Bleakney, E. Brendan Roark, Robert A. Washington-Allen, Steven M. Quiring, Amélie Berger, Oliver W. Frauenfeld, and N. C. Shibley

Subjects

Cloud forest, Environmental science, Montane ecology, Forestry, Precipitation, Vegetation, Leaf area index, Throughfall, Ecology, Evolution, Behavior and Systematics

Abstract

Precipitation throughfall (TF) plays an important role in the water balance of tropical forests. This study used 164 gauges to quantify precipitation and TF variability in a tropical pre-montane transitional cloud forest on the Caribbean slope of the Cordillera Tilaran, Costa Rica, to identify the ecological and meteorological drivers of this variability. Daily TF measurements were taken from 28 June to 17 July 2012 and 12 June to 16 July 2013, for a total of 39 precipitation events. The total mean TF was 87.9 percent and TF at individual gauges ranged from 22.7 percent to 245.7 percent. Leaf area index (LAI) was calculated above each gauge using hemispheric photography for a mean study-site LAI of 7.7. There was no statistically significant relationship between LAI and TF. However, the amount of TF was positively correlated with precipitation intensity, while the variability of TF was negatively correlated with precipitation intensity. Our calculations indicate that at least 61 gauges are required to obtain mean TF estimates with less than 5 percent error. This study demonstrates that TF is highly spatially heterogeneous due to multiple compounding effects. RESUMEN Precipitacion interna a traves del dosel del bosque (TF) es una parte importante del equilibrio de agua en bosques tropicales. Este estudio tuvo como objetivo cuantificar la variabilidad de precipitacion y TF en un bosque nuboso transicional y premontano en el lado Caribe de la Cordillera Tilaran, especificamente en el Centro Soltis, Costa Rica, e identificar los factores ecologicos y meteorologicos en esta variabilidad. Mediante 164 pluviometros, se obtuvieron lecturas diarias de precipitacion interna, desde 28 Junio –17 Julio 2012 y 12 Junio–16 Julio 2013, abarcando 39 eventos pluviales. El promedio total de la precipitacion interna fue 87.9% y la precipitacion interna de los pluviometros fluctuaron entre 22.7% y 245.7%. Mediante fotografia hemisferica se calcularon los indices de area foliar (LAI) sobre cada pluviometro. El promedio del LAI fue 7.7. No hubo una relacion estadisticamente significativa entre LAI y TF; sin embargo, hubo una correlacion positiva entre la precipitacion interna y la intensidad de la precipitacion, y la variabilidad de la precipitacion interna correlaciono negativamente con la intensidad de la precipitacion. Nuestros resultados indican que al menos 61 pluviometros son necesarios para determinar los promedios de precipitacion interna con menos de 5% de error. Este estudio demuestra que la precipitacion interna es espacialmente heterogenea debido a muchos efectos amontonados.

Published

2014

36. Surface Air Temperature Changes over the Twentieth and Twenty-First Centuries in China Simulated by 20 CMIP5 Models

Author

Oliver W. Frauenfeld and Liang Chen

Subjects

Atmospheric Science, Coupled model intercomparison project, geography, Surface air temperature, Plateau, geography.geographical_feature_category, Climatology, Environmental science, Climate change, Magnitude (mathematics), Terrain, China, Climatic warming

Abstract

Historical temperature variability over China during the twentieth century and projected changes under three emission scenarios for the twenty-first century are evaluated on the basis of a multimodel ensemble of 20 GCMs from phase 5 of the Coupled Model Intercomparison Project (CMIP5) and two observational datasets. Changes relative to phase 3 of the Coupled Model Intercomparison Project (CMIP3) are assessed, and the performance of individual GCMs is also quantified. Compared with observations, GCMs have substantial cold biases over the Tibetan Plateau, especially in the cold season. The timing and location of these biases also correspond to the greatest disagreement among the individual models, indicating GCMs’ limitations in reproducing climatic features in this complex terrain. The CMIP5 multimodel ensemble shows better agreement with observations than CMIP3 in terms of the temperature biases. Both CMIP3 and CMIP5 capture the climatic warming over the twentieth century. However, the magnitude of the annual mean temperature trends is underestimated. There is also limited agreement in the spatial and seasonal patterns of temperature trends over China. Based on six statistical measures, four individual models—the Max Planck Institute Earth System Model, low resolution (MPI-ESM-LR), Second Generation Canadian Earth System Model (CanESM2), Model for Interdisciplinary Research on Climate, Earth System Model (MIROC-ESM), and Community Climate System Model, version 4 (CCSM4)—best represent surface air temperature variability over China. The future temperature projections indicate that the representative concentration pathway (RCP) 8.5 and RCP 4.5 scenarios exhibit a gradual increase in annual temperature during the twenty-first century at a rate of 0.60° and 0.27°C (10 yr)−1, respectively. As the lowest-emission mitigation scenario, RCP 2.6 projects the lowest rate of temperature increase [0.10°C (10 yr)−1]. By the end of the twenty-first century, temperature is projected to increase by 1.7°–5.7°C, with larger warming over northern China and the Tibetan Plateau.

Published

2014

37. A comprehensive evaluation of precipitation simulations over China based on CMIP5 multimodel ensemble projections

Author

Liang Chen and Oliver W. Frauenfeld

Subjects

Atmospheric Science, geography, Coupled model intercomparison project, Plateau, geography.geographical_feature_category, Magnitude (mathematics), Representative Concentration Pathways, Monsoon, Geophysics, Space and Planetary Science, Climatology, Earth and Planetary Sciences (miscellaneous), Common spatial pattern, Environmental science, Precipitation, China

Abstract

Precipitation variability has great economic, social, and environmental impacts across the globe, and in particular in China. This paper evaluates the historical precipitation variability based on 20 general circulation models from the Coupled Model Intercomparison Project Phase 5 (CMIP5) archive over the 20th century relative to two observational data sets and quantifies CMIP5 improvements over CMIP3. Multimodel ensemble means and individual models are assessed. Three future emission scenarios are used (representative concentration pathways (RCP) 8.5, RCP 4.5, and RCP 2.6), and 21st century CMIP5 estimates are put into context based on the 20th century biases. We find that CMIP5 models can reproduce the spatial pattern of precipitation over China during the 20th century, which represents an improvement over CMIP3. However, the models overestimate the magnitude of seasonal and annual precipitation in most regions of China, especially along the eastern edge of the Tibetan Plateau, and underestimate summer precipitation over southeastern China. For China as a whole, CMIP5's overestimation of annual precipitation is greater than CMIP3, which can be traced back to a greater underestimation of summer precipitation in CMIP3. There is a large spread among individual models, with the greatest uncertainties in simulating summer precipitation. Trends and correlations also suggest a better agreement of CMIP5 with observations than CMIP3. Throughout the 20th century, both the observations and models show an increasing trend in precipitation over parts of northwestern China and a decreasing trend over the Tibetan Plateau. There is poor agreement in precipitation trends over the southeast and northeast regions. In general, multimodel means cannot capture the amplitude of observed multidecadal precipitation variability. In the 21st century, precipitation is generally projected to increase across all of China under all three scenarios. RCP 8.5 exhibits the largest significant trend at a rate of +1.5 mm/yr, corresponding to 16% precipitation increase by the end of the century. The RCP 2.6 scenario shows the smallest increases, at +0.5 mm/yr (6%) by 2100. The greatest increases are projected to occur over the Tibetan Plateau and eastern China in summer, suggesting an altered monsoonal circulation in the future. However, due to the uncertainties in CMIP5, future precipitation projections should be interpreted with caution.

Published

2014

38. Analysis of watershed topography effects on summer precipitation variability in the southwestern United States

Author

Dagbegnon Clement Sohoulande Djebou, Vijay P. Singh, and Oliver W. Frauenfeld

Subjects

Watershed, North American Monsoon, Climatology, Elevation data, Common spatial pattern, Environmental science, Climate change, Climate model, Arid, Water Science and Technology

Abstract

With climate change, precipitation variability is projected to increase. The present study investigates the potential interactions between watershed characteristics and precipitation variability. The watershed is considered as a functional unit that may impact seasonal precipitation. The study uses historical precipitation data from 370 meteorological stations over the last five decades, and digital elevation data from regional watersheds in the southwestern United States. This domain is part of the North American Monsoon region, and the summer period (June–July–August, JJA) was considered. Based on an initial analysis for 1895–2011, the JJA precipitation accounts, on average, for 22–43% of the total annual precipitation, with higher percentages in the arid part of the region. The unique contribution of this research is that entropy theory is used to address precipitation variability in time and space. An entropy-based disorder index was computed for each station’s precipitation record. The JJA total precipitation and number of precipitation events were considered in the analysis. The precipitation variability potentially induced by watershed topography was investigated using spatial regionalization combining principal component and cluster analysis. It was found that the disorder in precipitation total and number of events tended to be higher in arid regions. The spatial pattern showed that the entropy-based variability in precipitation amount and number of events gradually increased from east to west in the southwestern United States. Regarding the watershed topography influence on summer precipitation patterns, hilly relief has a stabilizing effect on seasonal precipitation variability in time and space. The results show the necessity to include watershed topography in global and regional climate model parameterizations.

Published

2014

39. Seasonal tropical cyclone precipitation in Texas: A statistical modeling approach based on a 60 year climatology

Author

Laiyin Zhu, Steven M. Quiring, and Oliver W. Frauenfeld

Subjects

Atmospheric Science, Atlantic hurricane, Storm, Tropical Atlantic, Atmospheric sciences, Wind speed, Sea surface temperature, Geophysics, Space and Planetary Science, North Atlantic oscillation, Climatology, Earth and Planetary Sciences (miscellaneous), Environmental science, Precipitation, Tropical cyclone

Abstract

[1] Sixty years of tropical cyclone precipitation (TCP) in Texas has been analyzed because of its importance in extreme hydrologic events and the hydrologic budget. We developed multiple linear regression models to provide seasonal forecasts for annual TCP, TCP's contribution (percentage) to total precipitation, and the number of TCP days in Texas. The regression models are based on three or fewer predictors with model fits ranging from 0.18 to 0.43 (R2) and cross-validation accuracy of 0.05–0.36 (R2). La Nina exhibits the most important control on TCP in Texas. It is the major driver in our models and acts to reduce the vertical shear in the Caribbean and the tropical Atlantic, thereby generating more precipitating storms in Texas. Lower maximum potential velocity, the theoretical maximum wind speed that storms can attain, in the Gulf of Mexico, and low-level vorticity in the Atlantic hurricane main development region increased the modeled R2 by 20% or more. Both variables have negative coefficients in the TCP models. Lower maximum potential velocity and vorticity are associated with tropical cyclones with lower maximum wind speed and slower translation speed. Such weak TCs produce the majority of TCP and extreme TCP events in Texas. The quartiles of the TCs with strongest maximum wind speed and fastest translation speed are not associated with the largest mean daily precipitation based on observations in Texas. We have also shown that sea level pressure in the Gulf of Mexico, sea surface temperature in the Caribbean, and the North Atlantic Oscillation are potentially important predictors of seasonal TCP in Texas.

Published

2013

40. Land cover changes and their biogeophysical effects on climate

Author

Samuel Gameda, Clive McAlpine, Andrew M. Carleton, Adriana Beltrán-Przekurat, Jinyang Du, Roger A. Pielke, Paul A. Dirmeyer, Rezaul Mahmood, U. S. Nair, Robert Hale, Richard T. McNider, Dev Niyogi, Bruce Baker, Oliver W. Frauenfeld, Marshall Shepherd, Kenneth G. Hubbard, David R. Legates, Peter D. Blanken, and Souleymane Fall

Subjects

Atmospheric Science, Desertification, Deforestation, Cloud cover, Climatology, Urbanization, media_common.quotation_subject, Environmental science, Afforestation, Land cover, Atmospheric temperature, Teleconnection, media_common

Abstract

Land cover changes (LCCs) play an important role in the climate system. Research over recent decades highlights the impacts of these changes on atmospheric temperature, humidity, cloud cover, circulation, and precipitation. These impacts range from the local- and regional-scale to sub-continental and global-scale. It has been found that the impacts of regional-scale LCC in one area may also be manifested in other parts of the world as a climatic teleconnection. In light of these findings, this article provides an overview and synthesis of some of the most notable types of LCC and their impacts on climate. These LCC types include agriculture, deforestation and afforestation, desertification, and urbanization. In addition, this article provides a discussion on challenges to, and future research directions in, assessing the climatic impacts of LCC.

Published

2013

41. Response of seasonal soil freeze depth to climate change across China

Author

Hang Su, Tingjun Zhang, Xiaoqing Peng, Xinyue Zhong, Kang Wang, Cuicui Mu, Bin Cao, and Oliver W. Frauenfeld

Subjects

Hydrology, 010504 meteorology & atmospheric sciences, Climate change, Vegetation, 010502 geochemistry & geophysics, Snow, 01 natural sciences, complex mixtures, Normalized Difference Vegetation Index, Carbon cycle, Water balance, Frost line, Environmental science, Ecosystem, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology

Abstract

The response of seasonal soil freeze depth to climate change has repercussions for the surface energy and water balance, ecosystems, the carbon cycle, and soil nutrient exchange. Despite its importance, the response of soil freeze depth to climate change is largely unknown. This study employs the Stefan solution and observations from 845 meteorological stations to investigate the response of variations in soil freeze depth to climate change across China. Observations include daily air temperatures, daily soil temperatures at various depths, mean monthly gridded air temperatures, and the normalized difference vegetation index. Results show that soil freeze depth decreased significantly at a rate of −0.18 ± 0.03 cm yr−1, resulting in a net decrease of 8.05 ± 1.5 cm over 1967–2012 across China. On the regional scale, soil freeze depth decreases varied between 0.0 and 0.4 cm yr−1 in most parts of China during 1950–2009. By investigating potential climatic and environmental driving factors of soil freeze depth variability, we find that mean annual air temperature and ground surface temperature, air thawing index, ground surface thawing index, and vegetation growth are all negatively associated with soil freeze depth. Changes in snow depth are not correlated with soil freeze depth. Air and ground surface freezing indices are positively correlated with soil freeze depth. Comparing these potential driving factors of soil freeze depth, we find that freezing index and vegetation growth are more strongly correlated with soil freeze depth, while snow depth is not significant. We conclude that air temperature increases are responsible for the decrease in seasonal freeze depth. These results are important for understanding the soil freeze–thaw dynamics and the impacts of soil freeze depth on ecosystem and hydrological process.

Published

2016

42. Impacts of Land Use/Land Cover Change on Climate and Future Research Priorities

Author

Roger A. Pielke, Chandana Mitra, Oliver W. Frauenfeld, David R. Legates, Souleymane Fall, Ravinesh C. Deo, Peter D. Blanken, Jimmy O. Adegoke, Andrew M. Carleton, Anna Treviño, Gordon B. Bonan, Rezaul Mahmood, Jinyang Du, Robert Hale, Hsin I. Chang, Robert Lund, Elif Sertel, Salvi Asefi, Budong Qian, Marshall Shepherd, Samuel Gameda, Dev Niyogi, Clive McAlpine, Kenneth G. Hubbard, Andrés Etter, Yuling Wu, Glen Conner, Peter Lawrence, Adriana Beltrán-Przekurat, Valentine G. Anantharaj, Thomas N. Chase, Scott Dobler, Richard T. McNider, Sajith Vezhapparambu, Jozef Syktus, Ronnie Leeper, Anthony Watts, Arturo I. Quintanar, and Udaysankar S. Nair

Subjects

Atmospheric Science, Land use, business.industry, Environmental resource management, Skin temperature, Climate change, Land use land cover, Land cover, Climatic data, Climatology, Urbanization, Environmental science, Precipitation, business

Abstract

Several recommendations have been proposed for detecting land use and land cover change (LULCC) on the environment from, observed climatic records and to modeling to improve its understanding and its impacts on climate. Researchers need to detect LULCCs accurately at appropriate scales within a specified time period to better understand their impacts on climate and provide improved estimates of future climate. The US Climate Reference Network (USCRN) can be helpful in monitoring impacts of LULCC on near-surface atmospheric conditions, including temperature. The USCRN measures temperature, precipitation, solar radiation, and ground or skin temperature. It is recommended that the National Climatic Data Center (NCDC) and other climate monitoring agencies develop plans and seek funds to address any monitoring biases that are identified and for which detailed analyses have not been completed.

Published

2010

43. Surface–Atmosphere Moisture Interactions in the Frozen Ground Regions of Eurasia

Author

Oliver W. Frauenfeld and Trent W. Ford

Subjects

Multidisciplinary, 010504 meteorology & atmospheric sciences, Moisture recycling, Climate change, 010502 geochemistry & geophysics, Atmospheric sciences, Permafrost, 01 natural sciences, Article, Arctic, Snowmelt, Environmental science, Climate model, Precipitation, Water cycle, 0105 earth and related environmental sciences

Abstract

Climate models simulate an intensifying Arctic hydrologic cycle in response to climatic warming, however the role of surface-atmosphere interactions from degrading frozen ground is unclear in these projections. Using Modern-Era Retrospective Analysis for Research and Applications (MERRA) data in high-latitude Eurasia, we examine long-term variability in surface-atmosphere coupling as represented by the statistical relationship between surface evaporative fraction (EF) and afternoon precipitation. Changes in EF, precipitation and their statistical association are then related to underlying permafrost type and snow cover. Results indicate significant positive trends in July EF in the Central Siberian Plateau, corresponding to significant increases in afternoon precipitation. The positive trends are only significant over continuous permafrost, with non-significant or negative EF and precipitation trends over isolated, sporadic and discontinuous permafrost areas. Concurrently, increasing EF and subsequent precipitation are found to coincide with significant trends in May and June snowmelt, which potentially provides the moisture source for the observed enhanced latent heating and moisture recycling in the region. As climate change causes continuous permafrost to transition to discontinuous, discontinuous to sporadic, sporadic to isolated and isolated permafrost disappears, this will also alter patterns of atmospheric convection, moisture recycling and hence the hydrologic cycle in high-latitude land areas.

Published

2016

44. Synoptic conditions related to soil moisture‐atmosphere interactions and unorganized convection in Oklahoma

Author

Anita D. Rapp, Steven M. Quiring, Trent W. Ford, and Oliver W. Frauenfeld

Subjects

Convection, Atmospheric Science, Advection, Vapour Pressure Deficit, Geopotential height, Atmosphere, Geophysics, Space and Planetary Science, Climatology, Soil water, Earth and Planetary Sciences (miscellaneous), HYSPLIT, Environmental science, Air mass

Abstract

Atmospheric modification by anomalously dry or wet soils can both enhance and suppress convective activity. However, the local- and meso-scale feedbacks governing soil moisture–precipitation coupling are embedded within the larger synoptic-scale environment. Despite their importance, synoptic-scale atmospheric conditions are rarely considered in studies examining soil moisture-atmosphere interactions. We combine self-organizing maps (SOMs) of 500 hPa geopotential height, spatial synoptic classification, and Hybrid Single Particle Lagrangian Integrated Trajectory (HYSPLIT) model air mass trajectories to determine if the synoptic-scale environment affects the ability of the land surface to force unorganized convection in Oklahoma. We identify several synoptic patterns that significantly impact the frequency of unorganized convection. Synoptic patterns characterized by mid-level troughs over the Southern Great Plains are less frequently associated with unorganized convective events. These patterns exhibit cool air advection in the mid- and lower-levels of the atmosphere, and are linked to suppression of convective activity. The synoptic patterns characterized by 500 hPa ridging over the study region are more frequently associated with unorganized convective events. These patterns likely result in increased net radiation, vapor pressure deficit, and more homogenously dry soils. Unorganized convective events that occur during these synoptic conditions initiate preferentially over dry soils. We present evidence that the synoptic-scale environment can influence whether and how the land surface has an impact on convection.

Published

2015

45. Northern Hemisphere freezing/thawing index variations over the twentieth century

Author

Tingjun Zhang, Oliver W. Frauenfeld, and James McCreight

Subjects

Atmospheric Science, Climatology, Middle latitudes, Trend surface analysis, Northern Hemisphere, Environmental science, Climate change, Cru, Global change, Atmospheric temperature, Permafrost

Abstract

Changes in the ground thermal regime in high-latitude cold regions have important consequences for surface and subsurface hydrology, the surface energy and moisture balance, carbon exchange, as well as ecosystem diversity and productivity. However, assessing these changes, particularly in light of significant atmospheric and terrestrial changes in recent decades, remains a challenge owing to data sparseness and discontinuous observations. The annual freezing and thawing index can be useful in evaluating permafrost and seasonally frozen ground distribution, has important engineering applications, and is a useful indicator of high-latitude climate change. The freezing/thawing index is generally defined based on daily observations, which are not readily available for many high-latitude locations. We thus employ monthly air temperatures, and provide an assessment of the validity of this approach. On the basis of a comprehensive relative error (RE) evaluation we find that our methodology introduces errors of less than 5% for most high-latitude land areas, and works well in many midlatitude regions as well. We evaluate a suite of gridded monthly temperature datasets and select the University of East Anglia's Climatic Research Unit (CRU) temperature product, available for 1901–2002. We are thus able to provide a continuous long-term 25 km × 25 km gridded Northern Hemisphere freezing/thawing index. Long-term climatologies of the freezing/thawing index delineate the cold regions of the Northern Hemisphere, as well as areas of seasonally frozen ground and permafrost. Objective trend analysis indicates that in recent decades, no significant changes have occurred in Russian permafrost regions; however, seasonally frozen ground areas are experiencing significant warming trends. Over North America, Canadian and Alaskan permafrost regions are experiencing a decrease in freezing index during the cold season, while coastal areas and eastern Canada are seeing significant increase in warm season thawing index. Copyright © 2006 Royal Meteorological Society.

Published

2006

46. A Distinctly Interdecadal Signal of Pacific Ocean–Atmosphere Interaction

Author

Michael E. Mann, Oliver W. Frauenfeld, and Robert E. Davis

Subjects

Atmosphere, Atmospheric Science, Sea surface temperature, Oceanography, El Niño, Atmospheric circulation, Anomaly (natural sciences), Climatology, Northern Hemisphere, Environmental science, Pacific ocean, Pacific decadal oscillation

Abstract

A new and distinctly interdecadal signal in the climate of the Pacific Ocean has been uncovered by examining the coupled behavior of sea surface temperatures (SSTs) and Northern Hemisphere atmospheric circulation. This interdecadal Pacific signal (IPS) of ocean–atmosphere interaction exhibits a highly statistically significant interdecadal component yet contains little to no interannual (El Niño scale) variability common to other Pacific climate anomaly patterns. The IPS thus represents the only empirically derived, distinctly interdecadal signal of Pacific Ocean SST variability that likely also represents the true interdecadal behavior of the Pacific Ocean–atmosphere system. The residual variability of the Pacific’s leading SST pattern, after removal of the IPS, is highly correlated with El Niño anomalies. This indicates that by simply including an atmospheric component, the leading mode of Pacific SST variability has been decomposed into its interdecadal and interannual patterns. Although the interdecadal signal is unrelated to interannual El Niño variability, the interdecadal ocean–atmosphere variability still seems closely linked to tropical Pacific SSTs. Because prior abrupt changes in Pacific SSTs have been related to anomalies in a variety of physical and biotic parameters throughout the Northern Hemisphere, and because of the persistence of these changes over several decades, isolation of this interdecadal signal in the Pacific Ocean–atmosphere system has potentially important and widespread implications to climate forecasting and climate impact assessment.

Published

2005

47. Trends in precipitation on the wettest days of the year across the contiguous USA

Author

Oliver W. Frauenfeld, Robert E. Davis, Paul C. Knappenberger, and Patrick J. Michaels

Subjects

Atmospheric Science, Trend analysis, Climatology, Annual average, Environmental science, Climate change, Climate variation, Precipitation, Daily events

Abstract

Over the course of the 20th century, average annual precipitation for the contiguous USA has increased by nearly 10%. This increase has been described as being dominated by ‘disproportionate’ increases in extreme precipitation events. However, methodological constraints have confounded detailed interpretation of such results. Here, we briefly describe those limitations and re-evaluate the nature of the observed precipitation changes using a method that allows for a more accurate examination of changes in the proportion of precipitation delivered in extreme daily events. We focus our analysis only on the trends in precipitation on the 10 wettest days of the year and compare the trends observed on those days with the trend in overall precipitation. When averaged across the USA, we find that the precipitation trends on the 10 wettest days of the year are not significantly different from the trend in total overall precipitation. On a regional level, in the northeast and southeast there is some evidence that the rate of precipitation increase on the wettest days exceeds that of total precipitation, whereas in the rest of the country the precipitation on the wettest days is increasing at a rate less than the increase in total precipitation. Copyright  2004 Royal Meteorological Society.

Published

2004

48. Revised 21st century temperature projections

Author

Robert E. Davis, Paul C. Knappenberger, Oliver W. Frauenfeld, and Patrick J. Michaels

Subjects

Atmospheric Science, Impact assessment, Climatology, Global warming, Environmental Chemistry, Environmental science, Climate change, Climate model, General Environmental Science

Published

2002

49. The influence of El Niño-Southern Oscillation events on the northern hemisphere 500 hPa circumpolar vortex

Author

Robert E. Davis and Oliver W. Frauenfeld

Subjects

Atmospheric circulation, Anomaly (natural sciences), Northern Hemisphere, Vortex, Sea surface temperature, Geophysics, Oceanography, Polar vortex, Climatology, Middle latitudes, parasitic diseases, General Earth and Planetary Sciences, Longitude, Geology

Abstract

The relationship between El Nino, the Southern Oscillation, and their joint effect (ENSO), and Northern Hemisphere 500 hPa midlatitude circulation for the 1946–1994 observational record is determined. Seasonally standardized vortex positions at a spatial resolution of 5° longitude are correlated with an equatorial Pacific sea surface temperature anomaly index and the Southern Oscillation Index (SOI). The 500 hPa circumpolar vortex is consistently expanded over the central Pacific during and for the entire year following warm ENSO periods. The vortex is contracted over North America concurrently with warm ENSO and to a lesser degree during the following season. Expansion/contraction variability is also evident over east Asia, although the linkages to warm or cold ENSO are weak. Sea surface temperatures have a stronger association with the vortex than does the SOI.

Published

2000

50. A reconstruction of annual Greenland ice melt extent, 1784–2009

Author

Oliver W. Frauenfeld, Patrick J. Michaels, and Paul C. Knappenberger

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Atmospheric circulation, Paleontology, Soil Science, Climate change, Greenland ice sheet, Forestry, Aquatic Science, Oceanography, Ice-sheet model, Geophysics, Ice core, Space and Planetary Science, Geochemistry and Petrology, Climatology, Earth and Planetary Sciences (miscellaneous), Melt pond, Period (geology), Ice sheet, Geology, Earth-Surface Processes, Water Science and Technology

Abstract

[1] The total extent of ice melt on the Greenland ice sheet has been increasing during the last three decades. The melt extent observed in 2007 in particular was the greatest on record according to several satellite-derived records of total Greenland melt extent. Total annual observed melt extent across the Greenland ice sheet has been shown to be strongly related to summer temperature measurements from stations located along Greenland's coast, as well as to variations in atmospheric circulation across the North Atlantic. We make use of these relationships along with historical temperature and circulation observations to develop a near-continuous 226 year reconstructed history of annual Greenland melt extent dating from 2009 back into the late eighteenth century. We find that the recent period of high-melt extent is similar in magnitude but, thus far, shorter in duration, than a period of high melt lasting from the early 1920s through the early 1960s. The greatest melt extent over the last 2 1/4 centuries occurred in 2007; however, this value is not statistically significantly different from the reconstructed melt extent during 20 other melt seasons, primarily during 1923–1961.

Published

2011