Harnessing remote sensing to address critical science questions on ocean-atmosphere interactions

Griet Neukermans; Tristan Harmel; Martí Galí; Natalia Rudorff; Jacek Chowdhary; Oleg Dubovik; Chris Hostetler; Yongxiang Hu; Cédric Jamet; Kirk Knobelspiesse; Yoav Lehahn; Pavel Litvinov; Andrew M. Sayer; Brian Ward; Emmanuel Boss; Ilan Koren; Lisa A. Miller

doi:10.1525/elementa.331

Harnessing remote sensing to address critical science questions on ocean-atmosphere interactions

Griet Neukermans
, Tristan Harmel
, Martí Galí
, Natalia Rudorff
, Jacek Chowdhary
, Oleg Dubovik
, Chris Hostetler
, Yongxiang Hu
, Cédric Jamet
, Kirk Knobelspiesse
, Yoav Lehahn
, Pavel Litvinov
, Andrew M. Sayer
, Brian Ward
, Emmanuel Boss
, Ilan Koren
, Lisa A. Miller

Physics

Sorbonne Université
Pôle AFB-Irstea Hydroécologie des Plans d'EAU
Takuvik Joint International Laboratory (Université Laval - CNRS)
Barcelona Supercomputing Center
INPE
Columbia University
University Lille
NASA Langley Research Center
Université du Littoral Côte d'Opale
NASA Goddard Space Flight Center
University of Haifa
GRASP-SAS
Universities Space Research Association
University of Maine
Weizmann Institute of Science Israel
Division of Ocean Sciences

Research output: Contribution to a Journal (Peer & Non Peer) › Review article › peer-review

26 Citations (Scopus)

Abstract

Earth observing systems have proven to be a unique source of long-term synoptic information on numerous physical, chemical and biological parameters on a global scale. Merging this information for integrated studies that peruse key questions about the ocean-atmosphere interface is, however, very challenging. Such studies require interdisciplinary frameworks and novel insights into ways to address the problem. We present here a perspective review on how current and emerging remote sensing technologies could help address two scientific questions within the Surface Ocean-Lower Atmosphere Study (SOLAS) science plan: (1) to what extent does upper-ocean biology affect the composition and radiative properties of the marine boundary layer; and (2) to what extent does upper-ocean turbulence drive fluxes of mass and energy at the air-sea interface. We provide a thorough review of how these questions have been addressed and discuss novel potential avenues using multiplatform space-borne missions, from visible to microwave, active and passive sensors.

Original language	English
Article number	71
Journal	Elementa
Volume	6
DOIs	https://doi.org/10.1525/elementa.331
Publication status	Published - 2018

Keywords

Atmosphere
Interactions
Interdisciplinarity
Interface
Ocean
Remote sensing

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10.1525/elementa.331

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Neukermans, G., Harmel, T., Galí, M., Rudorff, N., Chowdhary, J., Dubovik, O., Hostetler, C., Hu, Y., Jamet, C., Knobelspiesse, K., Lehahn, Y., Litvinov, P., Sayer, A. M., Ward, B., Boss, E., Koren, I., & Miller, L. A. (2018). Harnessing remote sensing to address critical science questions on ocean-atmosphere interactions. Elementa, 6, Article 71. https://doi.org/10.1525/elementa.331

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abstract = "Earth observing systems have proven to be a unique source of long-term synoptic information on numerous physical, chemical and biological parameters on a global scale. Merging this information for integrated studies that peruse key questions about the ocean-atmosphere interface is, however, very challenging. Such studies require interdisciplinary frameworks and novel insights into ways to address the problem. We present here a perspective review on how current and emerging remote sensing technologies could help address two scientific questions within the Surface Ocean-Lower Atmosphere Study (SOLAS) science plan: (1) to what extent does upper-ocean biology affect the composition and radiative properties of the marine boundary layer; and (2) to what extent does upper-ocean turbulence drive fluxes of mass and energy at the air-sea interface. We provide a thorough review of how these questions have been addressed and discuss novel potential avenues using multiplatform space-borne missions, from visible to microwave, active and passive sensors.",

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author = "Griet Neukermans and Tristan Harmel and Mart{\'i} Gal{\'i} and Natalia Rudorff and Jacek Chowdhary and Oleg Dubovik and Chris Hostetler and Yongxiang Hu and C{\'e}dric Jamet and Kirk Knobelspiesse and Yoav Lehahn and Pavel Litvinov and Sayer, \{Andrew M.\} and Brian Ward and Emmanuel Boss and Ilan Koren and Miller, \{Lisa A.\}",

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AU - Neukermans, Griet

AU - Harmel, Tristan

AU - Galí, Martí

AU - Rudorff, Natalia

AU - Chowdhary, Jacek

AU - Dubovik, Oleg

AU - Hostetler, Chris

AU - Hu, Yongxiang

AU - Jamet, Cédric

AU - Knobelspiesse, Kirk

AU - Lehahn, Yoav

AU - Litvinov, Pavel

AU - Sayer, Andrew M.

AU - Ward, Brian

AU - Boss, Emmanuel

AU - Koren, Ilan

AU - Miller, Lisa A.

PY - 2018

Y1 - 2018

N2 - Earth observing systems have proven to be a unique source of long-term synoptic information on numerous physical, chemical and biological parameters on a global scale. Merging this information for integrated studies that peruse key questions about the ocean-atmosphere interface is, however, very challenging. Such studies require interdisciplinary frameworks and novel insights into ways to address the problem. We present here a perspective review on how current and emerging remote sensing technologies could help address two scientific questions within the Surface Ocean-Lower Atmosphere Study (SOLAS) science plan: (1) to what extent does upper-ocean biology affect the composition and radiative properties of the marine boundary layer; and (2) to what extent does upper-ocean turbulence drive fluxes of mass and energy at the air-sea interface. We provide a thorough review of how these questions have been addressed and discuss novel potential avenues using multiplatform space-borne missions, from visible to microwave, active and passive sensors.

AB - Earth observing systems have proven to be a unique source of long-term synoptic information on numerous physical, chemical and biological parameters on a global scale. Merging this information for integrated studies that peruse key questions about the ocean-atmosphere interface is, however, very challenging. Such studies require interdisciplinary frameworks and novel insights into ways to address the problem. We present here a perspective review on how current and emerging remote sensing technologies could help address two scientific questions within the Surface Ocean-Lower Atmosphere Study (SOLAS) science plan: (1) to what extent does upper-ocean biology affect the composition and radiative properties of the marine boundary layer; and (2) to what extent does upper-ocean turbulence drive fluxes of mass and energy at the air-sea interface. We provide a thorough review of how these questions have been addressed and discuss novel potential avenues using multiplatform space-borne missions, from visible to microwave, active and passive sensors.

KW - Atmosphere

KW - Interactions

KW - Interdisciplinarity

KW - Interface

KW - Ocean

KW - Remote sensing

UR - https://www.scopus.com/pages/publications/85058192930

U2 - 10.1525/elementa.331

DO - 10.1525/elementa.331

M3 - Review article

SN - 2325-1026

VL - 6

JO - Elementa

JF - Elementa

M1 - 71

ER -

Harnessing remote sensing to address critical science questions on ocean-atmosphere interactions

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Keywords

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