Pönisch, Daniel Lars; Bittig, Henry C; Rehder, Gregor: Bottle data from a coastal peatland at the German Baltic Sea in 2021 [dataset]. PANGAEA, https://doi.pangaea.de/10.1594/PANGAEA.964758 (dataset in review), In: Pönisch, DL et al.: Autonomous high-resolution multiparameter measurements of physico-chemical variables in a coastal peatland that was rewetted with brackish water from the German Baltic Sea [dataset bundled publication]. PANGAEA, https://doi.pangaea.de/10.1594/PANGAEA.964839 (dataset in review)
Abstract:
Rewetting peatlands is an important measure to reduce greenhouse gas (GHG) emissions. However, after rewetting, the areas are highly heterogeneous in terms of GHG exchange, which depends on water level and source, vegetation, previous use, and duration of rewetting. These challenging conditions require new technologies that go beyond discrete sampling. Here we present data from two autonomous lander platforms deployed at the sediment-water interface (bottom lander) of a shallow coastal peatland (approx. 1 m water depth) that was rewetted by brackish water from the Baltic Sea, thus becoming part of the coastal water through a permanent connection. These landers were equipped with six commercially available state-of-the-art sensors, and temporal high-resolution measurements of physico-chemical variables, including partial pressures of carbon dioxide (CO2) and methane (CH4), were made. The resolution of the field data ranged from 10 seconds to 120 minutes and was obtained for partial pressure of CO2 (Contros HydroC-CO2) and CH4 (Contros HydroC-CH4), temperature, salinity, pressure (water depth), oxygen (O2) (CTD-O2 with SBE-37SMP-ODO), the concentrations of phosphate (SBE HydroCycle PO4), nitrate (SBE SUNA V2), chlorophyll a and the turbidity (both with SBE-FLNTUSB ECO) as stationary measurements at two different locations in close proximity. The CTD and oxygen measurements provide exact water depth data for the respective lander locations. In the other data sets (e.g., CO2 measurements) rounded data are inserted instead of the exact depth data, which is 0.6 m for lander_1 and 0.9 m for lander_2. SUNA raw data are provided for completeness. However, we found them of insufficient quality to estimate nitrate concentrations due to interferences and biofouling. The deployment and recovery of the landers, and thus the measurements, took place between 02 June 2021 and 09 August 2021, and the sensors were operated under permanent wired power supply and a centralized timestamp. The sensors were maintained and cleaned bi-weekly. Results show considerable temporal fluctuations expressed as multi-day, diurnal, and event-based variability, with spatial differences caused by biologically-dominated variables.
Keyword(s):
Supplement to:
Pönisch, Daniel Lars; Bittig, Henry C; Kolbe, Martin; Schuffenhauer, Ingo; Otto, Stefan; Premaratne, Kusala; Rehder, Gregor (in prep.): Trace gas variability of CO2 and CH4 in a coastal peatland rewetted with brackish water from the Baltic Sea by autonomous high-resolution measurements.
References:
Bittig, Henry; Körtzinger, Arne; Johnson, K; Claustre, Herve; Emerson, Steve; Fennel, Katja; Garcia, Hernan; Gilbert, Denis; Gruber, Nicolas; Kang, D-J; Naqvi, Wajih; Prakash, Satya; Riser, Steven; Thierry, Virginie; Tilbrook, Bronte; Uchida, Hiroshi; Ulloa, Osvaldo; Xing, Xiaogang (2018): SCOR WG 142: Quality Control Procedures for Oxygen and Other Biogeochemical Sensors on Floats and Gliders. Recommendations on the conversion between oxygen quantities for Bio-Argo floats and other autonomous sensor platforms. Ifremer, https://doi.org/10.13155/45915
Dickson, Andrew G (1990): Standard potential of the reaction: , and and the standard acidity constant of the ion HSO4− in synthetic sea water from 273.15 to 318.15 K. Journal of Chemical Thermodynamics, 22(2), 113-127, https://doi.org/10.1016/0021-9614(90)90074-Z
Dickson, Andrew G; Riley, J P (1979): The estimation of acid dissociation constants in seawater media from potentionmetric titrations with strong base. I. The ionic product of water — Kw. Marine Chemistry, 7(2), 89-99, https://doi.org/10.1016/0304-4203(79)90001-X
Dickson, Andrew G; Sabine, Christopher L; Christian, J R (2007): Guide to Best Practices for Ocean CO2 Measurements. PICES Special Publication, 3, 191 pp, hdl:10013/epic.51789.d001
Gattuso, Jean-Pierre; Epitalon, Jean-Marie; Lavigne, Héloïse; Orr, James (2019): seacarb: Seawater Carbonate Chemistry. R package version 3.2.15. https://CRAN.R-project.org/package=seacarb
Millero, Frank J (2010): Carbonate constants for estuarine waters. Marine and Freshwater Research, 61(2), 139-142, https://doi.org/10.1071/MF09254
Wiesenburg, Denis A; Guinasso Jr., Norman L (1979): Equilibrium solubilities of methane, carbon monoxide, and hydrogen in water and sea water. Journal of Chemical and Engineering Data, 24(4), 356-360, https://doi.org/10.1021/je60083a006
Funding:
German Research Foundation (DFG), grant/award no. 240942083: DFG Research Training Group Baltic TRANSCOAST
Coverage:
Latitude: 54.371818 * Longitude: 13.239514
Date/Time Start: 2021-06-10T09:29:16 * Date/Time End: 2021-08-03T09:55:26
Minimum DEPTH, water: 0.76 m * Maximum DEPTH, water: 1.40 m
Event(s):
Comment:
The calculation of pCO2 was performed using R (R Core Team, 2022) and the package seacarb (Gattuso et al., 2019), with K1 and K2 from (Millero, 2010), Ks from (Dickson, 1990), and Kf from (Dickson and Riley, 1979).
Parameter(s):
License:
Creative Commons Attribution 4.0 International (CC-BY-4.0) (License comes into effect after moratorium ends)
Size:
288 data points