Your search keyword '"Kurtz, Nathan T."' showing total 5 results

1. Modeled Trends in Antarctic Sea Ice Thickness

Author

Holland, Paul R., Bruneau, Nicolas, Enright, Clare, Losch, Martin, Kurtz, Nathan T., and Kwok, Ron

Published

2014

2. Impacts of snow data and processing methods on the interpretation of long-term changes in Baffin Bay early spring sea ice thickness.

Author

Glissenaar, Isolde A., Landy, Jack C., Petty, Alek A., Kurtz, Nathan T., and Stroeve, Julienne C.

Subjects

SEA ice, ELECTRONIC data processing, SNOW accumulation, SEASONS, ICE

Abstract

In the Arctic, multi-year sea ice is being rapidly replaced by seasonal sea ice. Baffin Bay, situated between Greenland and Canada, is part of the seasonal ice zone. In this study, we present a long-term multi-mission assessment (2003–2020) of spring sea ice thickness in Baffin Bay from satellite altimetry and sea ice charts. Sea ice thickness within Baffin Bay is calculated from Envisat, ICESat, CryoSat-2, and ICESat-2 freeboard estimates, alongside a proxy from the ice chart stage of development that closely matches the altimetry data. We study the sensitivity of sea ice thickness results estimated from an array of different snow depth and snow density products and methods for redistributing low-resolution snow data onto along-track altimetry freeboards. The snow depth products that are applied include a reference estimated from the Warren climatology, a passive microwave snow depth product, and the dynamic snow scheme SnowModel-LG. We find that applying snow depth redistribution to represent small-scale snow variability has a considerable impact on ice thickness calculations from laser freeboards but was unnecessary for radar freeboards. Decisions on which snow loading product to use and whether to apply snow redistribution can lead to different conclusions on trends and physical mechanisms. For instance, we find an uncertainty envelope around the March mean sea ice thickness of 13 % for different snow depth/density products and redistribution methods. Consequently, trends in March sea ice thickness from 2003–2020 range from - 23 to 17 cm per decade, depending on which snow depth/density product and redistribution method is applied. Over a longer timescale, since 1996, the proxy ice chart thickness product has demonstrated statistically significant thinning within Baffin Bay of 7 cm per decade. Our study provides further evidence for long-term asymmetrical trends in Baffin Bay sea ice thickness (with - 17.6 cm per decade thinning in the west and 10.8 cm per decade thickening in the east of the bay) since 2003. This asymmetrical thinning is consistent for all combinations of snow product and processing method, but it is unclear what may have driven these changes. [ABSTRACT FROM AUTHOR]

Published

2021

3. Characterizing the System Impulse Response Function From Photon-Counting LiDAR Data.

Author

Greeley, Adam P., Neumann, Thomas A., Kurtz, Nathan T., Markus, Thorsten, and Martino, Anthony J.

Subjects

HISTOGRAMS, MONTE Carlo method, IMPULSE response, BACKSCATTERING, LASER altimeters, LIDAR, SURFACE of the earth, ARITHMETIC mean, PHOTONS

Abstract

NASA’s Multiple Altimeter Beam Experimental LiDAR (MABEL) is an aircraft-based photon-counting laser altimeter designed as a simulator to test measurement techniques and algorithms for Advanced Topographic Laser Altimeter System (ATLAS), the sole instrument on NASA’s Ice, Cloud, and land Elevation Satellite-2 (ICESat-2) mission. By measuring the time of flight, pointing angle, and absolute position for individual photons, ICESat-2 provides detailed elevation measurements of earth’s surface. Calculating accurate and precise elevations requires an understanding of how photons interact with surfaces, and characterization of the photon distribution after returning from surfaces. Neither MABEL nor ATLAS records the transmitted laser pulse shape, relying instead on aggregating several pulses worth of photons, often using histograms, to characterize the pulse shape. In this paper, we assess the limitations of using histograms and propose a more robust method to describe MABEL’s system impulse-response function using an exponentially modified Gaussian distribution. We also provide standard error estimates for the arithmetic mean and standard deviation calculations, and for exponentially modified Gaussian parameters using a Monte Carlo sensitivity analysis. We apply this method to photon returns from a sea ice lead and from a dry salt lake bed as case studies for estimating the standard error associated with sample size for the arithmetic mean and standard deviation, and for the exponentially modified Gaussian parameters. We use these standard errors to calculate the minimum number of photons required to find both Gaussian and exponentially modified Gaussian distribution parameters within 3 cm of their parent population values. [ABSTRACT FROM AUTHOR]

Published

2019

4. Comparison of ICES at Data With Airborne Laser Altimeter Measurements Over Arctic Sea Ice.

Author

Kurtz, Nathan T., Markus, Thorsten, Cavalieri, Donald J., Krabill, William, Sonntag, John G., and Miller, Jeffrey

Subjects

*ALTITUDE measurements, *ICEBERGS, *AERONAUTICAL instruments, *METEOROLOGICAL instruments, *ALTIMETERS, *ARTIFICIAL satellites, *REMOTE sensing

Abstract

Surface elevation and roughness measurements from NASA's Ice, Cloud, and land Elevation Satellite (ICESat) are compared with high-resolution airborne laser altimeter measurements over the Arctic sea ice north of Alaska, which were taken during the March 2006 EOS Aqua Advanced Microwave Scanning Radiometer sea ice validation campaign. The comparison of the elevation measurements shows that they agree quite well with correlations of around 0.9 for individual shots and a bias of less than 2 cm. The differences are found to decrease quite rapidly when applying running means. The comparison of the roughness measurements show that there are significant differences between the two data sets, with ICESat generally having higher values. The roughness values are only moderately correlated on an individual-shot basis, but applying running means to the data significantly improves the correlations to as high as 0.9. For the conversion of the elevation measurements into snow-ice freeboard, ocean surface elevation estimates are made with the high-resolution laser altimeter data, as well as several methods using lower resolution ICESat data. Under optimum conditions, i.e., when leads that are larger than the ICESat footprint are present, the ICESat- and Airborne Topographic Mapper-derived freeboards are found to agree to within 2 cm. For other areas, ICESat tends to under- estimate the freeboard by up to 9 cm. [ABSTRACT FROM AUTHOR]

Published

2008

5. The Ice, Cloud, and Land Elevation Satellite – 2 mission: A global geolocated photon product derived from the Advanced Topographic Laser Altimeter System.

Author

Neumann, Thomas A., Martino, Anthony J., Markus, Thorsten, Bae, Sungkoo, Bock, Megan R., Brenner, Anita C., Brunt, Kelly M., Cavanaugh, John, Fernandes, Stanley T., Hancock, David W., Harbeck, Kaitlin, Lee, Jeffrey, Kurtz, Nathan T., Luers, Philip J., Luthcke, Scott B., Magruder, Lori, Pennington, Teresa A., Ramos-Izquierdo, Luis, Rebold, Timothy, and Skoog, Jonah

Subjects

*LASER altimeters, *SEA ice, *OCEAN surface topography, *GLOBAL Positioning System, *ICE sheets, *ICE, *PHOTONS, *BACKSCATTERING

Abstract

The Ice, Cloud, and land Elevation Satellite – 2 (ICESat-2) observatory was launched on 15 September 2018 to measure ice sheet and glacier elevation change, sea ice freeboard, and enable the determination of the heights of Earth's forests. ICESat-2's laser altimeter, the Advanced Topographic Laser Altimeter System (ATLAS) uses green (532 nm) laser light and single-photon sensitive detection to measure time of flight and subsequently surface height along each of its six beams. In this paper, we describe the major components of ATLAS, including the transmitter, the receiver and the components of the timing system. We present the major components of the ICESat-2 observatory, including the Global Positioning System, star trackers and inertial measurement unit. The ICESat-2 Level 1B data product (ATL02) provides the precise photon round-trip time of flight, among other data. The ICESat-2 Level 2A data product (ATL03) combines the photon times of flight with the observatory position and attitude to determine the geodetic location (i.e. the latitude, longitude and height) of the ground bounce point of photons detected by ATLAS. The ATL03 data product is used by higher-level (Level 3A) surface-specific data products to determine glacier and ice sheet height, sea ice freeboard, vegetation canopy height, ocean surface topography, and inland water body height. • Describes the ICESat-2 Observatory and its sole instrument: the Advanced Topographic Laser Altimeter System (ATLAS) • Presents the structure and major contents of the ICESat-2 Level 1B data product (ATL02; photon times of flight) • Presents the structure and major contents of the ICESat-2 Level 2A data product (ATL03; Global Geolocated Photons) [ABSTRACT FROM AUTHOR]

Published

2019