Towards global spaceborne lidar biomass: Developing and applying boreal forest biomass models for ICESat-2 laser altimetry data

A. Neuenschwander; L. Duncanson; P. Montesano; D. Minor; E. Guenther; S. Hancock; M.A. Wulder; J.C. White; M. Purslow; N. Thomas; A. Mandel; T. Feng; J. Armston; J.R. Kellner; H.E. Andersen; L. Boschetti; P. Fekety; A. Hudak; J. Pisek; N. Sánchez-López; K. Stereńczak

doi:10.1016/j.srs.2024.100150

Science of Remote Sensing (Dec 2024)

Towards global spaceborne lidar biomass: Developing and applying boreal forest biomass models for ICESat-2 laser altimetry data

A. Neuenschwander,
L. Duncanson,
P. Montesano,
D. Minor,
E. Guenther,
S. Hancock,
M.A. Wulder,
J.C. White,
M. Purslow,
N. Thomas,
A. Mandel,
T. Feng,
J. Armston,
J.R. Kellner,
H.E. Andersen,
L. Boschetti,
P. Fekety,
A. Hudak,
J. Pisek,
N. Sánchez-López,
K. Stereńczak

Affiliations

A. Neuenschwander: Center for Space Research, University of Texas at Austin, USA; Corresponding author.
L. Duncanson: Department of Geography, University of Maryland, USA
P. Montesano: Biospheric Sciences, NASA Goddard Space Flight Center, USA
D. Minor: Department of Geography, University of Maryland, USA
E. Guenther: Center for Space Research, University of Texas at Austin, USA
S. Hancock: School of Geosciences, University of Edinburgh, UK
M.A. Wulder: Canadian Forest Service (Pacific Forestry Centre), Natural Resources Canada, Victoria, BC, Canada
J.C. White: Canadian Forest Service (Pacific Forestry Centre), Natural Resources Canada, Victoria, BC, Canada
M. Purslow: School of Geosciences, University of Edinburgh, UK
N. Thomas: Biospheric Sciences, NASA Goddard Space Flight Center, USA
A. Mandel: Development Seed, Washington DC, USA
T. Feng: Department of Geography, University of Maryland, USA
J. Armston: Department of Geography, University of Maryland, USA
J.R. Kellner: Institute at Brown for Environment and Society, Brown University, USA
H.E. Andersen: USDA Forest Service, Pacific Northwest Research Station, USA
L. Boschetti: Department of Forest Rangeland and Fire Sciences, University of Idaho, USA
P. Fekety: Natural Resource Ecology Laboratory, Colorado State University, USA
A. Hudak: USDA Forest Service, Rocky Mountain Research Station, USA
J. Pisek: Tartu Observatory, University of Tartu, Estonia
N. Sánchez-López: USDA Forest Service, Rocky Mountain Research Station, USA
K. Stereńczak: Forest Research Institute, Poland

DOI: https://doi.org/10.1016/j.srs.2024.100150
Journal volume & issue: Vol. 10
p. 100150

Abstract

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Space-based laser altimetry has revolutionized our capacity to characterize terrestrial ecosystems through the direct observation of vegetation structure and the terrain beneath it. Data from NASA's ICESat-2 mission provide the first comprehensive look at canopy structure for boreal forests from space-based lidar. The objective of this research was to create ICESat-2 aboveground biomass density (AGBD) models for the global entirety of boreal forests at a 30 m spatial resolution and apply those models to ICESat-2 data from the 2019–2021 period. Although limited in dense canopy, ICESat-2 is the only space-based laser altimeter capable of mapping vegetation in northern latitudes. Along each ICESat-2 orbit track, ground and vegetation height is captured with additional modeling required to characterize biomass. By implementing a similar methodology of estimating AGBD as GEDI, ICESat-2 AGBD estimates can complement GEDI's estimates for a full global accounting of aboveground carbon. Using a suite of field measurements with contemporaneous airborne lidar data over boreal forests, ICESat-2 photons were simulated over many field sites and the impact of two methods of computing relative height (RH) metrics on AGBD at a 30 m along-track spatial resolution were tested; with and without ground photons. AGBD models were developed specifically for ICESat-2 segments having land cover as either Evergreen Needleleaf or Deciduous Broadleaf Trees, whereas a generalized boreal-wide AGBD model was developed for ICESat-2 segments whose land cover was neither. Applying our AGBD models to a set of over 19 million ICESat-2 observations yielded a 30 m along-track AGBD product for the pan-boreal. The ability demonstrated herein to calculate ICESat-2 biomass estimates at a 30 m spatial resolution provides the scientific underpinning for a full, spatially explicit, global accounting of aboveground biomass.

Published in Science of Remote Sensing

ISSN: 2666-0172 (Online)
Publisher: Elsevier
Country of publisher: Netherlands
LCC subjects: Geography. Anthropology. Recreation: Physical geography; Science
Website: https://www.sciencedirect.com/journal/science-of-remote-sensing

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