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123 results on '"Jordan, R. W."'

1. Predicting trends in atmospheric CO2 across the Mid-Pleistocene Transition using existing climate archives.

Author

Martin, Jordan R. W., Pedro, Joel B., and Vance, Tessa R.

Subjects
ATMOSPHERIC carbon dioxide, ICE cores, INTERGLACIALS, EARTH sciences, GLACIAL Epoch, CRYOSPHERE
Abstract

During the Mid-Pleistocene Transition (MPT), ca. 1200–800 000 years ago (ka), the Earth's glacial cycles changed from 41 to 100 kyr periodicity. The emergence of this longer ice age periodicity was accompanied by higher global ice volume in glacial periods and lower global ice volume in interglacial periods. Since there is no known change in external orbital forcing across the MPT, it is generally agreed that the cause of this transition is internal to the Earth system. Resolving the climate, carbon cycle, and cryosphere processes responsible for the MPT remains a major challenge in Earth and palaeoclimate science. To address this challenge, the international ice core community has prioritised recovery of an ice core record spanning the MPT interval. Here we present results from a simple generalised least-squares (GLS) model that predicts atmospheric CO2 out to 1.8 Myr. Our prediction utilises existing records of atmospheric carbon dioxide (CO2) from Antarctic ice cores spanning the past 800 kyr along with the existing LR04 benthic δ18Ocalcite stack (Lisiecki and Raymo, 2005; hereafter "benthic δ18O stack") from marine sediment cores. Our predictions assume that the relationship between CO2 and benthic δ18O over the past 800 000 years can be extended over the last 1.5 million years. The implicit null hypothesis is that there has been no fundamental change in feedbacks between atmospheric CO2 and the climate parameters represented by benthic δ18O , global ice volume, and ocean temperature. We test the GLS-model-predicted CO2 concentrations against observed blue ice CO2 concentrations, δ11B -based CO2 reconstructions from marine sediment cores, and δ13C of leaf-wax-based CO2 reconstructions (Higgins et al., 2015; Yan et al., 2019; Yamamoto et al., 2022). We show that there is no clear evidence from the existing blue ice or proxy CO2 data to reject our predictions or our associated null hypothesis. A definitive test and/or rejection of the null hypothesis may be provided following recovery and analysis of continuous oldest ice core records from Antarctica, which are still several years away. The record presented here should provide a useful comparison for the oldest ice core records and an opportunity for further constraints on the processes involved in the MPT. [ABSTRACT FROM AUTHOR]

Published
2024
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4. WHAT CAN ICE IN ANTARCTICA TELL US ABOUT EARTH'S PAST CLIMATE?

Author

Crockart, Camilla K., Harlan, Margaret, Martin, Jordan R. W., and Bertler, Nancy

Subjects
ICE, ATMOSPHERIC carbon dioxide, ENVIRONMENTAL sciences, ICE cores, DEEP-sea exploration
Abstract

Antarctica is the coldest, driest, highest, and windiest continent, and it is home to 70 research stations from 29 countries. Antarctica is a remote and harsh place, without many weather stations or people. This means scientists must come up with creative ways to learn about the continent's past climate. Scientists use sediment that builds up on the ocean floor to explore what Earth was like more than a million years ago; and they use satellites to learn about today's climate. But how can we know what happened in the time between? This is where ice can help! When snow falls in Antarctica, it builds up in layers that get squeezed into ice. These layers hold traces of the past climate. The ice in Antarctica is the oldest anywhere in the world. Hundreds of thousands of years ago until now. These studies help us to better understand the past climate and to predict the future climate. [ABSTRACT FROM AUTHOR]

Published
2023
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5. Predicting trends in atmospheric CO2 across the Mid-Pleistocene Transition using existing climate archives

Author

Jordan R. W. Martin, Joel Pedro, and Tessa R. Vance

Abstract

During the Mid-Pleistocene Transition (MPT), ca. 1250–800 kya, the Earth’s glacial cycles changed from 41 ky to 100 ky periodicity. The emergence of this longer ice-age periodicity was accompanied by higher global ice volume in glacial periods and lower global ice volume in interglacial periods. Since there is no known change in external orbital forcing across the MPT, it is generally agreed that the cause of this transition is internal to the earth system. Resolving the climate–carbon cycle–cryosphere dynamics processes responsible for the MPT remains a major challenge in ice core and climate science. To address this challenge, the international ice core community has prioritized recovery of an ice core record spanning the MPT interval. The results from such ‘oldest ice’ projects are still several years away. Our objective here it to make an advanced prediction of atmospheric CO2 out to 1.5 my. Our prediction utilizes existing records of atmospheric carbon dioxide (CO2) from Antarctic ice cores spanning the past 800 ky along with the existing benthic water stable isotope (ẟ18O) record from marine sediment cores. Our predictions assume that the relationship between CO2 and benthic ẟ18O over the past 800 thousand years can be extended over the last one and a half million years. The implied null hypothesis is that there has been no fundamental change in the global climate–carbon cycle–cryosphere feedback systems across the MPT. We find that our predicted CO2 record is significantly lower during glacial intervals than the existing blue-ice and boron isotope-based estimates of CO2 that pre-date the continuous 800 ky CO2 record. Our predicted glacial CO2 concentrations are ~9 ppm below glacial CO2 concentrations observed in blue ice data at ca. 1 mya and ~19 ppm below glacial CO2 concentrations reconstructed from boron isotopic data over ca ~1.1–1.25 mya. These results support rejection of our null hypothesis and provide quantitative evidence of a fundamental shift in the global climate–carbon cycle–cryosphere feedback systems across the MPT. However, the definitive test of the various theories explaining the MPT will be comparison of our predicted records with the forthcoming oldest ice core records.

Published
2022
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12. Predicting trends in atmospheric CO2 across the Mid-Pleistocene Transition using existing climate archives.

Author

Martin, Jordan R. W., Pedro, Joel, and Vance, Tessa R.

Subjects
CARBON dioxide, CLIMATE change, EARTH system science, NULL hypothesis, STABLE isotopes
Abstract

During the Mid-Pleistocene Transition (MPT), ca. 1250–800 kya, the Earth's glacial cycles changed from 41 ky to 100 ky periodicity. The emergence of this longer ice-age periodicity was accompanied by higher global ice volume in glacial periods and lower global ice volume in interglacial periods. Since there is no known change in external orbital forcing across the MPT, it is generally agreed that the cause of this transition is internal to the earth system. Resolving the climate–carbon cycle–cryosphere dynamics processes responsible for the MPT remains a major challenge in ice core and climate science. To address this challenge, the international ice core community has prioritized recovery of an ice core record spanning the MPT interval. The results from such 'oldest ice' projects are still several years away. Our objective here it to make an advanced prediction of atmospheric CO2 out to 1.5 my. Our prediction utilizes existing records of atmospheric carbon dioxide (CO2) from Antarctic ice cores spanning the past 800 ky along with the existing benthic water stable isotope (ẟ18O) record from marine sediment cores. Our predictions assume that the relationship between CO2 and benthic ẟ18O over the past 800 thousand years can be extended over the last one and a half million years. The implied null hypothesis is that there has been no fundamental change in the global climate–carbon cycle–cryosphere feedback systems across the MPT. We find that our predicted CO2 record is significantly lower during glacial intervals than the existing blue-ice and boron isotope-based estimates of CO2 that pre-date the continuous 800 ky CO2 record. Our predicted glacial CO2 concentrations are ~9 ppm below glacial CO2 concentrations observed in blue ice data at ca. 1 mya and ~19 ppm below glacial CO2 concentrations reconstructed from boron isotopic data over ca ~1.1–1.25 mya. These results support rejection of our null hypothesis and provide quantitative evidence of a fundamental shift in the global climate–carbon cycle–cryosphere feedback systems across the MPT. However, the definitive test of the various theories explaining the MPT will be comparison of our predicted records with the forthcoming oldest ice core records. [ABSTRACT FROM AUTHOR]

Published
2022
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15. Editorial-Special issue: Nannos as (paleo) indices

Author

Triantaphyllou, M, Malinverno, E, Jordan, R, Triantaphyllou M. V., Malinverno E., Jordan R. W., Triantaphyllou, M, Malinverno, E, Jordan, R, Triantaphyllou M. V., Malinverno E., and Jordan R. W.

Published
2019

22. Quantitative comparison of taxa and taxon concepts in the diatom genus Fragilariopsis: a case study on using slide scanning, multiexpert image annotation, and image analysis in taxonomy

Author

Beszteri, Bank, Allen, Claire, Almandoz, Gastón O., Armand, L., Barcena, M. A., Cantzler, Hannelore, Crosta, Xavier, Esper, Oliver, Jordan, R. W., Kauer, Gerhard, Klaas, Christine, Kloster, Michael, Leventer, Amy, Pike, J., Rigual Hernández, Andres S., Beszteri, Bank, Allen, Claire, Almandoz, Gastón O., Armand, L., Barcena, M. A., Cantzler, Hannelore, Crosta, Xavier, Esper, Oliver, Jordan, R. W., Kauer, Gerhard, Klaas, Christine, Kloster, Michael, Leventer, Amy, Pike, J., and Rigual Hernández, Andres S.

Abstract

Semiautomated methods for microscopic image acquisition, image analysis, and taxonomic identification have repeatedly received attention in diatom analysis. Less well studied is the question whether and how such methods might prove useful for clarifying the delimitation of species that are difficult to separate for human taxonomists. To try to answer this question, three very similar Fragilariopsis species endemic to the Southern Ocean were targeted in this study: F. obliquecostata, F. ritscheri, and F. sublinearis. A set of 501 extended focus depth specimen images were obtained using a standardized, semiautomated microscopic procedure. Twelve diatomists independently identified these specimen images in order to reconcile taxonomic opinions and agree upon a taxonomic gold standard. Using image analyses, we then extracted morphometric features representing taxonomic characters of the target taxa. The discriminating ability of individual morphometric features was tested visually and statistically, and multivariate classification experiments were performed to test the agreement of the quantitatively defined taxa assignments with expert consensus opinion. Beyond an updated differential diagnosis of the studied taxa, our study also shows that automated imaging and image analysis procedures for diatoms are coming close to reaching a broad applicability for routine use.

Published
2018

30. Sites M0001-M0004

Author

Backman, J., Moran, K., McInroy, D., Brinkhuis, H., Clemens, S., Cronin, T., Dickens, G. R., Eynaud, F., Gattacceca, J., Jakobsson, M., Jordan, R. W., Kaminski, M., King, J., Koç, N., Martinez, N. C., Matthiessen, J., Moore Jr, T. C., Onodera, J., O Regan, M., Pälike, H., Rea, B., Rio, D., Sakamoto, T., Smith, D. C., Stein, R., St John, K. E. K., Suto, I., Suzuki, N., Takahashi, K., Watanabe, M., and Yamamoto, M.

Published
2006

31. Sedimentation and subsidence history of the Lomonosov Ridge

Author

Moore, T. C., Backman, J., Moran, K., McInroy, D., Brinkhuis, H., Clemens, S., Cronin, T., Dickens, G. R., Eynaud, F., Gattacceca, J., Jakobsson, M., Jordan, R. W., Kaminski, M., King, J., Koç, N., Martinez, N. C., Matthiessen, J., Moore Jr, T. C., Onodera, J., O Regan, M., Pälike, H., Rea, B., Rio, D., Sakamoto, T., Smith, D. C., Stein, R., St John, K. E. K., Suto, I., Suzuki, N., Takahashi, K., Watanabe, M., and Yamamoto, M.

Published
2006

32. Expedition 302 geophysics: integrating past data with new results

Author

Jakobsson, M., Floden, T., Backman, J., Moran, K., McInroy, D., Brinkhuis, H., Clemens, S., Cronin, T., Dickens, G. R., Eynaud, F., Gattacceca, J., Jordan, R. W., Kaminski, M., King, J., Koç, N., Martinez, N. C., Matthiessen, J., Moore Jr, T. C., Onodera, J., O Regan, M., Pälike, H., Rea, B., Rio, D., Sakamoto, T., Smith, D. C., Stein, R., St John, K. E. K., Suto, I., Suzuki, N., Takahashi, K., Watanabe, M., and Yamamoto, M.

Published
2006

36. Morphological adaptation of a planktonic diatom to growth in Antarctic sea ice.

Author

Ligowski, R., Jordan, R. W., Assmy, Philipp, Ligowski, R., Jordan, R. W., and Assmy, Philipp

Abstract

Chaetoceros dichaeta Ehrenberg is one of the most important planktonic diatom species in the Southern Ocean, making a significant contribution to the total biomass in the region. Our observations on both field and culture material have revealed the existence of a specialized form of C. dichaeta adapted to living in sea ice. This sea ice form differs from the planktonic form by the shape and orientation of the setae and the aperture length between sibling cells. Thus, the diameter of the chain is equivalent to the apical axes of the cells and is accompanied by a two order of magnitude decrease in minimal space requirement. Here, we report for the first time on the extraordinary overwintering strategy of a planktonic diatom in sea ice facilitated by its rapid morphological adaptation to changing environmental conditions. This morphological plasticity enables it to thrive in the confined space of the sea ice brine matrix and retain its numerical dominance in recurrent growing seasons and has likely evolved to optimally exploit the dynamic ecosystem of the seasonally ice-covered seas of the Southern Ocean.

Published
2012

37. The Cenozoic palaeoenvironment of the Arctic Ocean

Author

Moran, K., Backman, J., Brinkhuis, H., Clemens, S. C., Cronin, T., Dickens, G. R., Eynaud, F., Gattacceca, J., Jakobsson, M., Jordan, R. W., Kaminski, M., King, J., Koc, N., Krylov, A., Martinez, N., Matthießen, Jens, McInroy, D., Moore, T. C., Onodera, J., O'Regan, A. M., Pälike, H., Rea, B., Rio, D., Sakamoto, T., Smith, D. C., Stein, Rüdiger, St. John, K., Suto, I., Suzuki, N., Takahashi, K., Watanabe, M., Yamamoto, M., Frank, M., Jokat, Wilfried, Kristoffersen, Y., Moran, K., Backman, J., Brinkhuis, H., Clemens, S. C., Cronin, T., Dickens, G. R., Eynaud, F., Gattacceca, J., Jakobsson, M., Jordan, R. W., Kaminski, M., King, J., Koc, N., Krylov, A., Martinez, N., Matthießen, Jens, McInroy, D., Moore, T. C., Onodera, J., O'Regan, A. M., Pälike, H., Rea, B., Rio, D., Sakamoto, T., Smith, D. C., Stein, Rüdiger, St. John, K., Suto, I., Suzuki, N., Takahashi, K., Watanabe, M., Yamamoto, M., Frank, M., Jokat, Wilfried, and Kristoffersen, Y.

Abstract

The Cenozoic history (0 to 65 million years, Myr, ago) of the Arctic Ocean is largely unknown from direct evidence. Here we present the first Cenozoic palaeoceanographic record constructed from > 400 m of core from a recent drilling expedition to the Lomonosov Ridge. Our record shows a palaeoenvironmental transition from a warm greenhouse world, of the latest Palaeocene and early Eocene, to an icehouse world influenced by sea ice and icebergs from the middle Eocene to the present. We show: 1-2 cm per thousand years (ka) sedimentation rates occurred from the middle Miocene - Holocene (~18-0 Myr) in stark contrast to rates proposed in earlier studies; the first occurrence of ice-rafted debris (IRD) is in the middle Eocene (~45 Myr), ~35 Myr earlier than previously thought; prior to the IRD, fresh surface waters were present at ~49 Myr; and warm surface waters, ~10° warmer than previous estimates, occurred during the Palaeocene Eocene Thermal Maximum (PETM). The revised timing of Arctic cooling events coincides with those from Antarctica, supporting arguments for bi-polar symmetry in climate change.

Published
2006

41. Taxon lists for studies of modern nannoplankton

Author

Jordan, R. W., Broerse, A. T. C., Hagino, K., Kinkel, H., Sprengel, Claudia, Takahashi, K., Young, J. R., Jordan, R. W., Broerse, A. T. C., Hagino, K., Kinkel, H., Sprengel, Claudia, Takahashi, K., and Young, J. R.

Abstract

Six studies in this special issue dealt with modern nannoplankton assemblages. In total during these studies 552 samples were analysed and about 180,000 specimens identified, from 152 species. This paper provides a unified list of taxa from these studies, records the present/absence of each species across the studies and indicates the more common species. Comparison of results indicates a high level of consensus on taxonomy and a high commonality of the floras.

Published
2000

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