Sea-level probability for the last deglaciation: A statistical analysis of far-field records
Pulses of ice-sheet meltwater into the world ocean during the last deglaciation are of great current interest, because these large-scale events offer important test-beds for numerical models of the responses of ocean circulation and climate to meltwater addition. The largest such event has become kn...
| Main Authors: | , , , , , |
|---|---|
| Format: | Article in Journal/Newspaper |
| Language: | unknown |
| Published: |
Elsevier
2015
|
| Subjects: | |
| Online Access: | http://hdl.handle.net/1885/78636 |
| id |
ftanucanberra:oai:digitalcollections.anu.edu.au:1885/78636 |
|---|---|
| record_format |
openpolar |
| spelling |
ftanucanberra:oai:digitalcollections.anu.edu.au:1885/78636 2023-05-15T16:41:38+02:00 Sea-level probability for the last deglaciation: A statistical analysis of far-field records Stanford, J D Hemingway, R. Rohling, Eelco Challenor, P.G. Medina-Elizalde, M Lester, A.J. 2015-12-13T22:41:44Z http://hdl.handle.net/1885/78636 unknown Elsevier 0921-8181 http://hdl.handle.net/1885/78636 Global and Planetary Change Journal article 2015 ftanucanberra 2015-12-28T23:37:09Z Pulses of ice-sheet meltwater into the world ocean during the last deglaciation are of great current interest, because these large-scale events offer important test-beds for numerical models of the responses of ocean circulation and climate to meltwater addition. The largest such event has become known as meltwater pulse (mwp) 1a, with estimates of about 20. m of sea-level rise in about 500. years. A second meltwater pulse (mwp-1b) has been inferred from some sea-level records, but its existence has become debated following the presentation of additional records. Even the use of the more ubiquitous mwp-1a in modelling studies has been compromised by debate about its exact age, based upon perceived discrepancies between far-field sea-level records. It is clear that an objective investigation is needed to determine to what level inferred similarities and/or discrepancies between the various deglacial sea-level records are statistically rigorous (or not). For that purpose, we present a Monte Carlo style statistical analysis to determine the highest-probability sea-level history from six key far-field deglacial sea-level records, which fully accounts for realistic methodological and chronological uncertainties in all these records, and which is robust with respect to removal of individual component datasets. We find that sea-level rise started to accelerate into the deglaciation from around 17. ka. BP. Within the deglacial rise, there were two distinct increases; one at around the timing of the Bølling warming (14.6. ka. BP), and another, much broader, event that just post-dates the end of the Younger Dryas (11.3. ka. BP). We interpret these as mwp-1a and mwp-1b, respectively. We find that mwp-1a occurred between 14.3. ka. BP and 12.8. ka. BP. Highest rates of sea-level rise occurred at ~. 13.8. ka, probably (67% confidence) within the range of 100-130. cm/century, although values may have been as high as 260. cm/century (99% confidence limit). Mwp-1b is robustly expressed as a broad multi-millennial interval of enhanced rates of sea-level rise between 11.5. ka. BP and 8.8. ka. BP, with peak rates of rise of up to 250. cm/century (99% confidence), but with a probable rate of 130-150. cm/century (67% confidence) at around 9.5. ka. BP. When considering the 67% probability interval for the deglacial sea-level history, it is clear that both mwp-1a and -1b were relatively subdued in comparison to the previously much higher rate estimates. Article in Journal/Newspaper Ice Sheet Australian National University: ANU Digital Collections |
| institution |
Open Polar |
| collection |
Australian National University: ANU Digital Collections |
| op_collection_id |
ftanucanberra |
| language |
unknown |
| description |
Pulses of ice-sheet meltwater into the world ocean during the last deglaciation are of great current interest, because these large-scale events offer important test-beds for numerical models of the responses of ocean circulation and climate to meltwater addition. The largest such event has become known as meltwater pulse (mwp) 1a, with estimates of about 20. m of sea-level rise in about 500. years. A second meltwater pulse (mwp-1b) has been inferred from some sea-level records, but its existence has become debated following the presentation of additional records. Even the use of the more ubiquitous mwp-1a in modelling studies has been compromised by debate about its exact age, based upon perceived discrepancies between far-field sea-level records. It is clear that an objective investigation is needed to determine to what level inferred similarities and/or discrepancies between the various deglacial sea-level records are statistically rigorous (or not). For that purpose, we present a Monte Carlo style statistical analysis to determine the highest-probability sea-level history from six key far-field deglacial sea-level records, which fully accounts for realistic methodological and chronological uncertainties in all these records, and which is robust with respect to removal of individual component datasets. We find that sea-level rise started to accelerate into the deglaciation from around 17. ka. BP. Within the deglacial rise, there were two distinct increases; one at around the timing of the Bølling warming (14.6. ka. BP), and another, much broader, event that just post-dates the end of the Younger Dryas (11.3. ka. BP). We interpret these as mwp-1a and mwp-1b, respectively. We find that mwp-1a occurred between 14.3. ka. BP and 12.8. ka. BP. Highest rates of sea-level rise occurred at ~. 13.8. ka, probably (67% confidence) within the range of 100-130. cm/century, although values may have been as high as 260. cm/century (99% confidence limit). Mwp-1b is robustly expressed as a broad multi-millennial interval of enhanced rates of sea-level rise between 11.5. ka. BP and 8.8. ka. BP, with peak rates of rise of up to 250. cm/century (99% confidence), but with a probable rate of 130-150. cm/century (67% confidence) at around 9.5. ka. BP. When considering the 67% probability interval for the deglacial sea-level history, it is clear that both mwp-1a and -1b were relatively subdued in comparison to the previously much higher rate estimates. |
| format |
Article in Journal/Newspaper |
| author |
Stanford, J D Hemingway, R. Rohling, Eelco Challenor, P.G. Medina-Elizalde, M Lester, A.J. |
| spellingShingle |
Stanford, J D Hemingway, R. Rohling, Eelco Challenor, P.G. Medina-Elizalde, M Lester, A.J. Sea-level probability for the last deglaciation: A statistical analysis of far-field records |
| author_facet |
Stanford, J D Hemingway, R. Rohling, Eelco Challenor, P.G. Medina-Elizalde, M Lester, A.J. |
| author_sort |
Stanford, J D |
| title |
Sea-level probability for the last deglaciation: A statistical analysis of far-field records |
| title_short |
Sea-level probability for the last deglaciation: A statistical analysis of far-field records |
| title_full |
Sea-level probability for the last deglaciation: A statistical analysis of far-field records |
| title_fullStr |
Sea-level probability for the last deglaciation: A statistical analysis of far-field records |
| title_full_unstemmed |
Sea-level probability for the last deglaciation: A statistical analysis of far-field records |
| title_sort |
sea-level probability for the last deglaciation: a statistical analysis of far-field records |
| publisher |
Elsevier |
| publishDate |
2015 |
| url |
http://hdl.handle.net/1885/78636 |
| genre |
Ice Sheet |
| genre_facet |
Ice Sheet |
| op_source |
Global and Planetary Change |
| op_relation |
0921-8181 http://hdl.handle.net/1885/78636 |
| _version_ |
1766032100079697920 |