Changes in El Niño – Southern Oscillation (ENSO) conditions during the Greenland Stadial 1 (GS-1) chronozone revealed by New Zealand tree-rings
(2016) In Quaternary Science Reviews 153. p.139-155- Abstract
The warming trend at the end of the last glacial was disrupted by rapid cooling clearly identified in Greenland (Greenland Stadial 1 or GS-1) and Europe (Younger Dryas Stadial or YD). This reversal to glacial-like conditions is one of the best known examples of abrupt change but the exact timing and global spatial extent remain uncertain. Whilst the wider Atlantic region has a network of high-resolution proxy records spanning GS-1, the Pacific Ocean suffers from a scarcity of sub-decadally resolved sequences. Here we report the results from an investigation into a tree-ring chronology from northern New Zealand aimed at addressing the paucity of data. The conifer tree species kauri (Agathis australis) is known from contemporary studies... (More)
The warming trend at the end of the last glacial was disrupted by rapid cooling clearly identified in Greenland (Greenland Stadial 1 or GS-1) and Europe (Younger Dryas Stadial or YD). This reversal to glacial-like conditions is one of the best known examples of abrupt change but the exact timing and global spatial extent remain uncertain. Whilst the wider Atlantic region has a network of high-resolution proxy records spanning GS-1, the Pacific Ocean suffers from a scarcity of sub-decadally resolved sequences. Here we report the results from an investigation into a tree-ring chronology from northern New Zealand aimed at addressing the paucity of data. The conifer tree species kauri (Agathis australis) is known from contemporary studies to be sensitive to regional climate changes. An analysis of a ‘historic’ 452-year kauri chronology confirms a tropical-Pacific teleconnection via the El Niño – Southern Oscillation (ENSO). We then focus our study on a 1010-year sub-fossil kauri chronology that has been precisely dated by comprehensive radiocarbon dating and contains a striking ring-width downturn between ∼12,500 and 12,380 cal BP within GS-1. Wavelet analysis shows a marked increase in ENSO-like periodicities occurring after the downturn event. Comparison to low- and mid-latitude Pacific records suggests a coherency with ENSO and Southern Hemisphere atmospheric circulation change during this period. The driver(s) for this climate event remain unclear but may be related to solar changes that subsequently led to establishment and/or increased expression of ENSO across the mid-latitudes of the Pacific, seemingly independent of the Atlantic and polar regions.
(Less)
- author
- Palmer, Jonathan G.
; Turney, Chris S M
; Cook, Edward R.
; Fenwick, Pavla
; Thomas, Zoë
; Helle, Gerhard
; Jones, Richard
; Clement, Amy
; Hogg, Alan
; Southon, John
; Bronk Ramsey, Christopher
; Staff, Richard
; Muscheler, Raimund
LU
; Corrège, Thierry
and Hua, Quan
(Less) - organization
- publishing date
- 2016-12-01
- type
- Contribution to journal
- publication status
- published
- subject
- keywords
- Abrupt climate change, Antarctic Cold Reversal (ACR), Bipolar seesaw, Dendrochronology, Kauri (Agathis australis), Last Termination, Younger Dryas (YD)
- in
- Quaternary Science Reviews
- volume
- 153
- pages
- 17 pages
- publisher
- Elsevier
- external identifiers
-
- wos:000389116000010
- scopus:84994607573
- ISSN
- 0277-3791
- DOI
- 10.1016/j.quascirev.2016.10.003
- language
- English
- LU publication?
- yes
- id
- 65706977-1ccd-4e46-9359-e9a1dd505048
- date added to LUP
- 2016-11-25 12:16:09
- date last changed
- 2024-10-05 06:30:42
@article{65706977-1ccd-4e46-9359-e9a1dd505048,
abstract = {{<p>The warming trend at the end of the last glacial was disrupted by rapid cooling clearly identified in Greenland (Greenland Stadial 1 or GS-1) and Europe (Younger Dryas Stadial or YD). This reversal to glacial-like conditions is one of the best known examples of abrupt change but the exact timing and global spatial extent remain uncertain. Whilst the wider Atlantic region has a network of high-resolution proxy records spanning GS-1, the Pacific Ocean suffers from a scarcity of sub-decadally resolved sequences. Here we report the results from an investigation into a tree-ring chronology from northern New Zealand aimed at addressing the paucity of data. The conifer tree species kauri (Agathis australis) is known from contemporary studies to be sensitive to regional climate changes. An analysis of a ‘historic’ 452-year kauri chronology confirms a tropical-Pacific teleconnection via the El Niño – Southern Oscillation (ENSO). We then focus our study on a 1010-year sub-fossil kauri chronology that has been precisely dated by comprehensive radiocarbon dating and contains a striking ring-width downturn between ∼12,500 and 12,380 cal BP within GS-1. Wavelet analysis shows a marked increase in ENSO-like periodicities occurring after the downturn event. Comparison to low- and mid-latitude Pacific records suggests a coherency with ENSO and Southern Hemisphere atmospheric circulation change during this period. The driver(s) for this climate event remain unclear but may be related to solar changes that subsequently led to establishment and/or increased expression of ENSO across the mid-latitudes of the Pacific, seemingly independent of the Atlantic and polar regions.</p>}},
author = {{Palmer, Jonathan G. and Turney, Chris S M and Cook, Edward R. and Fenwick, Pavla and Thomas, Zoë and Helle, Gerhard and Jones, Richard and Clement, Amy and Hogg, Alan and Southon, John and Bronk Ramsey, Christopher and Staff, Richard and Muscheler, Raimund and Corrège, Thierry and Hua, Quan}},
issn = {{0277-3791}},
keywords = {{Abrupt climate change; Antarctic Cold Reversal (ACR); Bipolar seesaw; Dendrochronology; Kauri (Agathis australis); Last Termination; Younger Dryas (YD)}},
language = {{eng}},
month = {{12}},
pages = {{139--155}},
publisher = {{Elsevier}},
series = {{Quaternary Science Reviews}},
title = {{Changes in El Niño – Southern Oscillation (ENSO) conditions during the Greenland Stadial 1 (GS-1) chronozone revealed by New Zealand tree-rings}},
url = {{http://dx.doi.org/10.1016/j.quascirev.2016.10.003}},
doi = {{10.1016/j.quascirev.2016.10.003}},
volume = {{153}},
year = {{2016}},
}