Abrupt Northward Shift of SPCZ position in the late-1920 s Indicates Coordinated Atlantic and Pacific ITCZ Change

Introduction Patterns of climate variability are often studied by evaluating instrumental or paleo-data from regions that have the highest correlations to the target climate mode. For example, past variations in ENSO have been primarily evaluated by compiling or reconstructing sea surface temperature (SST) in the Nino3.4 (5°N-5°S; 120°W-170°W) and Nino3 (5°N-5°S; 90°W-150°W) regions in the equatorial Pacific (e.g.: Trenberth 1997; Urban et al., 2000; Cobb et al., 2013). However, critical information on the spatial extent of a target climate mode can also be gained by studying conditions on the nodal line perimeter of the climate pattern where on average there is no correlation (R=~0) between the climate parameter being reconstructed and the target mode.


Introduction
Patterns of climate variability are often studied by evaluating instrumental or paleo-data from regions that have the highest correlations to the target climate mode.For example, past variations in ENSO have been primarily evaluated by compiling or reconstructing sea surface temperature (SST) in the Nino3.4(5°N-5°S; 120°W-170°W) and Nino3 (5°N-5°S; 90°W-150°W) regions in the equatorial Pacific (e.g.: Trenberth 1997; Urban et al., 2000;Cobb et al., 2013).However, critical information on the spatial extent of a target climate mode can also be gained by studying conditions on the nodal line perimeter of the climate pattern where on average there is no correlation (R=~0) between the climate parameter being reconstructed and the target mode.
During El Niño and La Niña events in the Pacific, the largest SST anomalies are focused in an elongated E-W pattern or footprint that is generally symmetric around 0° latitude in the central Pacific.Individual ENSO events display differences in both the amplitude and the longitude of the largest SST anomalies and cluster analysis of the last 50 years of Pacific SST data indicate that there are three primary El Niño patterns and one primary La Niña pattern (Chen et al., 2015).The mean of these ENSO event patterns results in the classic footprint in ENSOrelated SST anomalies surrounded by a perimeter where SST is on average not positively or negatively correlated with ENSO (see Fig. 1).This perimeter reflects a nodal line where on average SST variability is not correlated to ENSO.Instrumental data suggest that the average ENSO nodal line for all types of El Niño and La Niño events has been relatively stable over the last ~50 years.
In the South Pacific, the ENSO nodal line runs northwest to southeast though Samoa (14°S, 172°W) and American Samoa (14°S, 169.5°W) to French Polynesia (17°S, 150°W)(Fig.1).This location is nearly identical to the nodal line for the decadal mode of SST variability in the Pacific (the Pacific Decadal Oscillation (PDO)).Since the PDO appears to have both subtropical and tropical origins (Newman et al., 2016), the congruence of ENSO and PDO nodal lines in some regions is not unexpected.This region in the South Pacific is also the central rainfall axis of the South Pacific Convergence Zone (SPCZ) which trends northwest to southeast from the Equator in the western Pacific through Samoa and American Samoa.
The SPCZ is the largest spur of the Intertropical Convergence Zone (ITCZ) and a key hydrologic feature in the tropics yet its dynamics and even current position are poorly represented in climate models (Vincent 1994;Vincent et al., 2009;Cai et al., 2012;Evans et al., 2015).Atmospheric data indicate a close relationship between SPCZ movements and ENSO in this region.Over the last 30 years, instrumental precipitation data indicate that during most El Niño events the SPCZ moves a few degrees northward (Gouriou and Delcroix 2002;Vincent et al., 2009;Salinger et al., 1995).Southward SPCZ shifts occur during La Niña events (Gouriou andDelcroix 2002, Vincent et al., 2009;Cai et al., 2012).During very strong El Niño events such as 1982/83 and 1997/98, and during some moderate strength El Niño's such as 1991-1992, the SPCZ can collapse onto the equator (so-called zonal SPCZ events; Vincent et al., 2009;Linsley et al., 2017).Both SPCZ responses during El Niño result in saltier and slightly cooler conditions on average in the area of the SPCZ central rainfall axis as the SPCZ shifts northeast and the westward flowing South Equatorial Current (SEC) advects relatively salty water into the region.
In an effort to track past changes in the SPCZ response to ENSO events and the PDO we have analyzed sub-seasonal skeletal δ 18 O in a Porites lutea coral core from the island of Ta'u in the Manua Island group on the eastern side of American Samoa.Ta'u Island is located in the center of the SPCZ and on the nodal line region for both ENSO and the PDO.Variability of surface oceanographic conditions in American Samoa are closely related to SEC dynamics and SPCZ movements.This is the first 50+ year coral δ 18 O reconstruction from Samoa and American Samoa.

Methods
In November 2011 we cored a large colony of Porites lutea on the western side of the island of Ta'u located at S 14° 15' 33.74": W 169° 30' 01.61" (or S 14 15.566, W 169 30.027) on an exposed outer reef in 7.5m (25 feet) of water (water depth to top of coral).Core sections from the Ta'u-1 core were sawed longitudinally in half and 5mm thick slabs cut at Stanford University and shipped to the Lamont-Doherty Earth Observatory (LDEO) for isotopic analysis.At LDEO, slabs were cleaned in a deionized water bath with a probe sonicator (500W, 20kHz).Slabs were then oven dried at 50°C.Once dried, the slabs were X-rayed in an HP cabinet X-ray system (at 35 Kv).The X-ray positives were used to identify growth band orientation and the maximum growth axis down each slab section as a guide to the subsampling path.Subannual samples were hand-drilled from the slabs at 1 mm intervals by excavating a 3 mm wide by 2 mm deep trough with a variable speed Dremel drill fit with a spherical carbide bit.
Sample powders were analyzed on either an Elementar Isoprime mass spectrometer equipped with a dualinlet and Multiprep or a Themo-Fisher Delta V+ mass spectrometer with dual-inlet and Kiel IV carbonate reaction device.The instruments are in the same laboratory at LDEO and have been cross-calibrated.They use the same CO 2 reference gas and dewatered phosphoric acid is made using the same protocols for each instrument.The samples from the core's live-collected top, serve to anchor the chronology for the δ 18 O series to November 2011.Below this section, annual δ 18 O minima and maximum were attributed to seasonal maxima and minima in SST, respectively.Verification of this approach comes from pseudo-coral forward modeling where we used instrumental SST and sea surface salinity (SSS) to generate a modeled coral δ 18 O series from 2008 to 1981 (Fig. 2).This model assumes all variability in coral δ 18 O at Ta'u is due to SST and SSS.Ta'u-1 annual average coral δ 18 O and annual average pseudo-coral δ 18 O significantly correlate (R=0.77;p < 0.001) with annual average correlations between coral δ 18 O and SST and SSS of -0.58 and 0.64 respectively.This pseudo-coral comparison verifies our chronology and indicates that Porites coral δ 18 O at Ta'u is a function of both SST and SSS and where interannual changes in SST and SSS have additive effects on interannual coral δ 18 O variability.This 2.6m section of core extends from November 2011 to ~ January 1800.

Results and Discussion
Although on average there is no correlation between SST variability in American Samoa and Nino3.4 or Nino3 SST  2).There has been a close relationship between SPCZ movements, ENSO and the eastern extent of the western Pacific warm pool with the SPCZ shifting northeast during El Niño events and southwest during La Niña events (Gouriou andDelcroix 2002, Vincent et al., 2009).This SPCZ re-positioning results in more saline conditions on average in the Samoa region during El Niño as the SPCZ shifts northeast and the westward flowing SEC advects relatively salty water into the region.
To evaluate interannual and lower frequency changes in Ta'u-1 coral δ 18 O for comparison to equatorial indices of ENSO, we filtered the monthly coral δ 18 O series in two ways.Our first approach was to 24 month high-pass filter and then detrend the coral δ 18 O series due to the presence of a significant secular coral δ 18 O trend.The detrending was accomplished using Singular Spectrum Analysis to isolate and then remove the first principal component (the secular trend).This filtered Ta'u δ 18 O time series was then compared to 7 month running average filtered Nino3.4SST anomalies (see Fig. 3A).The second filtering approach was to apply only a 24 month high-pass filter (leaving the trend in place) to facilitate direct comparison to equatorial coral δ 18 O records (see Fig. 3C).We use a composite average of three coral δ 18 O records from Fanning (Cobb et al., 2013), Palmyra (Cobb et al., 2013) and Maiana (Urban et al., 2000) as a coral δ 18 O-based index of equatorial ENSO state (termed FPM; see Linsley et al., 2015).Prior to 1927, the Ta'u coral δ 18 O record contains distinct evidence that on average fresher conditions occurred during El Niño events in Samoa/American Samoa (Fig. 3A and C).This is exactly the situation which occurs today north of Samoa between 7°S and 8°S near the island groups of Tokelau (8°S, 172°W) and Tavalu (7°S, 179°E) (see Fig. 4).Surface salinity is significantly lower during El Niño events in the region extending NW-SE including the Tavalu and Tokelau Island groups at 7-8°S.At the same time, surface salinity increases at Fiji, Tonga and Samoa (Fig. 4).
These observations indicate that the mean position of the SPCZ must have been shifted southwest of its current position during at least the ~50 year period prior to the late 1920s combined possibly with a reduced latitudinal migration to the northeast during El Niño.This reorganization would explain the fresher conditions during El Niño recorded in our Ta'u coral δ 18 O record in  variability and equatorial ENSO.The lack of a change in SPCZ-ENSO phasing in the late 1960s when the AMO shifted from a positive phase to a negative phase suggests that there was something climatically different in the late 1920s and/or that the SPCZ and ITCZ are not connected causally.The 1920's were also a time when the PDO changed phase, although this phase change was gradual and appears to have started in the early 1920s.Other clues to significant tropical-subtropical re-organization in the late 1920s at the same time as the SPCZ and Atlantic ITCZ shifted north are a 1920s shift to weaker Pacific trade winds (Thompson et al., 2014).Further interpretation of these preliminary observations of SPCZ position change in the late 1920s will require future work.

Figure 1 :
Figure 1: Average correlation pattern of SST to Nino3 SST.Red-purple colors indicate positive correlation and green-blue colors indicate negative correlation.White box indicates the Nino3 region for monitoring ENSO sign and strength and black dashed box the Nino3.4region.Yellow circle highlights the location of our Ta'u coral site in American Samoa.Note that the zero correlation line (nodal line) runs SE-NW right through Samoa.Also shown are the locations of Fanning, Palmyra and Maiana (see Fig.3C) and Fiji, Tonga, Tokelau and Tavalu (see Fig.4).
Comparing the Ta'u coral δ 18 O record to the timing of equatorial ENSO variability indicates a striking phase shift in the decadal mean correlation in the late 1920s.Running correlations between the Ta'u δ 18 O results and Nino3.4SST and the FPM equatorial composite coral δ 18 O highlights the abruptness of the phase shift in the 1920s (see Fig.3B and D).Sea surface temperature (using ERSST) at American Samoa shows no change in phasing with Nino3.4SST in the 1920s (not shown) pointing to a change in the timing of interannual surface salinity variability.The Ta'u coral δ 18 O series indicates that the relationship between El Niño events and more saline conditions in this central region of the SPCZ existed only back to 1927, when there was an abrupt change.

Figure 4 :Figure 3 :
Figure 4: Monthly surface salinity from near Fiji, American Samoa, Tonga, and near Tokelau and Tavalu (north and northwest of Samoa respectively) (data from Delcroix et al., 2011).Note the strong freshening in the regions of the Tokelau and Tavalu Islands during El Niño (tan bars) when the SPCZ shifts northeast.Fiji and Tonga experience higher salinities during El Niño whereas Samoa surface salinity has a more intermediate response.Blue bars are La Niña events.
Here we report the δ 18 O results of the analysis of this upper 2.6m of core (n=2,565 1mm samples).