Boundary condition controls on the high sand flux regions of Mars

Slides:

Advertisements

Similar presentations

Predicting Martian Dune Characteristics Using Global and Mesoscale MarsWRF Output Claire Newman working with Nick Lancaster, Dave Rubin and Mark Richardson.

Advertisements

Key Question How do you make a topographical map from a 3-dimensional surface? These are the key questions we will be investigating in this workshop.

Martian Craters with Interior Deposits: Global Survey Results and Wind Model P21D-1875 Kristen A. Bennett 1 and Mark Schmeeckle 2 1 School of Earth and.

The timing of, duration of, and wind patterns driving sand saltation on Mars are typically poorly constrained. The patterns of aeolian activity within.

Large fractures (to be differentiated from the small polygonal fracturation) Long/lat: (no particular order) E, 23.84N E, 23.85N E,

Delayed onset of the South American Monsoon during the Last Glacial Maximum Kerry H. Cook and Edward K. Vizy, Cornell University I. INTRODUCTION Climate.

Despite being large, low-relief, tropical river systems, the floodplains and wetlands of the Amazon and Congo Basins show markedly different surface water.

Assessment of OIB 2009 Data over Pine Island and Thwaites Glaciers K. Jezek OIB Science Team Meeting.

Scale Feature that relates distances on a map to distances on Earth

Mapping the Surface of Mars NOAO Science Education Group and Chris Martin from Howenstine Magnet High School.

Student: Danielle Clarke and Mentor: Briony Horgan ASU/NASA Space Grant Program.

Reading Topographic Maps

Xiaoming Wang and Philip L.-F. Liu Cornell University

Latitudinal Trend of Roughness and Circumpolar Mantles on Mars M. A. Kreslavsky J. W. Head III Brown University.

Mapping. What is a map? It is a representation of something (Earth, stars, solar system, a building, etc… It is a representation of something (Earth,

Fig Decadal averages of the seasonal and annual mean anomalies for (a) temperature at Faraday/Vernadsky, (b) temperature at Marambio, and (c) SAM.

Measuring Mars sand flux seasonality and calibrating the threshold for sand mobility F. Ayoub, J-P. Avouac, C.E. Newman, M.I. Richardson, A. Lucas, S.

CCN Variability During LBA-SMOCC-EMfiN! 2002 and Its Role on Precipitation Initiation Over the Amazon Basin.

MARSIS Overview J. J. Plaut G. Picardi and the MARSIS Team.

Horizontal Variability In Microphysical Properties of Mixed-Phase Arctic Clouds David Brown, Michael Poellot – University of North Dakota Clouds are strong.

27-3OBJECTIVES Identify the basic characteristics of the inner planets. Compare the characteristics of the inner planets. Summarize the features that allow.

Essential Questions - Topography

Fig Wilkins Ice Shelf breakup events of (a) MODIS band 1 image 10 days after the end of the first event; (b) Envisat ASARimage during the second.

Maps. What do we need in order to read a map? Direction Scale Legend.

CHARACTERIZING THE EVOLUTION OF MARS SOUTH POLAR JETS AND FANS. By Étude Aro O’Neel-Judy Dr. Timothy Titus In association with The NASA Space Grant Program.

Models of the Earth Section 3 Section 3: Types of Maps Preview Key Ideas Topographic Maps Topographic Maps and Contour Lines Index Contour, Contour Interval,

Description of the climate system and of its components

Dynamics & Mass transfer modelling Application Observations

Chapter 3 Section 3 Types of Maps Objectives

Topographic Maps mdeppe 2010.

Unit 7 Lesson 4 Topographic Maps

Exploring Mars: The Inside Story

Mark A. Bourassa and Qi Shi

Figure 1. Spatial distribution of pinyon-juniper and ponderosa pine forests is shown for the southwestern United States. Red dots indicate location of.

Chapter 1, Lesson 2, Topographic and Geologic Maps 1

Take Notes as you view the slides

Agenda: Wednesday Opening Activity CHOCO BARS for the winners

Unit 1 Structure of the Earth

Determining Wind (Aeolian) Patterns Around the Spirit Rover, Mars

Earth vs. Mars Comparison

Chapter 1, Lesson 2, Topographic and Geologic Maps 1

Aeolian dune sediment flux heterogeneity in Meridiani Planum, Mars

R.A. Yingst, F.C. Chuang, D.C. Berman, S.C. Mest

Volume 98, Issue 11, Pages (June 2010)

Dune-Yardang Interactions in Becquerel Crater, Mars

Vilmos Zsolnay, Michael Fill, Dirk Gillespie Biophysical Journal

An ice age recorded in the polar deposits of Mars

by A. Dutton, A. E. Carlson, A. J. Long, G. A. Milne, P. U. Clark, R

A 3-D Model of Ligand Transport in a Deforming Extracellular Space

Topographic Heterogeneity in Transdermal Transport Revealed by High-Speed Two- Photon Microscopy: Determination of Representative Skin Sample Sizes Betty.

by Asaf Inbal, Jean Paul Ampuero, and Robert W. Clayton

Volume 111, Issue 2, Pages (July 2016)

Orbital Identification of Carbonate-Bearing Rocks on Mars

Mercury Basic data Basic data: Radius is 0.38 of Earth’s

Volume 78, Issue 1, Pages (January 2000)

Models of the Earth Earth Science Chapter 3.

Vilmos Zsolnay, Michael Fill, Dirk Gillespie Biophysical Journal

EMEP case studies on HMs: State of the art

Large wind ripples on Mars: A record of atmospheric evolution

by Paul A Carling, Charles S. Bristow, and Alexey S. Litvinov

Nanoscale Measurement of the Dielectric Constant of Supported Lipid Bilayers in Aqueous Solutions with Electrostatic Force Microscopy G. Gramse, A. Dols-Perez,

Fig. 1 Study area and field site setting.

Volume 111, Issue 5, Pages (September 2016)

Observations of an Aeolian Landscape: Gale Crater, Mars

Fig. 1 Global distribution of data.

Fig. 1 Block A at the Debra L. Friedkin site.

Presentation transcript:

Boundary condition controls on the high sand flux regions of Mars Bedform heights, migration rates, and sand fluxes all span two to three orders of magnitude across Mars (Fig. 1), but we found that areas with the highest sand fluxes are concentrated in three regions: Syrtis Major, Hellespontus Montes, and the North polar sand seas (Fig. 2). All regions are located near prominent transition zones of topography (e.g., basins, polar caps) and thermophysical properties (e.g., albedo variations); these are not known to be critical terrestrial boundary conditions (Fig. 3). Results suggest that, unlike on Earth, large-scale topographic and thermophysical variability play a leading role for driving sand fluxes on Mars. Highlights Wind has been an enduring geologic agent throughout Mars’ history, as evidenced by the migration of aeolian sandy bedforms (dunes and ripples), but it is often unclear where and why sediment is mobile. The spatial variations in bedform transport parameters relate to external forcing factors (i.e., boundary conditions), some of which may be unique to the red planet. We investigated whether aeolian bedform (dune and ripple) transport rates are depressed or enhanced in some areas by local or regional boundary conditions (e.g., topography, sand supply, seasonal factors). Background Figure 1. Map of volumetric sand flux measurements for 54 dune fields (graduated circles), bedform mobility detection status (triangles (Banks et al., 2015, 2018)), and dune field distributions (red polygons) (Hayward et al., 2014). The three high sand flux regions of Syrtis Major, Hellespontus Montes, the North polar erg are outlined in black. Base map is colorized MOLA elevation from +4 (red) to -5 km (blue). Figure 2. HiRISE images of high-sand flux dune fields in (left) Syrtis Major (near Mars2020 landing site Jezero crater) and (right) Hellespontus Montes. Image Credit: NASA/JPL-Caltech/University of Arizona Figure 3. Schematic representation of regional boundary conditions. MOLA topographic profiles where thicker blue lines indicate locations of dune fields and increased sediment supply. Primary (orange solid lines) and secondary (orange dashed lines) wind regimes, along with locations of relatively high (+ q) and low (- q) sand fluxes are shown. Published in Geology in 2019 by Matthew Chojnacki, Maria Banks, Lori Fenton, and Anna Urso. https://pubs.geoscienceworld.org/gsa/geology/article/569256/