Date post: | 18-Feb-2017 |
Category: |
Science |
Upload: | coralsncaves |
View: | 33 times |
Download: | 0 times |
Paleo-constraints on future tropical Pacific climateKim M. Cobb
Pamela Grothe, Hussein Sayani, Alyssa Atwood, Tianran Chen, Intan NurhatiEarth and Atmospheric Sciences, Georgia Tech
Chris Charles, SIO, UCSDLarry Edwards, Hai Cheng, UMN
• Pa
leocli
mate R
esearch • Georgia Tech •
Cobb Lab
Option 1
Wait 100+ years until we have enough instrumental data(e.g. Stevenson et al., 2012)
Is ENSO changing?
Option 1
Wait 100+ years until we have enough instrumental data(e.g. Stevenson et al., 2012)
Option 2
Use paleo-ENSO records to establish quantitative estimates of pre-industrial ENSO variability, compare to recent ENSO variability
Is ENSO changing?
last 100+ yrs
last 7000 yrsU/Th dated
drilled via SCUBA
storm/tsunami depositsscattered on beachesacross the tropics
1mm sampling transect for coral oxygen isotopes (δ18O)affords monthly resolution
Coral δ18O = SST + δ18Oseawater
1mm sampling transect for coral oxygen isotopes (δ18O)affords monthly resolution
Coral δ18O = SST + δ18Oseawater
co-varies with SSS(Fairbanks et al., 1997;Conroy et al., 2014)
1970 1975 1980 1985 1990 1995 2000 2005 2010 2015
-5.5
-5
-4.5
-4
22
24
26
28
30
Nurhati09 Evans99 x126 x123 Minicore1 Minicore2 OISSTv2
SS
T (º
C)
δ18 O
(‰)
coral oxygen isotopes vs. SST
grey=OISST
colors=coralδ18O
Evansetal.,1999Nurhati etal.,2009Grothe etal.,inprep
O’Connoretal.,inprep
1970 1975 1980 1985 1990 1995 2000 2005 2010 2015
-5.5
-5
-4.5
-4
22
24
26
28
30
Nurhati09 Evans99 x126 x123 Minicore1 Minicore2 OISSTv2
SS
T (º
C)
δ18 O
(‰)
coral oxygen isotopes vs. SST
grey=OISST
colors=coralδ18O
Evansetal.,1999Nurhati etal.,2009Grothe etal.,inprep
O’Connoretal.,inprepCoral δ18O records are interchangeable with SST.
Replication yields better reconstruction.
800 1000 1200 1400 1600 1800 2000
−5.5
−5
−4.5
−4
Year CE
Xmas coral d18O last millennium
monthly coral δ18O recordsthrough the last millennium
2015/2016 El Niño
δ18 O
(‰)
800 1000 1200 1400 1600 1800 2000
−5.5
−5
−4.5
−4
Year CE
Xmas coral d18O last millennium
monthly coral δ18O recordsthrough the last millennium
2015/2016 El Niño
δ18 O
(‰)
Has ENSO variance changed?
01000200030004000500060007000
−60
−40
−20
0
20
40
Year BP
Cha
nge
in s
tdev
of E
NSO
(%)
Fanning
Christmas
Palmyra
20th century
range
Grothe etal.,inprepCobbetal,2013Cobbetal.,2003McGregoretal.,2013Grothe etal.,inprepWoodroffe etal.,2003
1985-2005ENSOvariability
ENSOvarianceoverthelast7,000yrs
strongerENSO
weakerENSO
Most pre-industrial data reflectmuch weaker ENSO than present.
Virtually certain* that observed distribution ofinterannual coral δ18O variance does not reflect a stationary process.
* Significant of pre-industrial to modern shift in coral interannual variance is somewhat sensitive to the choice of null, and different testing periods will give you slightly different significance levels. Full investigation of significance will be reported in Grothe et al., in prep
Virtually certain* that observed distribution ofinterannual coral δ18O variance does not reflect a stationary process.
In and of itself, this does not prove that ENSOhas intensified with anthropogenic climate change.
* Significant of pre-industrial to modern shift in coral interannual variance is somewhat sensitive to the choice of null, and different testing periods will give you slightly different significance levels. Full investigation of significance will be reported in Grothe et al., in prep
Virtually certain* that observed distribution ofinterannual coral δ18O variance does not reflect a stationary process.
In and of itself, this does not prove that ENSOhas intensified with anthropogenic climate change.
However…
* Significant of pre-industrial to modern shift in coral interannual variance is somewhat sensitive to the choice of null, and different testing periods will give you slightly different significance levels. Full investigation of significance will be reported in Grothe et al., in prep
Evidencethat(late)20th centuryinterannual
varianceisstrongerthanpre-industrialvalues:
Lietal.,2013à treeringsfromJava
McGregoretal.,2013à Pacificmulti-proxy
Liuetal.,inrevisionà Taiwantreeδ18O
Cobbetal.,2013;Grothe etal.,inprepàLineIslandscoralδ18O
All paleo-ENSO records rely (to varying extents) on hydrological response to ENSO SST anomalies.
So now we have a new question:
Is ENSO SST variance already increasing?
or
Are we already seeing “more rainfall bang for our SST anomaly buck” that models project for the 21st century?(Power et al., 2013; Cai et al., 2014)
Frontiers and opportunitiespaleo-data assimilation
Journal of Geophysical Research: Atmospheres 10.1002/2016JD024751
Figure 1. Conceptual framework for the Last Millennium Reanalysis, outlining our paleoassimilation approach. Startingfrom the prior (a collection of simulated climate states) from which random draws are pulled, the states are mappedto proxy space via a proxy system model (PSM). These predictions y are compared to the actual proxy measurements yto compute the innovation, y − y. These innovations are then used to update the prior via the Kalman filter equations,which also update the error covariance. The cycle is repeated many (104) times to sample the distribution of the priorensemble.
diagonal matrix, and the diagonal values represent the error variance for each proxy (defined in section 2.4).A 100-member ensemble is used, and results are insensitive to this choice provided that the ensemble has atleast 50 members.
As an explicit illustration of how multivariate fields are recovered, consider a single tree ring width proxymeasurement for 1 year and assume a PSM that depends only on 2 m air temperature. We take the prior toconsist of 2 m air temperature at the location of the proxy and a globally gridded 500 hPa geopotential heightfield. The prior fields consist of an ensemble of annual-mean values, randomly drawn from a long climatesimulation. From this, we should expect that the prior estimate of the proxy, (xp), will differ considerablyfrom the proxy value; i.e., the innovation will be large. How much weight the innovation gets in equation (1)depends on R (see equation (2)), which in this example is simply a scalar variance, r. Given the innovation,which in this case is a scalar value, K determines the weight and transfers information from the innovation(in units of tree ring width) to the 500 hPa geopotential height field. Consider the 500 hPa geopotential heightat a single point in the global grid and call it x. From (2),
BHT ∼ 1n − 1
x(Hxp)T (3)
where n is the ensemble size and x is a row vector containing the ensemble of n values of 500 hPa geopo-tential heights (x) at the point, with the ensemble mean removed. The right side of equation (3) representsthe covariance between the 500 hPa height at the point and the prior estimate of the proxy. In the denomi-nator of K, HBHT is a scalar, representing the variance of the ensemble estimate of the proxy, var(ye) (directlycomparable to r). Therefore, we update the ensemble mean 500 hPa geopotential height at the point by
xa = xp + cov(xp, ye)var(ye) + r
(y − ye) (4)
where ye =Hxp is the prior estimated proxy; i.e., this equation says that the analysis 500 hPa geopotentialheight at the point is determined by linearly regressing the prior estimate against the innovation.
HAKIM ET AL. LAST MILLENNIUM REANALYSIS 6748
Hakim et al., JGR-Atm, 2016
Past trips:
Aug 2014
March 2015
July 2015
Nov 2015
April 2016
Team:
Kim Cobb (Georgia Tech, paleoclimate)
Julia Baum (U. Victoria, ecologist)
Ruth Gates (UH, coral ecologist)
Mark Merrifield (UH, phys. oceanography)
Brian Powell (UH, phys. oceanography)
Samantha Stevenson (NOAA, climate
scientist, ocean modeler)
Planned trips:
Nov 2016
April 2017
Research Goals:
data assimilation of coral δ18O data
(iso-ROMS) à reanalysis products
integrated climate and ecological impact
study over 2015/16 El Niño and beyond
Frontiers and opportunities
Summary
The paleoclimate community needs CLIVARto unlock the vast potential of their data.
CLIVAR needs the paleoclimate communityto address some of the most pressingquestions concerning the impacts of anthropogenic climate change.
Summary
The paleoclimate community needs CLIVARto unlock the vast potential of their data.
CLIVAR needs the paleoclimate communityto address some of the most pressingquestions concerning the impacts of anthropogenic climate change.
Rapid progress is possible but requires interdisciplinary teams of scientistsworking towards shared goals.