Proximal remote sensing: an essential tool for bridging the gap between high-resolution ecosystem monitoring and global ecology

Zoe Amie Pierrat; Troy S. Magney; Will P. Richardson; Benjamin R.K. Runkle; Jen L. Diehl; Xi Yang; William Woodgate; William K. Smith; Miriam R. Johnston; Yohanes R.S. Ginting; Gerbrand Koren; Loren P. Albert; Christopher L. Kibler; Bryn E. Morgan; Mallory Barnes; Adriana Uscanga; Charles Devine; Mostafa Javadian; Karem Meza; Tommaso Julitta; Giulia Tagliabue; Matthew P. Dannenberg; Michal Antala; Christopher Y.S. Wong; Andre L.D. Santos; Koen Hufkens; Julia K. Marrs; Atticus E.L. Stovall; Yujie Liu; Joshua B. Fisher; John A. Gamon; Kerry Cawse-Nicholson

doi:10.1111/nph.20405

Proximal remote sensing: an essential tool for bridging the gap between high-resolution ecosystem monitoring and global ecology

Zoe Amie Pierrat
, Troy S. Magney
, Will P. Richardson
, Benjamin R.K. Runkle
, Jen L. Diehl
, Xi Yang
, William Woodgate
, William K. Smith
, Miriam R. Johnston
, Yohanes R.S. Ginting
, Gerbrand Koren
, Loren P. Albert
, Christopher L. Kibler
, Bryn E. Morgan
, Mallory Barnes
, Adriana Uscanga
, Charles Devine
, Mostafa Javadian
, Karem Meza
, Tommaso Julitta

Giulia Tagliabue, Matthew P. Dannenberg, Michal Antala, Christopher Y.S. Wong, Andre L.D. Santos, Koen Hufkens, Julia K. Marrs, Atticus E.L. Stovall, Yujie Liu, Joshua B. Fisher, John A. Gamon, Kerry Cawse-Nicholson

Forest Management

Research output: Contribution to journal › Review article › peer-review

16 Scopus citations

Abstract

A new proliferation of optical instruments that can be attached to towers over or within ecosystems, or ‘proximal’ remote sensing, enables a comprehensive characterization of terrestrial ecosystem structure, function, and fluxes of energy, water, and carbon. Proximal remote sensing can bridge the gap between individual plants, site-level eddy-covariance fluxes, and airborne and spaceborne remote sensing by providing continuous data at a high-spatiotemporal resolution. Here, we review recent advances in proximal remote sensing for improving our mechanistic understanding of plant and ecosystem processes, model development, and validation of current and upcoming satellite missions. We provide current best practices for data availability and metadata for proximal remote sensing: spectral reflectance, solar-induced fluorescence, thermal infrared radiation, microwave backscatter, and LiDAR. Our paper outlines the steps necessary for making these data streams more widespread, accessible, interoperable, and information-rich, enabling us to address key ecological questions unanswerable from space-based observations alone and, ultimately, to demonstrate the feasibility of these technologies to address critical questions in local and global ecology.

Original language	English
Pages (from-to)	419-436
Number of pages	18
Journal	New Phytologist
Volume	246
Issue number	2
DOIs	https://doi.org/10.1111/nph.20405
State	Published - Apr 2025

Keywords

biodiversity
canopy structure
ecosystem flux
eddy covariance
phenology
proximal remote sensing
scaling
spectral biology
Environmental Monitoring/methods
Remote Sensing Technology/methods
Ecology/methods
Internationality
Ecosystem

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1111/nph.20405

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Pierrat, Z. A., Magney, T. S., Richardson, W. P., Runkle, B. R. K., Diehl, J. L., Yang, X., Woodgate, W., Smith, W. K., Johnston, M. R., Ginting, Y. R. S., Koren, G., Albert, L. P., Kibler, C. L., Morgan, B. E., Barnes, M., Uscanga, A., Devine, C., Javadian, M., Meza, K., ... Cawse-Nicholson, K. (2025). Proximal remote sensing: an essential tool for bridging the gap between high-resolution ecosystem monitoring and global ecology. New Phytologist, 246(2), 419-436. https://doi.org/10.1111/nph.20405

@article{cbde9c3505f540d99a5ee26e24493bf8,

title = "Proximal remote sensing: an essential tool for bridging the gap between high-resolution ecosystem monitoring and global ecology",

abstract = "A new proliferation of optical instruments that can be attached to towers over or within ecosystems, or {\textquoteleft}proximal{\textquoteright} remote sensing, enables a comprehensive characterization of terrestrial ecosystem structure, function, and fluxes of energy, water, and carbon. Proximal remote sensing can bridge the gap between individual plants, site-level eddy-covariance fluxes, and airborne and spaceborne remote sensing by providing continuous data at a high-spatiotemporal resolution. Here, we review recent advances in proximal remote sensing for improving our mechanistic understanding of plant and ecosystem processes, model development, and validation of current and upcoming satellite missions. We provide current best practices for data availability and metadata for proximal remote sensing: spectral reflectance, solar-induced fluorescence, thermal infrared radiation, microwave backscatter, and LiDAR. Our paper outlines the steps necessary for making these data streams more widespread, accessible, interoperable, and information-rich, enabling us to address key ecological questions unanswerable from space-based observations alone and, ultimately, to demonstrate the feasibility of these technologies to address critical questions in local and global ecology.",

keywords = "biodiversity, canopy structure, ecosystem flux, eddy covariance, phenology, proximal remote sensing, scaling, spectral biology, Environmental Monitoring/methods, Remote Sensing Technology/methods, Ecology/methods, Internationality, Ecosystem",

author = "Pierrat, \{Zoe Amie\} and Magney, \{Troy S.\} and Richardson, \{Will P.\} and Runkle, \{Benjamin R.K.\} and Diehl, \{Jen L.\} and Xi Yang and William Woodgate and Smith, \{William K.\} and Johnston, \{Miriam R.\} and Ginting, \{Yohanes R.S.\} and Gerbrand Koren and Albert, \{Loren P.\} and Kibler, \{Christopher L.\} and Morgan, \{Bryn E.\} and Mallory Barnes and Adriana Uscanga and Charles Devine and Mostafa Javadian and Karem Meza and Tommaso Julitta and Giulia Tagliabue and Dannenberg, \{Matthew P.\} and Michal Antala and Wong, \{Christopher Y.S.\} and Santos, \{Andre L.D.\} and Koen Hufkens and Marrs, \{Julia K.\} and Stovall, \{Atticus E.L.\} and Yujie Liu and Fisher, \{Joshua B.\} and Gamon, \{John A.\} and Kerry Cawse-Nicholson",

note = "{\textcopyright} 2025 The Author(s). New Phytologist {\textcopyright} 2025 New Phytologist Foundation.",

year = "2025",

month = apr,

doi = "10.1111/nph.20405",

language = "English",

volume = "246",

pages = "419--436",

journal = "New Phytologist",

issn = "0028-646X",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "2",

}

Pierrat, ZA, Magney, TS, Richardson, WP, Runkle, BRK, Diehl, JL, Yang, X, Woodgate, W, Smith, WK, Johnston, MR, Ginting, YRS, Koren, G, Albert, LP, Kibler, CL, Morgan, BE, Barnes, M, Uscanga, A, Devine, C, Javadian, M, Meza, K, Julitta, T, Tagliabue, G, Dannenberg, MP, Antala, M, Wong, CYS, Santos, ALD, Hufkens, K, Marrs, JK, Stovall, AEL, Liu, Y, Fisher, JB, Gamon, JA & Cawse-Nicholson, K 2025, 'Proximal remote sensing: an essential tool for bridging the gap between high-resolution ecosystem monitoring and global ecology', New Phytologist, vol. 246, no. 2, pp. 419-436. https://doi.org/10.1111/nph.20405

TY - JOUR

T1 - Proximal remote sensing

T2 - an essential tool for bridging the gap between high-resolution ecosystem monitoring and global ecology

AU - Pierrat, Zoe Amie

AU - Magney, Troy S.

AU - Richardson, Will P.

AU - Runkle, Benjamin R.K.

AU - Diehl, Jen L.

AU - Yang, Xi

AU - Woodgate, William

AU - Smith, William K.

AU - Johnston, Miriam R.

AU - Ginting, Yohanes R.S.

AU - Koren, Gerbrand

AU - Albert, Loren P.

AU - Kibler, Christopher L.

AU - Morgan, Bryn E.

AU - Barnes, Mallory

AU - Uscanga, Adriana

AU - Devine, Charles

AU - Javadian, Mostafa

AU - Meza, Karem

AU - Julitta, Tommaso

AU - Tagliabue, Giulia

AU - Dannenberg, Matthew P.

AU - Antala, Michal

AU - Wong, Christopher Y.S.

AU - Santos, Andre L.D.

AU - Hufkens, Koen

AU - Marrs, Julia K.

AU - Stovall, Atticus E.L.

AU - Liu, Yujie

AU - Fisher, Joshua B.

AU - Gamon, John A.

AU - Cawse-Nicholson, Kerry

PY - 2025/4

Y1 - 2025/4

N2 - A new proliferation of optical instruments that can be attached to towers over or within ecosystems, or ‘proximal’ remote sensing, enables a comprehensive characterization of terrestrial ecosystem structure, function, and fluxes of energy, water, and carbon. Proximal remote sensing can bridge the gap between individual plants, site-level eddy-covariance fluxes, and airborne and spaceborne remote sensing by providing continuous data at a high-spatiotemporal resolution. Here, we review recent advances in proximal remote sensing for improving our mechanistic understanding of plant and ecosystem processes, model development, and validation of current and upcoming satellite missions. We provide current best practices for data availability and metadata for proximal remote sensing: spectral reflectance, solar-induced fluorescence, thermal infrared radiation, microwave backscatter, and LiDAR. Our paper outlines the steps necessary for making these data streams more widespread, accessible, interoperable, and information-rich, enabling us to address key ecological questions unanswerable from space-based observations alone and, ultimately, to demonstrate the feasibility of these technologies to address critical questions in local and global ecology.

AB - A new proliferation of optical instruments that can be attached to towers over or within ecosystems, or ‘proximal’ remote sensing, enables a comprehensive characterization of terrestrial ecosystem structure, function, and fluxes of energy, water, and carbon. Proximal remote sensing can bridge the gap between individual plants, site-level eddy-covariance fluxes, and airborne and spaceborne remote sensing by providing continuous data at a high-spatiotemporal resolution. Here, we review recent advances in proximal remote sensing for improving our mechanistic understanding of plant and ecosystem processes, model development, and validation of current and upcoming satellite missions. We provide current best practices for data availability and metadata for proximal remote sensing: spectral reflectance, solar-induced fluorescence, thermal infrared radiation, microwave backscatter, and LiDAR. Our paper outlines the steps necessary for making these data streams more widespread, accessible, interoperable, and information-rich, enabling us to address key ecological questions unanswerable from space-based observations alone and, ultimately, to demonstrate the feasibility of these technologies to address critical questions in local and global ecology.

KW - biodiversity

KW - canopy structure

KW - ecosystem flux

KW - eddy covariance

KW - phenology

KW - proximal remote sensing

KW - scaling

KW - spectral biology

KW - Environmental Monitoring/methods

KW - Remote Sensing Technology/methods

KW - Ecology/methods

KW - Internationality

KW - Ecosystem

UR - https://www.scopus.com/pages/publications/105001077205

U2 - 10.1111/nph.20405

DO - 10.1111/nph.20405

M3 - Review article

C2 - 39853577

AN - SCOPUS:105001077205

SN - 0028-646X

VL - 246

SP - 419

EP - 436

JO - New Phytologist

JF - New Phytologist

IS - 2

ER -

Proximal remote sensing: an essential tool for bridging the gap between high-resolution ecosystem monitoring and global ecology

Abstract

Keywords

UN SDGs

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