Venus tesserae feature layered, folded, and eroded rocks

Paul K. Byrne; Richard Ghail; Martha Gilmore; A.M. Celal Sengor; Christian Klimczak; David Senske; Jennifer Whitten; Sara Khawja; Richard Ernst; Sean Solomon

doi:10.1130/G47940.1

Venus tesserae feature layered, folded, and eroded rocks

Paul K. Byrne, Richard Ghail, Martha Gilmore, A.M. Celal Sengor, Christian Klimczak, David Senske, Jennifer Whitten, Sara Khawja, Richard Ernst, Sean Solomon

Department of Earth Sciences

Research output: Contribution to journal › Article › peer-review

80 Downloads (Pure)

Abstract

Tesserae on Venus are locally the stratigraphically oldest units preserved on the planet. These regions are characterized by pervasive tectonic deformation including normal faults, grabens, thrust faults, and folds. In multiple tesserae, sets of (often highly) curved, parallel linear features are also present. These features strongly resemble terracing in layered volcanic or sedimentary sequences on Earth having arcuate or sinuous outcrop patterns that follow undulating topography. Should this analogy hold for Venus, then these outcrop patterns imply some erosion of the tessera units in which these strata occur; radar-dark materials filling proximal lows might be deposits of that eroded material. This outcrop pattern is seen in geographically dispersed tessera units, so the preservation of layering could be common for this terrain type. If so, then tesserae record the culmination of volcanic and/or sedimentary deposition, folding, and erosion—complex geological histories that should be considered in future studies of this enigmatic terrain.

Original language	English
Number of pages	5
Journal	Geology
DOIs	https://doi.org/10.1130/G47940.1
Publication status	Published - 4 Sept 2020

Access to Document

10.1130/G47940.1

Accepted ManuscriptAccepted author manuscript, 7.25 MB

Cite this

@article{824095628b26433d85f08d8b2194f6b2,

title = "Venus tesserae feature layered, folded, and eroded rocks",

abstract = "Tesserae on Venus are locally the stratigraphically oldest units preserved on the planet. These regions are characterized by pervasive tectonic deformation including normal faults, grabens, thrust faults, and folds. In multiple tesserae, sets of (often highly) curved, parallel linear features are also present. These features strongly resemble terracing in layered volcanic or sedimentary sequences on Earth having arcuate or sinuous outcrop patterns that follow undulating topography. Should this analogy hold for Venus, then these outcrop patterns imply some erosion of the tessera units in which these strata occur; radar-dark materials filling proximal lows might be deposits of that eroded material. This outcrop pattern is seen in geographically dispersed tessera units, so the preservation of layering could be common for this terrain type. If so, then tesserae record the culmination of volcanic and/or sedimentary deposition, folding, and erosion—complex geological histories that should be considered in future studies of this enigmatic terrain.",

author = "Byrne, {Paul K.} and Richard Ghail and Martha Gilmore and Sengor, {A.M. Celal} and Christian Klimczak and David Senske and Jennifer Whitten and Sara Khawja and Richard Ernst and Sean Solomon",

year = "2020",

month = sep,

day = "4",

doi = "10.1130/G47940.1",

language = "English",

journal = "Geology",

issn = "0091-7613",

publisher = "Geological Society of America",

}

TY - JOUR

T1 - Venus tesserae feature layered, folded, and eroded rocks

AU - Byrne, Paul K.

AU - Ghail, Richard

AU - Gilmore, Martha

AU - Sengor, A.M. Celal

AU - Klimczak, Christian

AU - Senske, David

AU - Whitten, Jennifer

AU - Khawja, Sara

AU - Ernst, Richard

AU - Solomon, Sean

PY - 2020/9/4

Y1 - 2020/9/4

N2 - Tesserae on Venus are locally the stratigraphically oldest units preserved on the planet. These regions are characterized by pervasive tectonic deformation including normal faults, grabens, thrust faults, and folds. In multiple tesserae, sets of (often highly) curved, parallel linear features are also present. These features strongly resemble terracing in layered volcanic or sedimentary sequences on Earth having arcuate or sinuous outcrop patterns that follow undulating topography. Should this analogy hold for Venus, then these outcrop patterns imply some erosion of the tessera units in which these strata occur; radar-dark materials filling proximal lows might be deposits of that eroded material. This outcrop pattern is seen in geographically dispersed tessera units, so the preservation of layering could be common for this terrain type. If so, then tesserae record the culmination of volcanic and/or sedimentary deposition, folding, and erosion—complex geological histories that should be considered in future studies of this enigmatic terrain.

AB - Tesserae on Venus are locally the stratigraphically oldest units preserved on the planet. These regions are characterized by pervasive tectonic deformation including normal faults, grabens, thrust faults, and folds. In multiple tesserae, sets of (often highly) curved, parallel linear features are also present. These features strongly resemble terracing in layered volcanic or sedimentary sequences on Earth having arcuate or sinuous outcrop patterns that follow undulating topography. Should this analogy hold for Venus, then these outcrop patterns imply some erosion of the tessera units in which these strata occur; radar-dark materials filling proximal lows might be deposits of that eroded material. This outcrop pattern is seen in geographically dispersed tessera units, so the preservation of layering could be common for this terrain type. If so, then tesserae record the culmination of volcanic and/or sedimentary deposition, folding, and erosion—complex geological histories that should be considered in future studies of this enigmatic terrain.

U2 - 10.1130/G47940.1

DO - 10.1130/G47940.1

M3 - Article

SN - 0091-7613

JO - Geology

JF - Geology

ER -