Eddy Flux Measurements, Pleistocene Park, Cherskii, Russia - 2015


In contribution to the Arctic Observing Network, the researchers have established two observatories of landscape-level carbon, water and energy balances at Imnaviat Creek, Alaska and at Pleistocene Park near Cherskii, Russia.  These will form part of a network of obervatories with Abisko (Sweden), Zackenburg (Greenland) and a location in the Canadian High Arctic which will provide further data  points as part of the International Polar Year.  This particular part of the project focuses on simultaneous measurements of carbon, water and energy fluxes of the terrestrial landscape at hourly, daily, seasonal and multi-year time scales.  These are the major regulatory drivers of the Arctic climate system and form key linkages and feedbacks between the land surface, the atmosphere and the oceans.
In support of these objectives, a new 32m tower was deployed in Pleistocene Park, about 20km south of North-East Science Station in Cherskii, Russia.  This station is currently measuring fluxes of carbon dioxide, methane, water vapor and energy in addition to other meteorological variables. 

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Published on EDI/LTER Data Portal


Bret-harte, M., Zimov, S., Euskirchen, E., Shaver, G. 2017. Eddy Flux Measurements, Pleistocene Park, Cherskii, Russia - 2015 Environmental Data Initiative. http://dx.doi.org/10.6073/pasta/7faa303fb88e25c6a4100656d779e372

Date Range: 

Thursday, January 1, 2015 to Friday, November 20, 2015

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Similar to the other flux stations involved in the AON project, the Pleistocene Park Station generates two types of data: high frequency eddy covariance (EC) data and low frequency means of meteorological and subsurface data.  On a daily basis, approximately 75Mb of high frequency binary data and 16Kb of low frequency ASCII data is collected.

This station uses a CR3000 datalogger and a laptop to collect and store data.  The CR3000 is used to measure the open-path EC equipment which is sampled at 10Hz.  Mircrometeorlogical data is scanned at 0.33Hz and all datapoints are averaged every half hour.  The CRBASIC program that controls the datalogger has been written in such a way that only the most basic corrections and filtering are applied to the raw data.  These would include shifting the CSAT3 and LI7500 data arrays by 2 and 3 scans respectively to account for the inherent processing delays of these sensors. 

About Data Processing
Time is expessed as local time, AST (UTC-9hrs) for Imnavait and MAGST (UTC+12hrs) for Pleistocene Park
Gas and energy fluxes are calculated from the high frequency time series using EdiRe or EddyPro software with these basic corrections:  despiking, coordinate rotation, spectral correction, the 'WPL' correction, and the 'Burba' correction (where appropriate, to account for instrument heating effects).
Some data have been filtered (_f) and gap-filled (_gf).
The generation of mass and energy fluxes from the high frequency data is performed with the following basic corrections:
The 'WPL' correction
A coordinate rotation
A spectral correction
The 'Burba' correction (where appropriate to account for instrument heating effect)
*Correct instrument lag adjustment occurs during datalogging
The following QA/QC variables are applied to the flux data:
Stationarity tests
Footprint analysis
Gas analyzer diagnostics are used as a QA/QC variable for both flux and radiation data
Rejection angles of 10° at Imnavait and 45° at Pleistocene Park are used when EC instruments were downwind of tower to remove flow distortions 
The flux and meteorological data is further post-processed to accomplish the following:
Data are within engineering specifications of each instrument. 
Removal of impossible measurements (e.g. negative precipitation)
Removal of outliers via a three-standard deviation filter
Removal of unrealistic changes in a time series with a step change filter
A similarity filter to remove errors from instruments that generate a string of identical values when not working

Flux variables are calculated using Licor's EddyPro flux processing software. The quality control flags for flux variables (either raw or filtered) are calculated using the Mauder and Foken (2004) method within the EddyPro. Flag values and meanings are available on the Licor web site at https://www.licor.com/env/help/eddypro/topics_eddypro/Flux_Quality_Flags...

Gaps in the data are filled using the BGC_Jena gapfilling tool ReddyProc.  Information on the gap-filling protocol is available here, https://www.bgc-jena.mpg.de/bgi/index.php/Services/REddyProcWebGapFilling. The meaning of the quality control flags for all gap-filled (_gf) variables is listed here (https://www.bgc-jena.mpg.de/bgi/index.php/Services/REddyProcWebOutput) under the _fqc entry.

See the file 2015_CH_2044_metadata_20151120.csv for data collection statistics.

Version Changes: 

Jan 2018-Version 1: Dataset first available
June 2019-Version 3: Updated metadata, removing abbreviations. Added detail to site descriptions. BK
Oct2019-Version 4: Units in metadata were incorrect; max and min values were added to the unit name. Jim L

Sites sampled.

Full Metadata and data files (either comma delimited (csv) or Excel) - Environmental Data Initiative repository.

Use of the data requires acceptance of the data use policy --> Arctic LTER Data Use Policy