13 results on '"Liddy, Hannah M."'
Search Results
2. Miocene C4 Grassland Expansion as Recorded by the Indus Fan
- Author
-
Feakins, Sarah J, Liddy, Hannah M, Tauxe, Lisa, Galy, Valier, Feng, Xiaojuan, Tierney, Jessica E, Miao, Yunfa, and Warny, Sophie
- Subjects
Life Below Water ,International Ocean Discovery Program ,Expedition 355 ,Site U1457 ,Indus Fan ,biomarker - Published
- 2020
3. Large-scale mass wasting on the Miocene continental margin of western India
- Author
-
Dailey, Sarah K, Clift, Peter D, Kulhanek, Denise K, Blusztajn, Jerzy, Routledge, Claire M, Calvès, Gérôme, O’Sullivan, Paul, Jonell, Tara N, Pandey, Dhananjai K, Andò, Sergio, Coletti, Giovanni, Zhou, Peng, Li, Yuting, Neubeck, Nikki E, Bendle, James AP, Aharonovich, Sophia, Griffith, Elizabeth M, Gurumurthy, Gundiga P, Hahn, Annette, Iwai, Masao, Khim, Boo-Keun, Kumar, Anil, Kumar, A Ganesh, Liddy, Hannah M, Lu, Huayu, Lyle, Mitchell W, Mishra, Ravi, Radhakrishna, Tallavajhala, Saraswat, Rajeev, Saxena, Rakesh, Scardia, Giancarlo, Sharma, Girish K, Singh, Arun D, Steinke, Stephan, Suzuki, Kenta, Tauxe, Lisa, Tiwari, Manish, Xu, Zhaokai, and Yu, Zhaojie
- Subjects
Geochemistry ,Geology ,Geophysics - Abstract
Abstract A giant mass-transport complex was recently discovered in the eastern Arabian Sea, exceeding in volume all but one other known complex on passive margins worldwide. The complex, named the Nataraja Slide, was drilled by International Ocean Discovery Program (IODP) Expedition 355 in two locations where it is ∼300 m (Site U1456) and ∼200 m thick (Site U1457). The top of this mass-transport complex is defined by the presence of both reworked microfossil assemblages and deformation structures, such as folding and faulting. The deposit consists of two main phases of mass wasting, each consisting of smaller pulses, with generally fining-upward cycles, all emplaced just prior to 10.8 Ma based on biostratigraphy. The base of the deposit at each site is composed largely of matrix-supported carbonate breccia that is interpreted as the product of debris-flows. In the first phase, these breccias alternate with well-sorted calcarenites deposited from a high-energy current, coherent limestone blocks that are derived directly from the Indian continental margin, and a few clastic mudstone beds. In the second phase, at the top of the deposit, muddy turbidites dominate and become increasingly more siliciclastic. At Site U1456, where both phases are seen, a 20-m section of hemipelagic mudstone is present, overlain by a ∼40-m-thick section of calcarenite and slumped interbedded mud and siltstone. Bulk sediment geochemistry, heavy-mineral analysis, clay mineralogy, isotope geochemistry, and detrital zircon U-Pb ages constrain the provenance of the clastic, muddy material to being reworked, Indus-derived sediment, with input from western Indian rivers (e.g., Narmada and Tapti rivers), and some material from the Deccan Traps. The carbonate blocks found within the breccias are shallow-water limestones from the outer western Indian continental shelf, which was oversteepened from enhanced clastic sediment delivery during the mid-Miocene. The final emplacement of the material was likely related to seismicity as there are modern intraplate earthquakes close to the source of the slide. Although we hypothesize that this area is at low risk for future mass wasting events, it should be noted that other oversteepened continental margins around the world could be at risk for mass failure as large as the Nataraja Slide.
- Published
- 2020
4. Photosynthetic pathway of grass fossils from the upper Miocene Dove Spring Formation, Mojave Desert, California
- Author
-
Liddy, Hannah M, Feakins, Sarah J, Corsetti, Frank A, Sage, Rowan, Dengler, Nancy, Whistler, David P, Takeuchi, Gary T, Faull, Mark, and Wang, Xiaoming
- Subjects
C-3 ,C-4 ,Carbon isotopes ,Grassland ,Grass anatomy ,Geology ,Ecology ,Evolutionary Biology ,Paleontology - Abstract
The spread of grasslands in the Miocene and of C4 grasses in the late Miocene-Pliocene represents a major development in terrestrial plant evolution that affected the climate system and faunal evolution. The macrofossil record of grasses is sparse, likely due to the limited preservation potential of grasses. Diagnosis of the C3 or C4 photosynthetic pathway depends on preservation of both cellular structures and organic carbon for isotope analysis. Here we analyze the anatomical and isotopic composition of newly-collected grass fossils from the Dove Spring Formation, Red Rock Canyon State Park, California, USA, located in the El Paso Basin on the western side of the Basin and Range Province, a site previously identified as one of the earliest known C4 grass fossil bearing localities. We analyzed the anatomical and geochemical characteristics of these new grass fossils dated to 12.01–12.15 Ma. The fossils analyzed in this study include grass shoots and in cross-section display anatomy indicative of the C3 photosynthetic pathway. We isolated organic carbon from the stem fossils and determined the carbon isotopic composition to be − 24.8 ± 0.5‰. Together, the anatomical and geochemical analyses confirm that these plants used the C3 photosynthetic pathway. Our findings are consistent with dietary evidence based on tooth enamel from grazing mammals of available C3 resources in the same sections. These newly reported Miocene-age C3 grass fossils contribute to a sparse macrofossil record of grass evolution. Overall, paleoecological reconstructions at this site indicate more humid conditions during the Miocene compared to the modern Mojave Desert with C3 grasses and diverse grazing mammals.
- Published
- 2018
5. Photosynthetic pathway of grass fossils from the upper Miocene Dove Spring Formation, Mojave Desert, California
- Author
-
Liddy, Hannah M., Feakins, Sarah J., Corsetti, Frank A., Sage, Rowan, Dengler, Nancy, Whistler, David P., Takeuchi, Gary T., Faull, Mark, and Wang, Xiaoming
- Published
- 2018
- Full Text
- View/download PDF
6. The drivers and impacts of Amazon forest degradation
- Author
-
Lapola, David M., Pinho, Patricia, Barlow, Jos, Aragão, Luiz E. O. C., Berenguer, Erika, Carmenta, Rachel, Liddy, Hannah M., Seixas, Hugo, Silva, Camila V. J., Silva-Junior, Celso H. L., Alencar, Ane A. C., Anderson, Liana O., Armenteras, Dolors, Brovkin, Victor, Calders, Kim, Chambers, Jeffrey, Chini, Louise, Costa, Marcos H., Faria, Bruno L., Fearnside, Philip M., Ferreira, Joice, Gatti, Luciana, Gutierrez-Velez, Victor Hugo, Han, Zhangang, Hibbard, Kathleen, Koven, Charles, Lawrence, Peter, Pongratz, Julia, Portela, Bruno T. T., Rounsevell, Mark, Ruane, Alex C., Schaldach, Rüdiger, da Silva, Sonaira S., von Randow, Celso, Walker, Wayne S., Lapola, David M., Pinho, Patricia, Barlow, Jos, Aragão, Luiz E. O. C., Berenguer, Erika, Carmenta, Rachel, Liddy, Hannah M., Seixas, Hugo, Silva, Camila V. J., Silva-Junior, Celso H. L., Alencar, Ane A. C., Anderson, Liana O., Armenteras, Dolors, Brovkin, Victor, Calders, Kim, Chambers, Jeffrey, Chini, Louise, Costa, Marcos H., Faria, Bruno L., Fearnside, Philip M., Ferreira, Joice, Gatti, Luciana, Gutierrez-Velez, Victor Hugo, Han, Zhangang, Hibbard, Kathleen, Koven, Charles, Lawrence, Peter, Pongratz, Julia, Portela, Bruno T. T., Rounsevell, Mark, Ruane, Alex C., Schaldach, Rüdiger, da Silva, Sonaira S., von Randow, Celso, and Walker, Wayne S.
- Abstract
Approximately 2.5 × 10 6 square kilometers of the Amazon forest are currently degraded by fire, edge effects, timber extraction, and/or extreme drought, representing 38% of all remaining forests in the region. Carbon emissions from this degradation total up to 0.2 petagrams of carbon per year (Pg C year −1 ), which is equivalent to, if not greater than, the emissions from Amazon deforestation (0.06 to 0.21 Pg C year −1 ). Amazon forest degradation can reduce dry-season evapotranspiration by up to 34% and cause as much biodiversity loss as deforestation in human-modified landscapes, generating uneven socioeconomic burdens, mainly to forest dwellers. Projections indicate that degradation will remain a dominant source of carbon emissions independent of deforestation rates. Policies to tackle degradation should be integrated with efforts to curb deforestation and complemented with innovative measures addressing the disturbances that degrade the Amazon forest.
- Published
- 2023
7. The drivers and impacts of Amazon forest degradation
- Author
-
Lapola, David M., primary, Pinho, Patricia, additional, Barlow, Jos, additional, Aragão, Luiz E. O. C., additional, Berenguer, Erika, additional, Carmenta, Rachel, additional, Liddy, Hannah M., additional, Seixas, Hugo, additional, Silva, Camila V. J., additional, Silva-Junior, Celso H. L., additional, Alencar, Ane A. C., additional, Anderson, Liana O., additional, Armenteras, Dolors, additional, Brovkin, Victor, additional, Calders, Kim, additional, Chambers, Jeffrey, additional, Chini, Louise, additional, Costa, Marcos H., additional, Faria, Bruno L., additional, Fearnside, Philip M., additional, Ferreira, Joice, additional, Gatti, Luciana, additional, Gutierrez-Velez, Victor Hugo, additional, Han, Zhangang, additional, Hibbard, Kathleen, additional, Koven, Charles, additional, Lawrence, Peter, additional, Pongratz, Julia, additional, Portela, Bruno T. T., additional, Rounsevell, Mark, additional, Ruane, Alex C., additional, Schaldach, Rüdiger, additional, da Silva, Sonaira S., additional, von Randow, Celso, additional, and Walker, Wayne S., additional
- Published
- 2023
- Full Text
- View/download PDF
8. Large-scale mass wasting on the miocene continental margin of Western India
- Author
-
Dailey, S, Clift, P, Kulhanek, D, Blusztajn, J, Routledge, C, Calvès, G, O’Sullivan, P, Jonell, T, Pandey, D, Ando', S, Coletti, G, Zhou, P, Yuting, L, Neubeck, N, Bendle, J, Aharonovich, S, Griffith, E, Gurumurthy, G, Hahn, A, Iwai, M, Khim, B, Kumar, A, Liddy, H, Huayu, L, Lyle, M, Mishra, R, Radhakrishna, T, Saraswat, R, Saxena, R, Scardia, G, Sharma, G, Singh, A, Steinke, S, Suzuki, K, Tauxe, L, Tiwari, M, Zhaokai, X, Zhaojie, Y, Dailey, Sarah K., Clift, Peter D., Kulhanek, Denise K., Blusztajn, Jerzy, Routledge, Claire M., Calvès, Gérôme, O’Sullivan, Paul, Jonell, Tara N., Pandey, Dhananjai K., SERGIO, ANDO', Coletti, Giovanni, Zhou, Peng, Li, Yuting, Neubeck, Nikki E., Bendle, James A. P., Aharonovich, Sophia, Griffith, Elizabeth M., Gurumurthy, Gundiga P., Hahn, Annette, Iwai, Masao, Khim, Boo-Keun, Kumar, Anil, Kumar, A. Ganesh, Liddy, Hannah M., Lu, Huayu, Lyle, Mitchell W., Mishra, Ravi, Radhakrishna, Tallavajhala, Saraswat, Rajeev, Saxena, Rakesh, Scardia, Giancarlo, Sharma, Girish K., Singh, Arun D., Steinke, Stephan, Suzuki, Kenta, Tauxe, Lisa, Tiwari, Manish, Xu, Zhaokai, Yu, Zhaojie, Dailey, S, Clift, P, Kulhanek, D, Blusztajn, J, Routledge, C, Calvès, G, O’Sullivan, P, Jonell, T, Pandey, D, Ando', S, Coletti, G, Zhou, P, Yuting, L, Neubeck, N, Bendle, J, Aharonovich, S, Griffith, E, Gurumurthy, G, Hahn, A, Iwai, M, Khim, B, Kumar, A, Liddy, H, Huayu, L, Lyle, M, Mishra, R, Radhakrishna, T, Saraswat, R, Saxena, R, Scardia, G, Sharma, G, Singh, A, Steinke, S, Suzuki, K, Tauxe, L, Tiwari, M, Zhaokai, X, Zhaojie, Y, Dailey, Sarah K., Clift, Peter D., Kulhanek, Denise K., Blusztajn, Jerzy, Routledge, Claire M., Calvès, Gérôme, O’Sullivan, Paul, Jonell, Tara N., Pandey, Dhananjai K., SERGIO, ANDO', Coletti, Giovanni, Zhou, Peng, Li, Yuting, Neubeck, Nikki E., Bendle, James A. P., Aharonovich, Sophia, Griffith, Elizabeth M., Gurumurthy, Gundiga P., Hahn, Annette, Iwai, Masao, Khim, Boo-Keun, Kumar, Anil, Kumar, A. Ganesh, Liddy, Hannah M., Lu, Huayu, Lyle, Mitchell W., Mishra, Ravi, Radhakrishna, Tallavajhala, Saraswat, Rajeev, Saxena, Rakesh, Scardia, Giancarlo, Sharma, Girish K., Singh, Arun D., Steinke, Stephan, Suzuki, Kenta, Tauxe, Lisa, Tiwari, Manish, Xu, Zhaokai, and Yu, Zhaojie
- Abstract
A giant mass-transport complex was recently discovered in the eastern Arabian Sea, exceeding in volume all but one other known complex on passive margins worldwide. The complex, named the Nataraja Slide, was drilled by International Ocean Discovery Program (IODP) Expedition 355 in two locations where it is ~300 m (Site U1456) and ~200 m thick (Site U1457). The top of this mass-transport complex is defined by the presence of both reworked microfossil assemblages and deformation structures, such as folding and faulting. The deposit consists of two main phases of mass wasting, each consisting of smaller pulses, with generally fining-upward cycles, all emplaced just prior to 10.8 Ma based on biostratigraphy. The base of the deposit at each site is composed largely of matrix-supported carbonate breccia that is interpreted as the product of debris-flows. In the first phase, these breccias alternate with wellsorted calcarenites deposited from a high-energy current, coherent limestone blocks that are derived directly from the Indian continental margin, and a few clastic mudstone beds. In the second phase, at the top of the deposit, muddy turbidites dominate and become increasingly more siliciclastic. At Site U1456, where both phases are seen, a 20-m section of hemipelagic mudstone is present, overlain by a ~40-m-thick section of calcarenite and slumped interbedded mud and siltstone. Bulk sediment geochemistry, heavy-mineral analysis, clay mineralogy, isotope geochemistry, and detrital zircon U-Pb ages constrain the provenance of the clastic, muddy material to being reworked, Indus-derived sediment, with input from western Indian rivers (e.g., Narmada and Tapti rivers), and some material from the Deccan Traps. The carbonate blocks found within the breccias are shallow-water limestones from the outer western Indian continental shelf, which was oversteepened from enhanced clastic sediment delivery during the mid-Miocene. The final emplacement of the material was likely related
- Published
- 2020
9. Miocene C 4 Grassland Expansion as Recorded by the Indus Fan
- Author
-
Feakins, Sarah J., primary, Liddy, Hannah M., additional, Tauxe, Lisa, additional, Galy, Valier, additional, Feng, Xiaojuan, additional, Tierney, Jessica E., additional, Miao, Yunfa, additional, and Warny, Sophie, additional
- Published
- 2020
- Full Text
- View/download PDF
10. Large-scale mass wasting on the Miocene continental margin of western India
- Author
-
Dailey, Sarah K., primary, Clift, Peter D., additional, Kulhanek, Denise K., additional, Blusztajn, Jerzy, additional, Routledge, Claire M., additional, Calvès, Gérôme, additional, O’Sullivan, Paul, additional, Jonell, Tara N., additional, Pandey, Dhananjai K., additional, Andò, Sergio, additional, Coletti, Giovanni, additional, Zhou, Peng, additional, Li, Yuting, additional, Neubeck, Nikki E., additional, Bendle, James A.P., additional, Aharonovich, Sophia, additional, Griffith, Elizabeth M., additional, Gurumurthy, Gundiga P., additional, Hahn, Annette, additional, Iwai, Masao, additional, Khim, Boo-Keun, additional, Kumar, Anil, additional, Kumar, A. Ganesh, additional, Liddy, Hannah M., additional, Lu, Huayu, additional, Lyle, Mitchell W., additional, Mishra, Ravi, additional, Radhakrishna, Tallavajhala, additional, Saraswat, Rajeev, additional, Saxena, Rakesh, additional, Scardia, Giancarlo, additional, Sharma, Girish K., additional, Singh, Arun D., additional, Steinke, Stephan, additional, Suzuki, Kenta, additional, Tauxe, Lisa, additional, Tiwari, Manish, additional, Xu, Zhaokai, additional, and Yu, Zhaojie, additional
- Published
- 2019
- Full Text
- View/download PDF
11. Cooling and drying in northeast Africa across the Pliocene
- Author
-
Liddy, Hannah M., Feakins, Sarah J., and Tierney, Jessica E.
- Published
- 2016
- Full Text
- View/download PDF
12. Miocene C4 Grassland Expansion as Recorded by the Indus Fan.
- Author
-
Feakins, Sarah J., Liddy, Hannah M., Tauxe, Lisa, Galy, Valier, Feng, Xiaojuan, Tierney, Jessica E., Miao, Yunfa, and Warny, Sophie
- Subjects
GRASSLANDS ,OCEAN temperature ,SOIL washing ,RIVER sediments ,GRASSLAND soils ,CARBON isotopes ,SUBMARINE fans ,FOSSIL collection - Abstract
In the late Miocene, grasslands spread across the forested floodplains of the Himalayan foreland, but the causes of the ecological transition are still debated. Recent seafloor drilling by the International Ocean Discovery Program (IODP) provides an opportunity to study the transition across a larger region as archived in the Indus submarine fan. We present a multiproxy study of past vegetation change based on analyses of the carbon isotopic composition (δ13C) of bulk organic carbon, plant wax n‐alkanes and n‐alkanoic acids, and quantification of lignin phenols, charcoal, and pollen. We analyze the hydrogen isotopic composition (δD) of plant wax to reconstruct precipitation δD. We use the Branched and Isoprenoid Tetraether (BIT) index to diagnose shifts between terrestrial versus marine lipid inputs between turbidite and hemipelagic sediments. We reconstruct ocean temperatures using the TEX86 index only where marine lipids dominate. We find evidence for the late Miocene grassland expansion in both facies, confirming this was a regional ecosystem transformation. Turbidites contain dominantly terrestrial matter from the Indus catchment (D‐depleted plant wax), delivered via fluvial transport as shown by the presence of lignin. In contrast, hemipelagic sediments lack lignin and bear D‐enriched plant wax consistent with wind‐blown inputs from the Indian peninsula; these show a 7.4–7.2 Ma expansion of C4 grasslands on the Indian subcontinent. Within each facies, we find no clear change in δD values across the late Miocene C4 expansion, implying consistent distillation of rainfall by monsoon dynamics. Yet, a cooling in the Arabian Sea is coincident with the C4 expansion. Plain Language Summary: This project studied the mud and sand on the seafloor in the Indian Ocean, west of India and south of Pakistan. We drilled a core through the mud and focused on a section corresponding to 5.5 to 10 Ma. Much of the sand came from the Indus River, but when the river sediments went elsewhere, layers of chalky sediments formed from the shells of marine organisms. Those chalks contain the history of longer spans of time. In the sediments, we found molecular fossils from the waxy coating on plant leaves and the woody parts of plants as well as pollen and charcoal; these point to the types of plants that were growing on land whose remains were washed or blown out to sea. We also found molecular fossils of microbes that lived in the oceans, whose structures indicate ocean temperatures—although when soils washed out in large amounts, ocean temperature estimates are not available. The main finding is that grasses replaced forests across much of the Indian subcontinent and Indus catchment, accompanied by more grass fire and cooler ocean temperatures. Key Points: Multiproxy study of the Indus Fan organic matter reveals that terrestrial sources differ between turbidite and hemipelagic faciesCarbon isotopes, grass pollen, and charcoal indicate that C4 grasslands expanded between 7.4–7.2 Ma in hemipelagic faciesHydrogen isotopes in plant waxes differ between source regions but do not detect monsoon rainfall changes across the C4 grassland expansion [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
13. Northeast African vegetation change over 12 m.y.
- Author
-
Feakins, Sarah J., Levin, Naomi E., Liddy, Hannah M., Sieracki, Alexa, Eglinton, Timothy I., and Bonnefille, Raymonde
- Subjects
- *
GRASS research , *PHOTOSYNTHESIS , *MARINE sediments , *CARBON content of plants - Abstract
Intense debate surrounds the evolution of grasses using the C4 (Hatch-Slack) photosynthesis pathway and the emergence of African grasslands, often assumed to be one and the same. Here, we bring new insights with the combination of plant leaf wax carbon isotopic composition (δ13Cwax) and pollen data from marine sediments of the Gulf of Aden (northeast Africa), which show that C4 biomass increases were not necessarily associated with regional grassland expansion. We find broadly opposing trends toward more enriched δ13Cwax values and decreased grass pollen proportions between 12 and 1.4 Ma. This apparently contradictory evidence can be reconciled if a greater proportion of the Late Miocene northeast African landscape were covered by C3 grasses than previously thought, such that C4 grasses and shrubs replaced a C3 ecosystem including trees and productive grasslands. In addition, δ13Cwax and pollen both indicate that true rainforests were unlikely to have been extensive in northeast Africa at any time in the last 12 m.y., although seasonally dry forests were a significant component of the regional landscape since the Late Miocene. Here, we extend regionally integrative marine archives of terrestrial vegetation back to 12 Ma, and we evaluate them in the context of an updated compilation of pedogenic carbonate δ13C values from East African Rift strata. We identify two distinct phases of increasing C4 biomass between 11 and 9 Ma (with a reversal by 4.3 Ma) and then a re-expansion between 4.3 and 1.4 Ma; surprisingly, neither was associated with grassland expansion. [ABSTRACT FROM AUTHOR]
- Published
- 2013
- Full Text
- View/download PDF
Catalog
Discovery Service for Jio Institute Digital Library
For full access to our library's resources, please sign in.