A 3-year time series of volatile organic iodocarbons in Bedford Basin, Nova Scotia: a northwestern Atlantic fjord

• Published in: Ocean science Vol. 14; no. 6; pp. 1385 - 1403
• Main Authors: Shi, Qiang, Wallace, Douglas
• Format: Journal Article
• Language: English
• Published: Katlenburg-Lindau Copernicus GmbH 08.11.2018; Copernicus Publications
• Subjects: Alkylation; Biodegradation; Blooms; Coastal environments; Continental shelves; Degradation; Density stratification; Dynamics; Fjords; Fluxes; Freshwater; Inland water environment; Interannual variability; Iodine; Measurement; Microbial degradation; Microorganisms; Natural history; Observations; Organic matter; Oxygen; Oxygen depletion; Photolysis; Seasonal variability; Seasonal variation; Seasonal variations; Shallow water; Stratification; Time series; Volatile organic compounds; Wind speed; Nova Scotia; Canada; Nova Scotia Canada
• ISSN: 1812-0792; 1812-0784; 1812-0792
• DOI: 10.5194/os-14-1385-2018

We report weekly observations of volatile organic iodocarbons (CH3I, CH2ClI and CH2I2) over the time period May 2015 to December 2017 from four depths in Bedford Basin, a coastal fjord (70 m deep) on the Atlantic coast of Canada. The fjord is subject to wintertime mixing, seasonal stratification and bloom dynamics, subsurface oxygen depletion, local input of freshwater, and occasional intrusions of higher-density water from the adjacent continental shelf. Near-surface concentrations showed strong seasonal and sub-seasonal variability, which is compared with other coastal time series. The vertical variation of CH2I2 and CH2ClI within the upper 10 m is consistent with rapid photolysis of CH2I2. Average annual sea-to-air fluxes (46.7 nmol m−2 day−1) of total volatile organic iodine were similar to those observed in other coastal and shelf time series, and polyiodinated compounds contributed 80 % of the total flux. Fluxes were subject to strong interannual variability (a factor of 2) mainly due to wind speed variability. Near-surface net production of CH3I averaged 1 pmol L−1 day−1 and was similar to rates in the English Channel but an order of magnitude higher than in shallow waters of the Kiel Fjord, Germany, possibly due to higher microbial degradation in the latter. The near-bottom (60 m) time series showed evidence of CH3I production associated with organic matter degradation and a possible “switch” from the production of CH3I via an alkylation pathway to the production of CH2I2 by a haloform-type reaction. Near-bottom CH3I production varied strongly between years but was generally ca. 20 times lower than near-surface production.