Data

Cumberland Plain FLUXNET Release 2025_r1

Name: Cumberland Plain FLUXNET Release 2025_r1
Published: 2026

Terrestrial Ecosystem Research Network

Pendall, Elise ; Griebel, Anne ; Barton, Craig ; Metzen, Daniel

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ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Adc&rfr_id=info%3Asid%2FANDS&rft_id=info:doi10.25901/xhvd-3485&rft.title=Cumberland Plain FLUXNET Release 2025_r1&rft.identifier=10.25901/xhvd-3485&rft.publisher=Terrestrial Ecosystem Research Network&rft.description=This release consists of flux tower measurements of the exchange of energy and mass between the surface and the atmospheric boundary-layer using eddy covariance techniques. Data were processed using PyFluxPro (v3.4.21) as described by Isaac et al. (2017) for the quality control and post-processing steps. The final, gap-filled product containing Net Ecosystem Exchange (NEE) partitioned into Gross Primary Productivity (GPP) and Ecosystem Respiration (ER) has been produced using the ONEFlux software as described in Pastorello et al (2020). This data set has been produced as part of the FLUXNET Shuttle project. The Cumberland Plain flux station is located in the Hawkesbury Valley in central New South Wales. Operation commenced for the station in September 2012 and is managed by the Hawkesbury Institute for the Environment, Western Sydney University The Cumberland Plain Woodland is now an endangered ecological community that encompasses distinct groupings of plants growing on clayey soils. The canopy is dominated by Eucalyptus moluccana and Eucalyptus fibrosa, which host an expanding population of mistletoe. Average canopy height is 23m, the elevation of the site is 20m and mean annual precipitation is 800mm. Fluxes of water vapour, carbon dioxide and heat are quantified with the open-path eddy flux technique from a 30 m tall mast. Additional measurements above the canopy include temperature, humidity, wind speed and direction, rainfall, incoming and reflected shortwave and longwave radiation and net, diffuse and direct radiation and the photochemical reflectance index. In addition, profiles of humidity and CO2 are measured at eight levels within the canopy, as well as measurements of soil moisture content, soil heat fluxes, soil temperature, and 10-hr fuel moisture dynamics. In addition, regular monitoring of understory species abundance, mistletoe infection, leaf area index and litterfall are also performed.Data collected using standard eddy covariance and meteorological instrumentation on a 30m tower at the Cumberland Plain site. The data were quality controlled using the PyFluxPro software package, see Isaac et al (2017), which is available at https://github.com/OzFlux/PyFluxPro. Gap filling and partitioning has been done using the ONEFlux software package, see Pastorello et al 2020, which is available at https://github.com/fluxnet/ONEFlux.Data CreationData is measured using standard micro-meteorological instrumentation on a flux tower.Data is recorded on a data logger and is collected by the site PI.Data quality control including removal of data outside plausible ranges, removal of spikes, exclusion of particular date ranges and removal of data based on the dependence of one variable on another is done using PyFluxPro.Filtering for low-ustar conditions, gap filling and partitioning of NEE into GPP and ER are done using ONEFlux.Progress Code: completedMaintenance and Update Frequency: annually&rft.creator=Pendall, Elise &rft.creator=Griebel, Anne &rft.creator=Barton, Craig &rft.creator=Metzen, Daniel &rft.date=2026&rft.edition=2025_r1&rft.coverage=The Cumberland flux tower is located at the University of Western Sydney's Hawkesbury campus in Richmond, New South Wales.&rft.coverage=northlimit=-33.6052; southlimit=-33.6252; westlimit=150.7136; eastLimit=150.7336; projection=EPSG:4326&rft_rights=Creative Commons Attribution 4.0 International Licence http://creativecommons.org/licenses/by/4.0&rft_rights=TERN services are provided on an as-is and as available basis. Users use any TERN services at their discretion and risk. They will be solely responsible for any damage or loss whatsoever that results from such use including use of any data obtained through TERN and any analysis performed using the TERN infrastructure. Web links to and from external, third party websites should not be construed as implying any relationships with and/or endorsement of the external site or its content by TERN. Please advise any work or publications that use this data via the online form at https://www.tern.org.au/research-publications/#reporting&rft_rights=Please cite this dataset as {Author} ({PublicationYear}). {Title}. {Version, as appropriate}. Terrestrial Ecosystem Research Network. Dataset. {Identifier}.&rft_subject=climatologyMeteorologyAtmosphere&rft_subject=environment&rft_subject=NET ECOSYSTEM CO2 EXCHANGE (NEE)&rft_subject=GROSS PRIMARY PRODUCTION (GPP)&rft_subject=RESPIRATION RATE&rft_subject=EARTH SCIENCE&rft_subject=BIOSPHERE&rft_subject=ECOLOGICAL DYNAMICS&rft_subject=ECOSYSTEM FUNCTIONS&rft_subject=VERTICAL WIND VELOCITY/SPEED&rft_subject=WATER VAPOR PROCESSES&rft_subject=CARBON FLUX&rft_subject=EVAPOTRANSPIRATION&rft_subject=ATMOSPHERE&rft_subject=ATMOSPHERIC WATER VAPOR&rft_subject=SOILS&rft_subject=SENSIBLE HEAT FLUX&rft_subject=WATER VAPOR&rft_subject=LATENT HEAT FLUX&rft_subject=LONGWAVE RADIATION&rft_subject=WIND DIRECTION PROFILES&rft_subject=SHORTWAVE RADIATION&rft_subject=RAIN&rft_subject=PRECIPITATION&rft_subject=LIQUID PRECIPITATION&rft_subject=AIR TEMPERATURE&rft_subject=ATMOSPHERIC TEMPERATURE&rft_subject=SURFACE TEMPERATURE&rft_subject=HUMIDITY&rft_subject=Carbon Sequestration Science&rft_subject=ENVIRONMENTAL SCIENCES&rft_subject=SOIL SCIENCES&rft_subject=Ecosystem Function&rft_subject=ECOLOGICAL APPLICATIONS&rft_subject=ATMOSPHERIC SCIENCES&rft_subject=EARTH SCIENCES&rft_subject=Climatology&rft_subject=Meteorology&rft_subject=Climate change impacts and adaptation&rft_subject=net primary productivity of biomass expressed as carbon accumulated in miscellaneous living matter (Micromole per Square Metre Second)&rft_subject=Micromole per Square Metre Second&rft_subject=air temperature (Degree Celsius)&rft_subject=Degree Celsius&rft_subject=downward heat flux at ground level in soil (Watt Square Metre)&rft_subject=Watt Square Metre&rft_subject=ecosystem respiration (Micromole per Square Metre Square Second)&rft_subject=Micromole per Square Metre Square Second&rft_subject=gross primary productivity (Micromole per Square Metre Square Second)&rft_subject=lateral component of wind speed (Metre per Second)&rft_subject=Metre per Second&rft_subject=longitudinal component of wind speed (Metre per Second)&rft_subject=magnitude of surface downward stress (Kilograms per metre per square second)&rft_subject=Kilograms per metre per square second&rft_subject=mass concentration of water vapor in air (Gram per Cubic Metre)&rft_subject=Gram per Cubic Metre&rft_subject=mole fraction of carbon monoxide in dry air (Micromole per Mole)&rft_subject=Micromole per Mole&rft_subject=mole fraction of water vapor in air (Millimole per Mole)&rft_subject=Millimole per Mole&rft_subject=Monin-Obukhov length (Metre)&rft_subject=Metre&rft_subject=net ecosystem exchange (Micromole per Square Metre Second)&rft_subject=net ecosystem productivity (Micromole per Square Metre Second)&rft_subject=relative humidity (Percent)&rft_subject=Percent&rft_subject=soil temperature (Degree Celsius)&rft_subject=surface air pressure (Kilopascal)&rft_subject=Kilopascal&rft_subject=surface downwelling longwave flux in air (Watt per Square Metre)&rft_subject=Watt per Square Metre&rft_subject=surface downwelling shortwave flux in air (Watt per Square Metre)&rft_subject=surface friction velocity (Metre per Second)&rft_subject=surface net downward radiative flux (Watt per Square Metre)&rft_subject=surface upward latent heat flux (Watt per Square Metre)&rft_subject=surface upward mole flux of carbon dioxide (Micromole per Square Metre Second)&rft_subject=surface upward sensible heat flux (Watt per Square Metre)&rft_subject=surface upwelling longwave flux in air (Watt per Square Metre)&rft_subject=surface upwelling shortwave flux in air (Watt per Square Metre)&rft_subject=thickness of rainfall amount (Millimetre)&rft_subject=Millimetre&rft_subject=volume fraction of condensed water in soil (Cubic Metre per Cubic Metre)&rft_subject=Cubic Metre per Cubic Metre&rft_subject=wind from direction (Degree)&rft_subject=Degree&rft_subject=wind speed (Metre per Second)&rft_subject=250 meters - < 500 meters&rft_subject=1 minute - < 1 hour&rft_subject=AU-Cum&rft_subject=FLUXNET ID&rft.type=dataset&rft.language=English Access the data

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Creative Commons Attribution 4.0 International Licence
http://creativecommons.org/licenses/by/4.0

TERN services are provided on an "as-is" and "as available" basis. Users use any TERN services at their discretion and risk. They will be solely responsible for any damage or loss whatsoever that results from such use including use of any data obtained through TERN and any analysis performed using the TERN infrastructure.
Web links to and from external, third party websites should not be construed as implying any relationships with and/or endorsement of the external site or its content by TERN.

Please advise any work or publications that use this data via the online form at https://www.tern.org.au/research-publications/#reporting

Please cite this dataset as {Author} ({PublicationYear}). {Title}. {Version, as appropriate}. Terrestrial Ecosystem Research Network. Dataset. {Identifier}.

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Contact Information

Street Address:
Terrestrial Ecosystem Research Network
Building 1019, 80 Meiers Rd
QLD 4068
Australia
Ph: +61 7 3365 9097

[email protected]

Brief description

This release consists of flux tower measurements of the exchange of energy and mass between the surface and the atmospheric boundary-layer using eddy covariance techniques. Data were processed using PyFluxPro (v3.4.21) as described by Isaac et al. (2017) for the quality control and post-processing steps. The final, gap-filled product containing Net Ecosystem Exchange (NEE) partitioned into Gross Primary Productivity (GPP) and Ecosystem Respiration (ER) has been produced using the ONEFlux software as described in Pastorello et al (2020). This data set has been produced as part of the FLUXNET Shuttle project.
The Cumberland Plain flux station is located in the Hawkesbury Valley in central New South Wales. Operation commenced for the station in September 2012 and is managed by the Hawkesbury Institute for the Environment, Western Sydney University The Cumberland Plain Woodland is now an endangered ecological community that encompasses distinct groupings of plants growing on clayey soils. The canopy is dominated by Eucalyptus moluccana and Eucalyptus fibrosa, which host an expanding population of mistletoe. Average canopy height is 23m, the elevation of the site is 20m and mean annual precipitation is 800mm.

Fluxes of water vapour, carbon dioxide and heat are quantified with the open-path eddy flux technique from a 30 m tall mast. Additional measurements above the canopy include temperature, humidity, wind speed and direction, rainfall, incoming and reflected shortwave and longwave radiation and net, diffuse and direct radiation and the photochemical reflectance index. In addition, profiles of humidity and CO2 are measured at eight levels within the canopy, as well as measurements of soil moisture content, soil heat fluxes, soil temperature, and 10-hr fuel moisture dynamics. In addition, regular monitoring of understory species abundance, mistletoe infection, leaf area index and litterfall are also performed.

Lineage

Data collected using standard eddy covariance and meteorological instrumentation on a 30m tower at the Cumberland Plain site. The data were quality controlled using the PyFluxPro software package, see Isaac et al (2017), which is available at https://github.com/OzFlux/PyFluxPro. Gap filling and partitioning has been done using the ONEFlux software package, see Pastorello et al 2020, which is available at https://github.com/fluxnet/ONEFlux.

Data Creation
Data is measured using standard micro-meteorological instrumentation on a flux tower.
Data is recorded on a data logger and is collected by the site PI.
Data quality control including removal of data outside plausible ranges, removal of spikes, exclusion of particular date ranges and removal of data based on the dependence of one variable on another is done using PyFluxPro.
Filtering for low-ustar conditions, gap filling and partitioning of NEE into GPP and ER are done using ONEFlux.

Progress Code: completed

Maintenance and Update Frequency: annually

Notes

Credit
We at TERN acknowledge the Traditional Owners and Custodians throughout Australia, New Zealand and all nations. We honour their profound connections to land, water, biodiversity and culture and pay our respects to their Elders past, present and emerging.

Purpose
The purpose of the Cumberland Plain flux station is to:

quantify the exchanges of carbon dioxide, water vapour and energy in a dry sclerophyll forest.
characterize the functional behaviour and sensitivity of the different components contributing to the ecosystem carbon balance from sub-daily to multi-annual temporal scales and under climatic variability.
identify the role of hydraulic limitations on constraining ecosystem productivity.
quantify the impact of mistletoe on plant physiological processes and whole ecosystem water vapour and carbon dioxide exchange.
validate remote sensing estimates of different radiation components to obtain accurate regional predictions of fuel moisture.
understand how wood traits and microbial diversity interact to determine rates of wood decay.

Data Quality Information

Data Quality Assessment Scope
local : dataset
The data have been quality controlled using the PyFluxPro software. Quality control checks applied to the data include:<ul style="list-style-type: disc;"> <li>range checks for plausible limits</li> <li>spike detection and removal</li> <li>dependency on other variables</li> <li>manual rejection of date ranges</li></ul> Specific checks applied to the sonic and IRGA data including rejection of points based on the sonic and IRGA diagnostic values and on either automatic gain control (AGC) or CO2 and H2O signal strength, depending upon the configuration of the IRGA. If the data quality is poor, the meteorological data is filled from ERA5 reanalysis data and fluxes are filled using the Marginal Distribution Sampling method. Filled data can be identified by the Quality Controls flags in the dataset. The ONEFlux software used to gap fill and partition this data set also applies a Median Absolute Deviation (MAD) filter to the carbon dioxide, latent heat and sensible heat before the gap filling step.

Isaac P., Cleverly J., McHugh I., van Gorsel E., Ewenz C. and Beringer, J. (2017). OzFlux data: network integration from collection to curation, Biogeosciences, 14: 2903-2928
doi : https://doi.org/10.5194/bg-14-2903-2017

Data Quality Assessment Result
local : Quality Result
No anomalous data detected after quality control.

Created: 2025-12-11

Issued: 2026-03-25

Modified: 2026-03-25

Data time period: 2014-01-01 to 2025-01-01

This dataset is part of a larger collection

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text: The Cumberland flux tower is located at the University of Western Sydney's Hawkesbury campus in Richmond, New South Wales.

Subjects

User Contributed Tags

Other Information

Point-of-truth metadata URL

uri : https://geonetwork.tern.org.au/geonetwork/srv/eng/catalog.search#/metadata/1591c25f-5ad0-4643-8d94-b027281cd27c External Link

Isaac P., Cleverly J., McHugh I., van Gorsel E., Ewenz C. and Beringer, J. (2017). OzFlux data: network integration from collection to curation, Biogeosciences, 14: 2903-2928

doi : https://doi.org/10.5194/bg-14-2903-2017 DOI Link

PyFluxPro

uri : https://github.com/OzFlux/PyFluxPro External Link

ONEFlux

uri : https://github.com/fluxnet/ONEFlux External Link

Pastorello, G., Trotta, C., Canfora, E. et al. The FLUXNET2015 dataset and the ONEFlux processing pipeline for eddy covariance data. Sci Data 7, 225 (2020).

doi : https://doi.org/10.1038/s41597-020-0534-3 DOI Link

Identifiers

URI : geonetwork.tern.org.au/geonetwork/srv/eng/catalog.search#/metadata/1591c25f-5ad0-4643-8d94-b027281cd27c
global : 1591c25f-5ad0-4643-8d94-b027281cd27c