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Insights from geodynamic models into ice flow, mantle magmatism, and their interactions (2022)

Clerc, Fiona

Massachusetts Institute of Technology and Woods Hole Oceanographic Institution

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Publication Date: 2023-01-18

Description: Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at the Massachusetts Institute of Technology and the Woods Hole Oceanographic Institution February 2023.

Description: In this thesis, I use geodynamic models to study processes within the Earth’s mantle and cryosphere. I begin by quantifying previously unconsidered sources of magmatic CO2. In Chapter 2, I predict how small concentrations of CO2 found in passively upwelling mantle throughout ocean basins may generate low-degree carbonate melting. I find the flux of CO2 segregated by these melts rivals the flux from mid-ocean ridges. In Chapter 3, I model how the deglaciation of the Yellowstone ice cap caused a reduction in mantle pressures and enhanced melting 19-fold. I predict the additional melting segregates a globally-significant mass of CO2, potentially playing a role in positive feedbacks between deglaciation and climate. I suggest enhanced melting may be important in other magmatically-active, continental settings undergoing rapid deglaciation — for instance, under the collapse of the West Antarctic Ice Sheet (WAIS). This thesis next explores glaciological factors controlling WAIS stability, associated with the fracturing of ice sheet margins supported by floating ice shelves. The Marine Ice Cliff Instability posits ice cliffs above a critical height collapse under their own weight, initiating runaway ice sheet retreat. In Chapter 4, I model the formation of marine ice cliffs, as an Antarctic ice shelf is removed. I show that over ice-shelf collapse timescales longer than a few days (consistent with observations), ice cliffs comprised of intact ice are more stable, undergoing viscous flow rather than brittle fracture. I next investigate interactions between viscous and brittle processes, guided by observations on a modern Antarctic ice shelf. In Chapter 5, I model deformation at the McDonald Ice Rumples (MIR), formed as the Brunt Ice Shelf is grounded into a bathymetric high. The MIR are characterized by concentric folds intersected by radial fractures, implying viscous and brittle behavior, respectively. I interpret these features to constrain ice rheology and strength. More broadly, this final chapter highlights how leveraging glaciological observations as natural experiments places constraints on the phenomenological laws which govern ice and (analogously) mantle flow. In summary, jointly developing models of both ice and mantle flow better constrains the dynamics of each system (solid Earth and cryosphere) and their interactions.

Description: I was funded by an NSF Graduate Research Fellowship, WHOI’s Karen L. Von Damm Fellowship, and NSFGEO-NERC grant 1853918.

Keywords: Solid Earth ; Cryosphere

Repository Name: Woods Hole Open Access Server

Type: Thesis

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Causes of oceanic crustal thickness oscillations along a 74-Myr Mid-Atlantic Ridge flow line (2019)

Shinevar, William J. ; Mark, Hannah F. ; Clerc, Fiona ; [et al.]

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Publication Date: 2022-05-26

Description: These data sets collected geophysical data: multi-beam bathymetry, gravity, magnetics, sub-bottom profile to investigate the relationships between faulting, magmatism, and sea level change.

Description: Gravity, magnetic, and bathymetry data collected along a continuous 1400-km-long spreading-parallel flow line across the Mid-Atlantic Ridge indicate significant tectonic and magmatic fluctuations in the formation of oceanic crust over a range of timescales. The transect spans from 28 Ma on the African Plate to 74 Ma on the North American plate, crossing the Mid-Atlantic Ridge at 35.8 ºN. Gravity-derived crustal thicknesses vary from 3–9 km with a standard deviation of 1 km. Spectral analysis of bathymetry and residual mantle Bouguer anomaly (RMBA) show diffuse power at 〉1 Myr and concurrent peaks at 390, 550, and 950 kyr. Large-scale (〉10-km) mantle thermal and compositional heterogeneities, variations in upper mantle flow, and detachment faulting likely generate the 〉1 Myr diffuse power. The 550- and 950-kyr peaks may reflect the presence of magma solitons and/or regularly spaced ~7.7 and 13.3 km short-wavelength mantle compositional heterogeneities. The 390-kyr spectral peak corresponds to the characteristic spacing of faults along the flow line. Fault spacing also varies over longer periods (〉10 Myr), which we interpret as reflecting long-lived changes in the fraction of tectonically- vs. magmatically- accommodated extensional strain. A newly discovered off-axis oceanic core complex (Kafka Dome) found at 8 Ma on the African plate further suggests extended time periods of tectonically dominated plate separation. Fault spacing negatively correlates with gravity-derived crustal thickness, supporting a strong link between magma input and fault style at mid-ocean ridges.

Repository Name: Woods Hole Open Access Server

Type: Dataset

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Causes of oceanic crustal thickness oscillations along a 74-M Mid-Atlantic ridge flow line (2020)

Shinevar, William J. ; Mark, Hannah F. ; Clerc, Fiona ; [et al.]

American Geophysical Union

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Publication Date: 2022-10-20

Description: Author Posting. © American Geophysical Union, 2019. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Geochemistry, Geophysics, Geosystems 20, (2019): 6123-6139, doi: 10.1029/2019GC008711.

Description: Gravity, magnetic, and bathymetry data collected along a continuous 1,400‐km‐long spreading‐parallel flow line across the Mid‐Atlantic Ridge indicate significant tectonic and magmatic fluctuations in the formation of oceanic crust over a range of time scales. The transect spans from 28 Ma on the African Plate to 74 Ma on the North American plate, crossing the Mid‐Atlantic Ridge at 35.8°N. Gravity‐derived crustal thicknesses vary from 3–9 km with a standard deviation of 1.0 km. Spectral analysis of bathymetry and residual mantle Bouguer anomaly show a diffuse power at 〉1 Myr and concurrent peaks at 390, 550, and 950 kyr. Large‐scale (〉10 km) mantle thermal and compositional heterogeneities, variations in upper mantle flow, and detachment faulting likely generate the 〉1 Myr diffuse power. The 550‐ and 950‐kyr peaks may reflect the presence of magma solitons and/or regularly spaced ~7.7 and 13.3 km short‐wavelength mantle compositional heterogeneities. The 390‐kyr spectral peak corresponds to the characteristic spacing of faults along the flow line. Fault spacing also varies over longer periods (〉10 Myr), which we interpret as reflecting long‐lived changes in the fraction of tectonically versus magmatically accommodated extensional strain. A newly discovered off‐axis oceanic core complex (Kafka Dome) found at 8 Ma on the African plate further suggests extended time periods of tectonically‐dominated plate separation. Fault spacing negatively correlates with gravity‐derived crustal thickness, supporting a strong link between magma input and fault style at mid‐ocean ridges.

Description: Data and supplemental materials are available at the Woods Hole Open Access Server (doi.org/10.26025/1912/24796). We would like to thank the Woods Hole Oceanographic Institution, National Science Foundation, Naval Oceanographic Office, and the captain and crew of R/V Neil Armstrong for making the SCARF cruise possible. We would also like to thank Eboné Pierce for her help during the cruise. We thank Meghan Jones for advice using MBSystem. We also thank Maurice Tivey, John Greene, and Masako Tominaga for advice on processing the magnetic data sets. We would like to thank Peter Huybers for sharing his spectral analysis codes. We would like to thank Rob Sohn for his help on interpreting the spectral analysis. We would like to thank Del Bohnenstiel, Milena Marjanović, one anonymous reviewer, and Editor Thorsten Becker for their very helpful comments that improved this manuscript. Funding was provided for this research by NSF OCE‐14‐58201.

Description: 2020-05-19

Keywords: Ocean crustal thickness ; Faulting style ; Mid‐Atlantic Ridge ; Spectral analysis ; Oceanic core complex ; Magma input variation

Repository Name: Woods Hole Open Access Server

Type: Article

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Marine ice cliff instability mitigated by slow removal of ice shelves (2020)

Clerc, Fiona ; Minchew, Brent M. ; Behn, Mark D.

American Geophysical Union

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Publication Date: 2022-10-26

Description: Author Posting. © American Geophysical Union, 2019. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Geophysical Research Letters 46, (2019): 12108-12116, doi: 10.1029/2019GL084183.

Description: The accelerated calving of ice shelves buttressing the Antarctic Ice Sheet may form unstable ice cliffs. The marine ice cliff instability hypothesis posits that cliffs taller than a critical height (~90 m) will undergo structural collapse, initiating runaway retreat in ice‐sheet models. This critical height is based on inferences from preexisting, static ice cliffs. Here we show how the critical height increases with the timescale of ice‐shelf collapse. We model failure mechanisms within an ice cliff deforming after removal of ice‐shelf buttressing stresses. If removal occurs rapidly, the cliff deforms primarily elastically and fails through tensile‐brittle fracture, even at relatively small cliff heights. As the ice‐shelf removal timescale increases, viscous relaxation dominates, and the critical height increases to ~540 m for timescales greater than days. A 90‐m critical height implies ice‐shelf removal in under an hour. Incorporation of ice‐shelf collapse timescales in prognostic ice‐sheet models will mitigate the marine ice cliff instability, implying less ice mass loss.

Description: We thank Greg Hirth, Brad Hager, and Bill Durham for their useful comments. The manuscript benefited from constructive reviews by Dan Martin and an anonymous reviewer and editorial handling by Mathieu Morlighem. This work was supported by an NSF‐GRFP (Fiona Clerc), and NSF Awards OPP‐1739031 (Brent Minchew) and EAR‐19‐03897 (Mark Behn). Code reproducing our results is found at this address (https://doi.org/10.5281/zenodo.3379074).

Description: 2020-04-21

Keywords: Marine ice cliff ; Buttressing ice shelf ; Antarctic Ice Sheet ; Ice‐shelf collapse ; Brittle‐ductile transition ; Marine ice cliff instability

Repository Name: Woods Hole Open Access Server

Type: Article

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Predicting Rates and Distribution of Carbonate Melting in Oceanic Upper Mantle: Implications for Seismic Structure and Global Carbon Cycling (2018)

Clerc, Fiona ; Behn, Mark D. ; Parmentier, E. M. ; [et al.]

American Geophysical Union

In: Geophysical Research Letters. 2018; 45(14): 6944-6953. Published 2018 Jul 28. doi: 10.1029/2018gl078142.

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Publication Date: 2018-07-28

Description: Coupling a global mantle flow model with a parameterized carbonate solidus, we examine the global distribution and extent of carbonate melting beneath the ocean basins. We predict carbonate melting in spatially heterogeneous patterns throughout the oceans. The rate of CO2 segregation from the mantle by off-axis carbonate melting (~1.1 × 1012 mol/year) is comparable to the global ridge flux (~1.2 × 1012 mol/year). As the generation of carbonate melts should be enhanced in regions of mantle upwelling, we compare upwelling patterns with seismic detections of the G-discontinuity. The upwelling velocities in areas where the G-discontinuity is detected are not statistically different from areas with no detections—implying that the generation and pooling of carbonate melts are not dominant mechanisms in forming the G-discontinuity. However, detections of a deeper seismic discontinuity are correlated with enhanced upwelling velocities, suggesting locally higher melt fractions at the transition between carbonate-only and carbonate-enhanced silicate melting. ©2018. American Geophysical Union. All Rights Reserved.

Print ISSN: 0094-8276

Electronic ISSN: 1944-8007

Topics: Geosciences , Physics