论文信息 - The Retreat of Mountain Glaciers since the Little Ice Age: A Spatially Explicit Database - 字舞流文

The Retreat of Mountain Glaciers since the Little Ice Age: A Spatially Explicit Database

Most of the world’s mountain glaciers have been retreating for more than a century in response to climate change. Glacier retreat is evident on all continents, and the rate of retreat has accelerated during recent decades. Accurate, spatially explicit information on the position of glacier margins over time is useful for analyzing patterns of glacier retreat and measuring reductions in glacier surface area. This information is also essential for evaluating how mountain ecosystems are evolving due to climate warming and the attendant glacier retreat. Here, we present a non-comprehensive spatially explicit dataset showing multiple positions of glacier fronts since the Little Ice Age (LIA) maxima, including many data from the pre-satellite era. The dataset is based on multiple historical archival records including topographical maps; repeated photographs, paintings, and aerial or satellite images with a supplement of geochronology; and own field data. We provide ESRI shapefiles showing 728 past positions of 94 glacier fronts from all continents, except Antarctica, covering the period between the Little Ice Age maxima and the present. On average, the time series span the past 190 years. From 2 to 46 past positions per glacier are depicted (on average: 7.8).

Gentile Francesco Ficetola | Davide Fugazza | Antoine Rabatel | Sigmund Hågvar | Guglielmina Adele Diolaiuti | Roberto Ambrosini | Marco Caccianiga | Aurélie Bonin | Pritam Chand | Roberto Seppi | Philip Deline | Andrea Franzetti | Ludovic Gielly | Silvio Marta | Roberto Sergio Azzoni | Levan Tielidze | Katrin Sieron | Peter Almond | Fabien Anthelme | Pablo Alviz Gazitúa | Rakesh Bhambri | Sophie Cauvy-Fraunié | Jorge Luis Ceballos Lievano | John Clague | Justiniano Alejo Cochachín Rapre | Olivier Dangles | Andre Eger | Rolando Cruz Encarnación | Sergey Erokhin | Fabrizio Gili | Mauro Gobbi | Alessia Guerrieri | Norine Khedim | Rahab Kinyanjui | Erwan Messager | Marco Aurelio Morales-Martínez | Gwendolyn Peyre | Francesca Pittino | Jerome Poulenard | Milap Chand Sharma | Nurai Urseitova | Blake Weissling | Yan Yang | Vitalii Zaginaev | Anaïs Zimmer | J. Clague | P. Deline | M. Sharma | O. Dangles | R. Bhambri | R. Ambrosini | G. Diolaiuti | G. Ficetola | L. Gielly | A. Bonin | F. Gili | F. Anthelme | A. Franzetti | S. Hågvar | M. Caccianiga | B. Weissling | G. Peyre | J. Poulenard | M. Gobbi | P. Almond | S. Cauvy‐Fraunié | R. Seppi | A. Eger | A. Rabatel | D. Fugazza | R. Azzoni | R. Kinyanjui | F. Pittino | A. Guerrieri | E. Messager | Yan Yang | K. Sieron | M. Morales-Martínez | S. Marta | P. Chand | Levan Tielidze | R. Encarnación | S. Erokhin | N. Khedim | Nurai Urseitova | V. Zaginaev | Anaïs Zimmer | Alessia Guerrieri | Gwendolyn Peyre

[1] Andreas Kääb,et al. High Mountain Areas , 2019, The Ocean and Cryosphere in a Changing Climate.

[2] R. Ambrosini,et al. Dynamics of Ecological Communities Following Current Retreat of Glaciers , 2021, Annual Review of Ecology, Evolution, and Systematics.

[3] M. Nüsser,et al. Assessing glacier changes in the Nanga Parbat region using a multitemporal photographic dataset , 2021, Data in brief.

[4] O. Dangles,et al. Multi‐taxa colonisation along the foreland of a vanishing equatorial glacier , 2021, Ecography.

[5] M. Nüsser,et al. Glacier changes on the Nanga Parbat 1856-2020: A multi-source retrospective analysis. , 2021, The Science of the total environment.

[6] J. Clague,et al. Topsoil organic matter build‐up in glacier forelands around the world , 2020, Global change biology.

[7] M. Huss,et al. On the Imbalance and Response Time of Glaciers in the European Alps , 2020, Geophysical Research Letters.

[8] F. Paul,et al. Glacier shrinkage in the Alps continues unabated as revealed by a new glacier inventory from Sentinel-2 , 2019, Earth System Science Data.

[9] O. Dangles,et al. A global synthesis of biodiversity responses to glacier retreat , 2019, Nature Ecology & Evolution.

[10] N. Eckert,et al. Global glacier mass changes and their contributions to sea-level rise from 1961 to 2016 , 2019, Nature.

[11] Geneva, Switzerland , 2019, The Statesman’s Yearbook Companion.

[12] M. Nüsser,et al. Nanga Parbat Revisited: Evolution and Dynamics of Sociohydrological Interactions in the Northwestern Himalaya , 2017, Mountains: Physical, Human-Environmental, and Sociocultural Dynamics.

[13] S. U. Nussbaumer,et al. Little Ice Age glacier history of the Central and Western Alps from pictorial documents , 2017 .

[14] M. Sharma,et al. Reconstructing the pattern of the Bara Shigri Glacier fluctuation since the end of the Little Ice Age, Chandra valley, north-western Himalaya , 2017 .

[15] R. Wheate,et al. The Greater Caucasus Glacier Inventory (Russia, Georgia and Azerbaijan) , 2017 .

[16] Olaf Conrad,et al. Climatologies at high resolution for the earth’s land surface areas , 2016, Scientific Data.

[17] C. Schöb,et al. Feedback effects between plant and flower-visiting insect communities along a primary succession gradient , 2016, Arthropod-Plant Interactions.

[18] M. Caccianiga,et al. Glacier Forelands: Lessons of Plant Population and Community Development , 2016 .

[19] Antoine Rabatel,et al. Multitemporal glacier inventory of the French Alps from the late 1960s to the late 2000s , 2014 .

[20] David Parkes,et al. Attribution of global glacier mass loss to anthropogenic and natural causes , 2014, Science.

[21] C. Rondinini,et al. An evaluation of the robustness of global amphibian range maps , 2014 .

[22] Jeffrey S. Kargel,et al. Global Land Ice Measurements from Space , 2014 .

[23] J. Aravena,et al. Lichenometric analysis using genus Rhizocarpon, section Rhizocarpon (Lecanorales: Rhizocarpaceae) at Mount San Lorenzo, southern Chile , 2013 .

[24] Manuel Collet,et al. Current state of glaciers in the tropical Andes: a multi-century perspective on glacier evolution and climate change , 2013 .

[25] Jens Hartmann,et al. The new global lithological map database GLiM: A representation of rock properties at the Earth surface , 2012 .

[26] Erle C. Ellis,et al. Mapping where ecologists work: biases in the global distribution of terrestrial ecological observations , 2012, Frontiers in Ecology and the Environment.

[27] S. U. Nussbaumer,et al. The Little Ice Age history of the Glacier des Bossons (Mont Blanc massif, France): a new high-resolution glacier length curve based on historical documents , 2012, Climatic Change.

[28] J. Cogley,et al. Estimating the Glacier Contribution to Sea-Level Rise for the Period 1800–2005 , 2011 .

[29] L. A. Rasmussen,et al. Glossary of glacier mass balance and related terms , 2010 .

[30] G. Hoffmann,et al. Fluctuations of glaciers in the tropical Andes over the last millennium and palaeoclimatic implications: A review , 2009 .

[31] Mark Carey. The History of Ice: How Glaciers Became an Endangered Species , 2007, Environmental History.

[32] Siri Jodha Singh Khalsa,et al. The GLIMS geospatial glacier database: A new tool for studying glacier change ☆ , 2007 .

[33] Mark Carey. Living and dying with glaciers: people's historical vulnerability to avalanches and outburst floods in Peru ☆ , 2005 .