Oriented Bedrock Samples Drilled by the Perseverance Rover on Mars

Benjamin P. Weiss; Elias N. Mansbach; Joseph L. Carsten; Kyle W. Kaplan; Justin N. Maki; Roger C. Wiens; Tanja Bosak; Curtis L. Collins; Jennifer Fentress; Joshua M. Feinberg; Yulia Goreva; Megan Kennedy Wu; Tara A. Estlin; Douglas E. Klein; Rachel E. Kronyak; Robert C. Moeller; Nicholas Peper; Adriana Reyes-Newell; Mark A. Sephton; David L. Shuster; Justin I. Simon; Kenneth H. Williford; Kathryn W. Stack; Kenneth A. Farley

doi:10.1029/2023EA003322

Oriented Bedrock Samples Drilled by the Perseverance Rover on Mars

Benjamin P. Weiss, Elias N. Mansbach, Joseph L. Carsten, Kyle W. Kaplan, Justin N. Maki, Roger C. Wiens, Tanja Bosak, Curtis L. Collins, Jennifer Fentress, Joshua M. Feinberg, Yulia Goreva, Megan Kennedy Wu, Tara A. Estlin, Douglas E. Klein, Rachel E. Kronyak, Robert C. Moeller, Nicholas Peper, Adriana Reyes-Newell, Mark A. Sephton, David L. ShusterJustin I. Simon, Kenneth H. Williford, Kathryn W. Stack, Kenneth A. Farley

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

Abstract

A key objective of the Perseverance rover mission is to acquire samples of Martian rocks for future return to Earth. Eventual laboratory analyses of these samples would address key questions about the evolution of the Martian climate, interior, and habitability. Many such investigations would benefit greatly from samples of Martian bedrock that are oriented in absolute Martian geographic coordinates. However, the Mars 2020 mission was designed without a requirement for orienting the samples. Here we describe a methodology that we developed for orienting rover drill cores in the Martian geographic frame and its application to Perseverance's first 20 rock samples. To orient the cores, three angles were measured: the azimuth and hade of the core pointing vector (i.e., vector oriented along the core axis) and the core roll (i.e., the solid body angle of rotation around the pointing vector). We estimated the core pointing vector from the attitude of the rover's Coring Drill during drilling. To orient the core roll, we used oriented images of asymmetric markings on the bedrock surface acquired with the rover's Wide Angle Topographic Sensor for Operations and eNgineering (WATSON) camera. For most samples, these markings were in the form of natural features on the outcrop, while for four samples they were artificial ablation pits produced by the rover's SuperCam laser. These cores are the first geographically-oriented (<2.7° 3σ total uncertainty) bedrock samples from another planetary body. This will enable a diversity of paleomagnetic, sedimentological, igneous, tectonic, and astrobiological studies on the returned samples.

Original language	English (US)
Article number	e2023EA003322
Journal	Earth and Space Science
Volume	11
Issue number	3
DOIs	https://doi.org/10.1029/2023EA003322
State	Published - Mar 2024
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2024 The Authors.

Keywords

bedrock
cores
Mars
orientation
Perseverance rover

Access

10.1029/2023EA003322

OpenUrl availability

Full text

Cite this

Weiss, B. P., Mansbach, E. N., Carsten, J. L., Kaplan, K. W., Maki, J. N., Wiens, R. C., Bosak, T., Collins, C. L., Fentress, J., Feinberg, J. M., Goreva, Y., Kennedy Wu, M., Estlin, T. A., Klein, D. E., Kronyak, R. E., Moeller, R. C., Peper, N., Reyes-Newell, A., Sephton, M. A., ... Farley, K. A. (2024). Oriented Bedrock Samples Drilled by the Perseverance Rover on Mars. Earth and Space Science, 11(3), Article e2023EA003322. https://doi.org/10.1029/2023EA003322

Weiss, BP, Mansbach, EN, Carsten, JL, Kaplan, KW, Maki, JN, Wiens, RC, Bosak, T, Collins, CL, Fentress, J, Feinberg, JM, Goreva, Y, Kennedy Wu, M, Estlin, TA, Klein, DE, Kronyak, RE, Moeller, RC, Peper, N, Reyes-Newell, A, Sephton, MA, Shuster, DL, Simon, JI, Williford, KH, Stack, KW & Farley, KA 2024, 'Oriented Bedrock Samples Drilled by the Perseverance Rover on Mars', Earth and Space Science, vol. 11, no. 3, e2023EA003322. https://doi.org/10.1029/2023EA003322

@article{b25c5fcf7aaa4d668148ab909cd77bed,

title = "Oriented Bedrock Samples Drilled by the Perseverance Rover on Mars",

abstract = "A key objective of the Perseverance rover mission is to acquire samples of Martian rocks for future return to Earth. Eventual laboratory analyses of these samples would address key questions about the evolution of the Martian climate, interior, and habitability. Many such investigations would benefit greatly from samples of Martian bedrock that are oriented in absolute Martian geographic coordinates. However, the Mars 2020 mission was designed without a requirement for orienting the samples. Here we describe a methodology that we developed for orienting rover drill cores in the Martian geographic frame and its application to Perseverance's first 20 rock samples. To orient the cores, three angles were measured: the azimuth and hade of the core pointing vector (i.e., vector oriented along the core axis) and the core roll (i.e., the solid body angle of rotation around the pointing vector). We estimated the core pointing vector from the attitude of the rover's Coring Drill during drilling. To orient the core roll, we used oriented images of asymmetric markings on the bedrock surface acquired with the rover's Wide Angle Topographic Sensor for Operations and eNgineering (WATSON) camera. For most samples, these markings were in the form of natural features on the outcrop, while for four samples they were artificial ablation pits produced by the rover's SuperCam laser. These cores are the first geographically-oriented (<2.7° 3σ total uncertainty) bedrock samples from another planetary body. This will enable a diversity of paleomagnetic, sedimentological, igneous, tectonic, and astrobiological studies on the returned samples.",

keywords = "bedrock, cores, Mars, orientation, Perseverance rover",

author = "Weiss, {Benjamin P.} and Mansbach, {Elias N.} and Carsten, {Joseph L.} and Kaplan, {Kyle W.} and Maki, {Justin N.} and Wiens, {Roger C.} and Tanja Bosak and Collins, {Curtis L.} and Jennifer Fentress and Feinberg, {Joshua M.} and Yulia Goreva and {Kennedy Wu}, Megan and Estlin, {Tara A.} and Klein, {Douglas E.} and Kronyak, {Rachel E.} and Moeller, {Robert C.} and Nicholas Peper and Adriana Reyes-Newell and Sephton, {Mark A.} and Shuster, {David L.} and Simon, {Justin I.} and Williford, {Kenneth H.} and Stack, {Kathryn W.} and Farley, {Kenneth A.}",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors.",

year = "2024",

month = mar,

doi = "10.1029/2023EA003322",

language = "English (US)",

volume = "11",

journal = "Earth and Space Science",

issn = "2333-5084",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "3",

}

TY - JOUR

T1 - Oriented Bedrock Samples Drilled by the Perseverance Rover on Mars

AU - Weiss, Benjamin P.

AU - Mansbach, Elias N.

AU - Carsten, Joseph L.

AU - Kaplan, Kyle W.

AU - Maki, Justin N.

AU - Wiens, Roger C.

AU - Bosak, Tanja

AU - Collins, Curtis L.

AU - Fentress, Jennifer

AU - Feinberg, Joshua M.

AU - Goreva, Yulia

AU - Kennedy Wu, Megan

AU - Estlin, Tara A.

AU - Klein, Douglas E.

AU - Kronyak, Rachel E.

AU - Moeller, Robert C.

AU - Peper, Nicholas

AU - Reyes-Newell, Adriana

AU - Sephton, Mark A.

AU - Shuster, David L.

AU - Simon, Justin I.

AU - Williford, Kenneth H.

AU - Stack, Kathryn W.

AU - Farley, Kenneth A.

PY - 2024/3

Y1 - 2024/3

N2 - A key objective of the Perseverance rover mission is to acquire samples of Martian rocks for future return to Earth. Eventual laboratory analyses of these samples would address key questions about the evolution of the Martian climate, interior, and habitability. Many such investigations would benefit greatly from samples of Martian bedrock that are oriented in absolute Martian geographic coordinates. However, the Mars 2020 mission was designed without a requirement for orienting the samples. Here we describe a methodology that we developed for orienting rover drill cores in the Martian geographic frame and its application to Perseverance's first 20 rock samples. To orient the cores, three angles were measured: the azimuth and hade of the core pointing vector (i.e., vector oriented along the core axis) and the core roll (i.e., the solid body angle of rotation around the pointing vector). We estimated the core pointing vector from the attitude of the rover's Coring Drill during drilling. To orient the core roll, we used oriented images of asymmetric markings on the bedrock surface acquired with the rover's Wide Angle Topographic Sensor for Operations and eNgineering (WATSON) camera. For most samples, these markings were in the form of natural features on the outcrop, while for four samples they were artificial ablation pits produced by the rover's SuperCam laser. These cores are the first geographically-oriented (<2.7° 3σ total uncertainty) bedrock samples from another planetary body. This will enable a diversity of paleomagnetic, sedimentological, igneous, tectonic, and astrobiological studies on the returned samples.

AB - A key objective of the Perseverance rover mission is to acquire samples of Martian rocks for future return to Earth. Eventual laboratory analyses of these samples would address key questions about the evolution of the Martian climate, interior, and habitability. Many such investigations would benefit greatly from samples of Martian bedrock that are oriented in absolute Martian geographic coordinates. However, the Mars 2020 mission was designed without a requirement for orienting the samples. Here we describe a methodology that we developed for orienting rover drill cores in the Martian geographic frame and its application to Perseverance's first 20 rock samples. To orient the cores, three angles were measured: the azimuth and hade of the core pointing vector (i.e., vector oriented along the core axis) and the core roll (i.e., the solid body angle of rotation around the pointing vector). We estimated the core pointing vector from the attitude of the rover's Coring Drill during drilling. To orient the core roll, we used oriented images of asymmetric markings on the bedrock surface acquired with the rover's Wide Angle Topographic Sensor for Operations and eNgineering (WATSON) camera. For most samples, these markings were in the form of natural features on the outcrop, while for four samples they were artificial ablation pits produced by the rover's SuperCam laser. These cores are the first geographically-oriented (<2.7° 3σ total uncertainty) bedrock samples from another planetary body. This will enable a diversity of paleomagnetic, sedimentological, igneous, tectonic, and astrobiological studies on the returned samples.

KW - bedrock

KW - cores

KW - Mars

KW - orientation

KW - Perseverance rover

UR - http://www.scopus.com/inward/record.url?scp=85186857456&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85186857456&partnerID=8YFLogxK

U2 - 10.1029/2023EA003322

DO - 10.1029/2023EA003322

M3 - Article

AN - SCOPUS:85186857456

SN - 2333-5084

VL - 11

JO - Earth and Space Science

JF - Earth and Space Science

IS - 3

M1 - e2023EA003322

ER -

Oriented Bedrock Samples Drilled by the Perseverance Rover on Mars

Abstract

Bibliographical note

Keywords

Access

OpenUrl availability

Other files and links

Fingerprint

Cite this