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Benthic foraminiferal δ 18 O in the ocean's temperature‐salinity‐density field: Constraints on Ice Age thermohaline circulation

Zahn, Rainer ; Mix, Alan C.

American Geophysical Union (AGU) ; 1991

In: Paleoceanography Vol. 6, No. 1 ( 1991-02), p. 1-20

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In: Paleoceanography, American Geophysical Union (AGU), Vol. 6, No. 1 ( 1991-02), p. 1-20

Abstract: Benthic δ 18 O data from 95 core sites are used to infer possible temperature‐salinity (T‐S) fields of the Atlantic and Pacific oceans at the Last Glacial Maximum (LGM). A constraint of stable density stratification yields logically consistent scenarios for both T and S. The solutions are not unique but are useful as a thinking tool. Using GEOSECS data, we solve for the modem relationship between δ 18 O water (δ w ) and salinity in the deep sea: δ w (SMOW) = 1.529 * S ‐ 53.18. As a starting point, we assume that the slope of this equation applies to LGM conditions and predict δ 18 O calcite (δ c ) gradients in equilibrium with probable T‐S fields of LGM deep and bottom waters. Benthic foraminiferal δ 18 O data from the deep Pacific (2–4 km depth), and the bottom Atlantic ( 〉 4 km depth), are 0.1–0.2‰ lower than from the deep Atlantic (2–4 km depth) at the LGM. If the modern δ w ‐S slope applies, Atlantic deep and bottom waters were more dense than Pacific deep waters. This assumption would imply bottom waters both fresher (ΔS 〉 0.5) and colder (ΔT ∼3°C) than overlying deep waters, in conflict with other data, suggesting ice age deep water much colder than at present. It is also possible that the observed δ c gradients are an artifact of laboratory intercalibration. If Atlantic deep and bottom water δ c values were similar to deep Pacific values, this would be consistent with the hypothesis of a stronger southern ocean versus North Atlantic source for deep‐ocean ventilation at the LGM. Taking the observed gradients at face value, however, a solution could be that the LGM δ w ‐S slope in deep and bottom waters was higher than at present, conceivably because of a stronger contribution of salt to the deep ocean via more intense sea ice freezing. This would allow Pacific deep waters and Atlantic bottom waters to have a common source, again in the Antarctic. Both would be more dense than Atlantic deep waters, even though the deep waters were much colder than at present. To better constrain these inferences drawn from the spatial distribution of benthic δ 18 O, we must reduce scatter in the δ 18 O data with more high‐quality measurements in high sedimentation rate cores. This is especially true at bottom water sites. Also, we must intercalibrate mass spectrometers at different isotope laboratories more accurately, to insure our isotope data are compatible.

Type of Medium: Online Resource

ISSN: 0883-8305 , 1944-9186

URL: Article

DOI: 10.1029/90PA01882

Language: English

Publisher: American Geophysical Union (AGU)

Publication Date: 1991

detail.hit.zdb_id: 637876-6

detail.hit.zdb_id: 2015231-0

detail.hit.zdb_id: 2916554-4

SSG: 16,13

SSG: 13

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Nonlinear response in the global climate system: Evidence from benthic oxygen isotopic record in core RC13‐110

Pisias, Nicklas G. ; Mix, Alan C. ; Zahn, Rainer

American Geophysical Union (AGU) ; 1990

In: Paleoceanography Vol. 5, No. 2 ( 1990-04), p. 147-160

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In: Paleoceanography, American Geophysical Union (AGU), Vol. 5, No. 2 ( 1990-04), p. 147-160

Abstract: The Milankovitch theory of climate change predicts that variations of the climate system should match the dominant frequencies of the orbital forcing in the 41 and 23 kyr −1 frequency bands. Such a linear theory would predict that the amplitude variations of the climate response in these bands should match amplitude variations in orbital forcing. Here we compare amplitude variations of the marine oxygen isotope record with orbital forcing in these bands over the last 700,000 years and find systematic changes through time. We express these amplitude mismatches as variations in the glacial response time, a measure of the climate system's sensitivity to orbitally induced insolation changes. Variations in the glacial response time occur in all frequencies bands without strong concentration of variance in any given band, and have a “red” spectrum with larger variations at the longer periods. The response time is coherent with δ 18 O at periods of 100 and 41 kyr, which suggests that the variations in glacial response time in part reflect internal feedback mechanisms of the global climate system. The phase relationship between the estimated glacial response time and the δ 18 O (ice volume) record is very different at these two frequencies, which suggests at least two separate feedback mechanisms. The first mechanism enhances the 100,000‐year climate cycle by increasing rates of change during major glacial terminations. Candidates for this feedback include lithospheric depression and rebound, enhanced ice calving from large marine based ice sheets, and possibly others. A second set of mechanisms, which is detected in the response to the 41,000‐year orbital cycle of Earth's obliquity, accelerates ice growth events and slows glacial melting. Some models which include feedbacks between ice sheets, sea ice, and deep ocean temperatures predict early rapid ice growth, followed by slower growth, and this general feature is consistent with our analysis. While we can not at present identify the specific feedbacks leading to asymmetry of growth and decay rates at different frequency bands, the finding of this ice‐growth acceleration mechanism in the 41,000‐year frequency band suggests that high‐latitude processes, where insolation varies most strongly at this rhythm, may be involved. Our finding of systematic changes in climate sensitivity has implications for orbitally tuned chronologies in Pleistocene sediments. Instead of a constant phase shift within a frequency band between orbital forcing and glacial response, as has been assumed in the past, we suggest a variable phase. The largest changes in age estimates for isotopic events are at the glacial terminations, which in our chronology are as much as 3500 years older that estimated previously.

Type of Medium: Online Resource

ISSN: 0883-8305 , 1944-9186

URL: Article

DOI: 10.1029/PA005i002p00147

Language: English

Publisher: American Geophysical Union (AGU)

Publication Date: 1990

detail.hit.zdb_id: 637876-6

detail.hit.zdb_id: 2015231-0

detail.hit.zdb_id: 2916554-4

SSG: 16,13

SSG: 13

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Water Mass Conversion in the Glacial Subarctic Pacific (54°N, 148°W): Physical Constraints and the Benthic‐Planktonic Stable Isotope Record

Zahn, Rainer ; Pedersen, Thomas F. ; Bornhold, Brian D. ; [et al.]

American Geophysical Union (AGU) ; 1991

In: Paleoceanography Vol. 6, No. 5 ( 1991-10), p. 543-560

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In: Paleoceanography, American Geophysical Union (AGU), Vol. 6, No. 5 ( 1991-10), p. 543-560

Abstract: Benthic ( Uvigerina spp., Cibicidoides spp., Gyroidinoides spp.) and planktonic ( N. pachyderma sinistral, G. bulloides ) stable isotope records from three core sites in the central Gulf of Alaska are used to infer mixed‐layer and deepwater properties of the late glacial Subarctic Pacific. Glacial‐interglacial amplitudes of the planktonic δ 18 O records are 1.1–1.3‰, less than half the amplitude observed at core sites at similar latitudes in the North Atlantic; these data imply that a strong, negative δ w anomaly existed in the glacial Subarctic mixed layer during the summer, which points to a much stronger low‐salinity anomaly than exists today. If true, the upper water column in the North Pacific would have been statically more stable than today, thus suppressing convection even more efficiently. This scenario is further supported by vertical (i.e., planktic versus benthic) δ 18 O and δ 13 C gradients of 〉 1‰, which suggest that a thermohaline link between Pacific deep waters and the Subarctic Pacific mixed layer did not exist during the late glacial. Epibenthic δ 13 C in the Subarctic Pacific is more negative than at tropical‐subtropical Pacific sites but similar to that recorded at Southern Ocean sites, suggesting ventilation of the deep central Pacific from mid‐latitude sources, e.g., from the Sea of Japan and Sea of Okhotsk. Still, convection to intermediate depths could have occurred in the Subarctic during the winter months when heat loss to the atmosphere, sea ice formation, and wind‐driven upwelling of saline deep waters would have been most intense. This would be beyond the grasp of our planktonic records which only document mixed‐layer temperature‐salinity fields extant during the warmer seasons. Also we do not have benthic isotope records from true intermediate water depths of the Subarctic Pacific.

Type of Medium: Online Resource

ISSN: 0883-8305 , 1944-9186

URL: Article

DOI: 10.1029/91PA01327

Language: English

Publisher: American Geophysical Union (AGU)

Publication Date: 1991

detail.hit.zdb_id: 637876-6

detail.hit.zdb_id: 2015231-0

detail.hit.zdb_id: 2916554-4

SSG: 16,13

SSG: 13

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