Your search keyword '"Young DA"' showing total 5 results

1. The Scientific Legacy of NASA’s Operation IceBridge

Author

MacGregor, JA, MacGregor, JA, Boisvert, LN, Medley, B, Petty, AA, Harbeck, JP, Bell, RE, Blair, JB, Blanchard-Wrigglesworth, E, Buckley, EM, Christoffersen, MS, Cochran, JR, Csathó, BM, De Marco, EL, Dominguez, RAT, Fahnestock, MA, Farrell, SL, Gogineni, SP, Greenbaum, JS, Hansen, CM, Hofton, MA, Holt, JW, Jezek, KC, Koenig, LS, Kurtz, NT, Kwok, R, Larsen, CF, Leuschen, CJ, Locke, CD, Manizade, SS, Martin, S, Neumann, TA, Nowicki, SMJ, Paden, JD, Richter-Menge, JA, Rignot, EJ, Rodríguez-Morales, F, Siegfried, MR, Smith, BE, Sonntag, JG, Studinger, M, Tinto, KJ, Truffer, M, Wagner, TP, Woods, JE, Young, DA, Yungel, JK, MacGregor, JA, MacGregor, JA, Boisvert, LN, Medley, B, Petty, AA, Harbeck, JP, Bell, RE, Blair, JB, Blanchard-Wrigglesworth, E, Buckley, EM, Christoffersen, MS, Cochran, JR, Csathó, BM, De Marco, EL, Dominguez, RAT, Fahnestock, MA, Farrell, SL, Gogineni, SP, Greenbaum, JS, Hansen, CM, Hofton, MA, Holt, JW, Jezek, KC, Koenig, LS, Kurtz, NT, Kwok, R, Larsen, CF, Leuschen, CJ, Locke, CD, Manizade, SS, Martin, S, Neumann, TA, Nowicki, SMJ, Paden, JD, Richter-Menge, JA, Rignot, EJ, Rodríguez-Morales, F, Siegfried, MR, Smith, BE, Sonntag, JG, Studinger, M, Tinto, KJ, Truffer, M, Wagner, TP, Woods, JE, Young, DA, and Yungel, JK

Abstract

The National Aeronautics and Space Administration (NASA)’s Operation IceBridge (OIB) was a 13-year (2009–2021) airborne mission to survey land and sea ice across the Arctic, Antarctic, and Alaska. Here, we review OIB’s goals, instruments, campaigns, key scientific results, and implications for future investigations of the cryosphere. OIB’s primary goal was to use airborne laser altimetry to bridge the gap in fine-resolution elevation measurements of ice from space between the conclusion of NASA’s Ice, Cloud, and land Elevation Satellite (ICESat; 2003–2009) and its follow-on, ICESat-2 (launched 2018). Additional scientific requirements were intended to contextualize observed elevation changes using a multisensor suite of radar sounders, gravimeters, magnetometers, and cameras. Using 15 different aircraft, OIB conducted 968 science flights, of which 42% were repeat surveys of land ice, 42% were surveys of previously unmapped terrain across the Greenland and Antarctic ice sheets, Arctic ice caps, and Alaskan glaciers, and 16% were surveys of sea ice. The combination of an expansive instrument suite and breadth of surveys enabled numerous fundamental advances in our understanding of the Earth’s cryosphere. For land ice, OIB dramatically improved knowledge of interannual outlet-glacier variability, ice-sheet, and outlet-glacier thicknesses, snowfall rates on ice sheets, fjord and sub-ice-shelf bathymetry, and ice-sheet hydrology. Unanticipated discoveries included a reliable method for constraining the thickness within difficult-to-sound incised troughs beneath ice sheets, the extent of the firn aquifer within the Greenland Ice Sheet, the vulnerability of many Greenland and Antarctic outlet glaciers to ocean-driven melting at their grounding zones, and the dominance of surface-melt-driven mass loss of Alaskan glaciers. For sea ice, OIB significantly advanced our understanding of spatiotemporal variability in sea ice freeboard and its snow cover, especially through combin

Published

2021

2. The Scientific Legacy of NASA’s Operation IceBridge

Author

MacGregor, JA, MacGregor, JA, Boisvert, LN, Medley, B, Petty, AA, Harbeck, JP, Bell, RE, Blair, JB, Blanchard-Wrigglesworth, E, Buckley, EM, Christoffersen, MS, Cochran, JR, Csathó, BM, De Marco, EL, Dominguez, RAT, Fahnestock, MA, Farrell, SL, Gogineni, SP, Greenbaum, JS, Hansen, CM, Hofton, MA, Holt, JW, Jezek, KC, Koenig, LS, Kurtz, NT, Kwok, R, Larsen, CF, Leuschen, CJ, Locke, CD, Manizade, SS, Martin, S, Neumann, TA, Nowicki, SMJ, Paden, JD, Richter-Menge, JA, Rignot, EJ, Rodríguez-Morales, F, Siegfried, MR, Smith, BE, Sonntag, JG, Studinger, M, Tinto, KJ, Truffer, M, Wagner, TP, Woods, JE, Young, DA, Yungel, JK, MacGregor, JA, MacGregor, JA, Boisvert, LN, Medley, B, Petty, AA, Harbeck, JP, Bell, RE, Blair, JB, Blanchard-Wrigglesworth, E, Buckley, EM, Christoffersen, MS, Cochran, JR, Csathó, BM, De Marco, EL, Dominguez, RAT, Fahnestock, MA, Farrell, SL, Gogineni, SP, Greenbaum, JS, Hansen, CM, Hofton, MA, Holt, JW, Jezek, KC, Koenig, LS, Kurtz, NT, Kwok, R, Larsen, CF, Leuschen, CJ, Locke, CD, Manizade, SS, Martin, S, Neumann, TA, Nowicki, SMJ, Paden, JD, Richter-Menge, JA, Rignot, EJ, Rodríguez-Morales, F, Siegfried, MR, Smith, BE, Sonntag, JG, Studinger, M, Tinto, KJ, Truffer, M, Wagner, TP, Woods, JE, Young, DA, and Yungel, JK

Abstract

The National Aeronautics and Space Administration (NASA)’s Operation IceBridge (OIB) was a 13-year (2009–2021) airborne mission to survey land and sea ice across the Arctic, Antarctic, and Alaska. Here, we review OIB’s goals, instruments, campaigns, key scientific results, and implications for future investigations of the cryosphere. OIB’s primary goal was to use airborne laser altimetry to bridge the gap in fine-resolution elevation measurements of ice from space between the conclusion of NASA’s Ice, Cloud, and land Elevation Satellite (ICESat; 2003–2009) and its follow-on, ICESat-2 (launched 2018). Additional scientific requirements were intended to contextualize observed elevation changes using a multisensor suite of radar sounders, gravimeters, magnetometers, and cameras. Using 15 different aircraft, OIB conducted 968 science flights, of which 42% were repeat surveys of land ice, 42% were surveys of previously unmapped terrain across the Greenland and Antarctic ice sheets, Arctic ice caps, and Alaskan glaciers, and 16% were surveys of sea ice. The combination of an expansive instrument suite and breadth of surveys enabled numerous fundamental advances in our understanding of the Earth’s cryosphere. For land ice, OIB dramatically improved knowledge of interannual outlet-glacier variability, ice-sheet, and outlet-glacier thicknesses, snowfall rates on ice sheets, fjord and sub-ice-shelf bathymetry, and ice-sheet hydrology. Unanticipated discoveries included a reliable method for constraining the thickness within difficult-to-sound incised troughs beneath ice sheets, the extent of the firn aquifer within the Greenland Ice Sheet, the vulnerability of many Greenland and Antarctic outlet glaciers to ocean-driven melting at their grounding zones, and the dominance of surface-melt-driven mass loss of Alaskan glaciers. For sea ice, OIB significantly advanced our understanding of spatiotemporal variability in sea ice freeboard and its snow cover, especially through combin

Published

2021

3. The Scientific Legacy of NASA’s Operation IceBridge

Author

MacGregor, JA, MacGregor, JA, Boisvert, LN, Medley, B, Petty, AA, Harbeck, JP, Bell, RE, Blair, JB, Blanchard-Wrigglesworth, E, Buckley, EM, Christoffersen, MS, Cochran, JR, Csathó, BM, De Marco, EL, Dominguez, RAT, Fahnestock, MA, Farrell, SL, Gogineni, SP, Greenbaum, JS, Hansen, CM, Hofton, MA, Holt, JW, Jezek, KC, Koenig, LS, Kurtz, NT, Kwok, R, Larsen, CF, Leuschen, CJ, Locke, CD, Manizade, SS, Martin, S, Neumann, TA, Nowicki, SMJ, Paden, JD, Richter-Menge, JA, Rignot, EJ, Rodríguez-Morales, F, Siegfried, MR, Smith, BE, Sonntag, JG, Studinger, M, Tinto, KJ, Truffer, M, Wagner, TP, Woods, JE, Young, DA, Yungel, JK, MacGregor, JA, MacGregor, JA, Boisvert, LN, Medley, B, Petty, AA, Harbeck, JP, Bell, RE, Blair, JB, Blanchard-Wrigglesworth, E, Buckley, EM, Christoffersen, MS, Cochran, JR, Csathó, BM, De Marco, EL, Dominguez, RAT, Fahnestock, MA, Farrell, SL, Gogineni, SP, Greenbaum, JS, Hansen, CM, Hofton, MA, Holt, JW, Jezek, KC, Koenig, LS, Kurtz, NT, Kwok, R, Larsen, CF, Leuschen, CJ, Locke, CD, Manizade, SS, Martin, S, Neumann, TA, Nowicki, SMJ, Paden, JD, Richter-Menge, JA, Rignot, EJ, Rodríguez-Morales, F, Siegfried, MR, Smith, BE, Sonntag, JG, Studinger, M, Tinto, KJ, Truffer, M, Wagner, TP, Woods, JE, Young, DA, and Yungel, JK

Abstract

The National Aeronautics and Space Administration (NASA)’s Operation IceBridge (OIB) was a 13-year (2009–2021) airborne mission to survey land and sea ice across the Arctic, Antarctic, and Alaska. Here, we review OIB’s goals, instruments, campaigns, key scientific results, and implications for future investigations of the cryosphere. OIB’s primary goal was to use airborne laser altimetry to bridge the gap in fine-resolution elevation measurements of ice from space between the conclusion of NASA’s Ice, Cloud, and land Elevation Satellite (ICESat; 2003–2009) and its follow-on, ICESat-2 (launched 2018). Additional scientific requirements were intended to contextualize observed elevation changes using a multisensor suite of radar sounders, gravimeters, magnetometers, and cameras. Using 15 different aircraft, OIB conducted 968 science flights, of which 42% were repeat surveys of land ice, 42% were surveys of previously unmapped terrain across the Greenland and Antarctic ice sheets, Arctic ice caps, and Alaskan glaciers, and 16% were surveys of sea ice. The combination of an expansive instrument suite and breadth of surveys enabled numerous fundamental advances in our understanding of the Earth’s cryosphere. For land ice, OIB dramatically improved knowledge of interannual outlet-glacier variability, ice-sheet, and outlet-glacier thicknesses, snowfall rates on ice sheets, fjord and sub-ice-shelf bathymetry, and ice-sheet hydrology. Unanticipated discoveries included a reliable method for constraining the thickness within difficult-to-sound incised troughs beneath ice sheets, the extent of the firn aquifer within the Greenland Ice Sheet, the vulnerability of many Greenland and Antarctic outlet glaciers to ocean-driven melting at their grounding zones, and the dominance of surface-melt-driven mass loss of Alaskan glaciers. For sea ice, OIB significantly advanced our understanding of spatiotemporal variability in sea ice freeboard and its snow cover, especially through combin

Published

2021

4. Phylotranscriptomics resolves phylogeny of the Heliozelidae (Adeloidea: Lepidoptera) and suggests a Late Cretaceous origin in Australia

Author

Milla, L, Moussalli, A, Wilcox, SA, van Nieukerken, EJ, Young, DA, Halsey, M, McConville, T, Jones, TM, Kallies, A, Hilton, DJ, Milla, L, Moussalli, A, Wilcox, SA, van Nieukerken, EJ, Young, DA, Halsey, M, McConville, T, Jones, TM, Kallies, A, and Hilton, DJ

Abstract

Heliozelidae are a cosmopolitan family of small, day‐flying moths, and include some pest species of commercial crops. Overall, the family is poorly known and lacks a well‐resolved phylogeny. Previous molecular and taxonomic work has revealed rich undescribed diversity within the family, particularly in Australia; however, the relationships amongst the major clades or genera were not resolved. We sequenced the transcriptomes of 39 taxa, representing all major genera of Heliozelidae, and seven outgroups representing most other Adeloidea families and the putative sister superfamily, Andesianoidea. The resulting phylogeny, based on the coding sequences of up to 1049 nuclear genes, provides a robust hypothesis for the generic relationships within Heliozelidae. On the basis of this analysis, the genus Plesiozela, previously proposed as sister group to all other Heliozelidae, is excluded from the family and formally transferred to Incurvariidae. By incorporating fossil and secondary time calibrations into our phylogeny, we estimated that Heliozelidae ancestors first appeared at the beginning of the Late Cretaceous, approximately 95 Ma. We propose an ancestral biogeographical range hypothesis of the family, based on a combination of our transcriptome data and a previous multigene study including over 100 species. Our ancestral range modelling results suggest that Heliozelidae are likely to have originated in the Australian region, with subsequent range expansions to the rest of the world.

Published

2020

5. The Fine Arts of Distinction: Bourdieu on Society and Art

Author

Young, DA and Young, DA

Published

2006