Evaluation of community respiratory mechanisms with oxygen isotopes: A case study in Lake Kinneret

Luz, Boaz; Barkan, Eugeni; Sagi, Yftach; Yacobi, Yosef Z.

doi:10.4319/lo.2002.47.1.0033

Cited by 84 publications

(139 citation statements)

References 38 publications

Supporting

Mentioning

126

Contrasting

Unclassified

Order By: Relevance

“…DO was determined by Winkler titration (Grasshoff et al 1983), with a relative standard deviation of better than 1%. For O 2 isotopic analysis, approximately 150 mL of water was collected in evacuated 300-mL bottles containing 100 mL of saturated HgCl 2 solution to stop biological activity (Emerson et al 1995;Luz et al 2002). The dissolved gases were allowed to equilibrate with the headspace over several days at room temperature.…”

Section: Methodsmentioning

confidence: 99%

“…Hence, respiration leads to a detectable increase in the 18 O : 16 O ratio of O 2 in oxygen-deficient marine and freshwater environments (Bender 1990;Kiddon et al 1993;Parker et al 2005). If the isotope fractionation during respiration (e O ) is known, the spatial distribution of the O 2 18 O : 16 O, or its temporal variation, can yield quantitative information on community respiration rates (Luz et al 2002;Tobias et al 2007). Previous work (Guy et al 1993;Kiddon et al 1993;Bender et al 1994) indicates that the O-isotope effect for dark respiration by bacteria, through the enzyme cytochrome oxidase, is relatively robust, with estimates clustering around 18%.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Aerobic respiration and hypoxia in the Lower St. Lawrence Estuary: Stable isotope ratios of dissolved oxygen constrain oxygen sink partitioning

Lehmann

Barnett

Gélinas

et al. 2009

Limnology & Oceanography

View full text Add to dashboard Cite

We measured the concentration and the stable isotope ratios of dissolved oxygen in the water column in the Estuary and Gulf of St. Lawrence to determine the relative importance of pelagic and benthic dissolved oxygen respiration to the development of hypoxic deep waters. The progressive landward decrease of dissolved oxygen in the bottom waters along the axis of the Laurentian Channel (LC) is accompanied by an increase in the 18 O : 16 O ratio, as would be expected from O-isotope fractionation associated with bacterial oxygen respiration. The apparent O-isotope effect, e O-app , of 10.8% reveals that community O-isotope fractionation is significantly smaller than if bacterial respiration occurred solely in the water column. Our observation can best be explained by a contribution of benthic O 2 consumption occurring with a strongly reduced O-isotope effect at the scale of sediment-water exchange (e O-sed , 7%). The value for e O-sed was estimated from benthic O 2 exchange simulations using a one-dimensional diffusion-reaction O-isotope model. Adopting this e O-sed value, and given the observed community O-isotope fractionation, we calculate that approximately two thirds of the ecosystem respiration occurs within the sediment, in reasonable agreement with direct respiration measurements. Based on the difference between dissolved oxygen concentrations in the deep waters of the Lower St. Lawrence Estuary and in the water that enters the LC at Cabot Strait, we estimate an average respiration rate of 5500 mmol O 2 m 22 yr 21 for the 100-m-thick layer of bottom water along the LC, 3540 mmol O 2 m 22 yr 21 of which is attributed to bacterial benthic respiration.The Laurentian Channel (LC) is a 1200-km-long and more than 300-m-deep submarine valley that originates on the Atlantic continental shelf off Nova Scotia and ends near the mouth of the Saguenay Fjord (Fig. 1). The deep and slow landward flow in the deep waters brings oxygenrich water from the Atlantic Ocean into the Gulf of St. Lawrence (Gilbert et al. 2005). The deep water is separated from the oxygenated surface and the cold intermediate subsurface layer (Gilbert and Pettigrew 1997) by a strong density gradient that inhibits vertical mixing of oxygen-rich surface waters with oxygen-poor bottom water (Fig. 2). Even during winter, water-column convection does not reach beyond 150 m in depth (Galbraith 2006). Thus, isolated from the atmosphere, the bottom water loses oxygen gradually through organic matter respiration as it flows landward along the LC.The bottom water in the Lower St. Lawrence Estuary (LSLE) at the western end of the LC is hypoxic, with dissolved oxygen (O 2 ) concentrations as low as 55 mmol L 21 (Gilbert et al. 2005). The O 2 concentration in the LSLE bottom water has decreased by 50% since 1930 (Gilbert et al. 2005), corresponding to an average depletion of approximately 1 mmol L 21 yr 21 . Gilbert et al. (2005) attributed one half to two thirds of the oxygen depletion to changes in the properties of the deep-water mass that enters the ...

show abstract

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

Aerobic respiration and hypoxia in the Lower St. Lawrence Estuary: Stable isotope ratios of dissolved oxygen constrain oxygen sink partitioning

Lehmann

Barnett

Gélinas

et al. 2009

Limnology & Oceanography

View full text Add to dashboard Cite

show abstract

“…A similar mass balance equation was used by Hendricks et al (2004), but the latter study did not consider the influence of isotopic fractionation during oxygen invasion from and evasion to the atmosphere. Following Luz et al (2002), I include these fractionations here explicitly. I also show how the model could be extended to include bubble injection, which was mentioned but apparently disregarded in the gross production calculations of Stanley et al (2010).…”

Section: Production Respiration and Gas Exchangementioning

confidence: 99%

Technical note: Consistent calculation of aquatic gross production from oxygen triple isotope measurements

Kaiser

2011

Biogeosciences

144

View full text Add to dashboard Cite

Abstract. Oxygen triple isotope measurements can be used to calculate aquatic gross oxygen production rates. Past studies have emphasised the appropriate definition of the 17 O excess and often used an approximation to derive production rates from the 17 O excess. Here, I show that the calculation can be phrased more consistently and without any approximations using the relative 17 O/ 16 O and 18 O/ 16 O isotope ratio differences (delta values) directly. I call this the "dual delta method". The 17 O excess is merely a mathematical construct and the derived production rate is independent of its definition, provided all calculations are performed with a consistent definition. I focus on the mixed layer, but also show how time series of triple isotope measurements below the mixed layer can be used to derive gross production.In the calculation of mixed layer productivity, I explicitly include isotopic fractionation during gas invasion and evasion, which requires the oxygen supersaturation s to be measured as well. I also suggest how bubble injection could be considered in the same mathematical framework. I distinguish between concentration steady state and isotopic steady state and show that only the latter needs to be assumed in the calculation. It is even possible to derive an estimate of the net production rate in the mixed layer that is independent of the assumption of concentration steady state.I review measurements of the parameters required for the calculation of gross production rates and show how their systematic uncertainties as well as the use of different published calculation methods can cause large variations in the production rates for the same underlying isotope ratios. In particular, the 17 O excess of dissolved O 2 in equilibrium with atmospheric O 2 and the 17 O excess of photosynthetic O 2 need to be re-measured. Because of these uncertainties, all calculaCorrespondence to: J. Kaiser (j.kaiser@uea.ac.uk) tion parameters should always be fully documented and the measured relative isotope ratio differences as well as the oxygen supersaturation should be permanently archived, so that improved measurements of the calculation parameters can be used to retrospectively improve production rates.

show abstract

“…For example, spatial patterns are not affected by e, but lower e values give higher P : R and productivity estimates when P : R is larger than 1. Even though our three independent estimates for e were very close to 222%, we explored the effects of alternative e values of 218% and 225%, covering the range commonly reported in previous studies (Kroopnick 1975;Luz et al 2002;Hendricks et al 2004). For the northern Gulf of Mexico shelf adjacent to the Mississippi and Atchafalaya Rivers, e values of 225% did not seem reasonable for either seasonal transects or summer cruises, because P : R values for most stations could not be calculated using e of 225%.…”

Section: Summertime Oxygen Dynamics-thementioning

confidence: 89%

“…Decreasing d 18 O values in response to photosynthesis are due to the addition of isotopically depleted (light) oxygen, derived from ambient water, to the existing dissolved oxygen (DO) pool (Guy et al 1989(Guy et al , 1993, whereby the d 18 O of source water in coastal marine systems ranges from 0% to about 23%. Respiration preferentially removes light oxygen with a large fractionation factor (e of 215% to 225% ;Kroopnick 1975;Luz et al 2002;Hendricks et al 2004), which results in increased d 18 O values for the residual DO pool. Oxygen that is respired within bottom sediments (hereafter referred to as benthic respiration) has a small fractionation effect, ranging from 0% to 23% (Brandes and Devol 1997).…”

mentioning

confidence: 99%

Effects of biological and physical factors on seasonal oxygen dynamics in a stratified, eutrophic coastal ecosystem

Rivera

Wissel

Rabalais

et al. 2009

Limnology & Oceanography

View full text Add to dashboard Cite

Using a dual-budget approach based on oxygen concentrations and stable isotopes, we examined primary production, respiration, and production to respiration ratios (P : R) across the Louisiana continental shelf to determine the relative roles of biological and physical factors in controlling seasonal oxygen dynamics. Regression models for d 18 O and P : R indicated that the concentration of algal biomass explained most of the variability of the seasonal oxygen dynamics in surface waters. Physical factors, such as salinity, temperature, water-column stability, and station depth were only of minor importance. Seasonal oxygen dynamics were more pronounced in bottom waters than in surface waters as hypoxia was common in bottom waters during summer months (MayOctober). During cooler winter months (November-April), oxygen concentrations throughout the water column were close to equilibrium with the atmosphere. The relative importance of benthic respiration to water-column respiration in bottom waters was more pronounced during summer months when the water column was stratified.

show abstract

Evaluation of community respiratory mechanisms with oxygen isotopes: A case study in Lake Kinneret

Cited by 84 publications

References 38 publications

Aerobic respiration and hypoxia in the Lower St. Lawrence Estuary: Stable isotope ratios of dissolved oxygen constrain oxygen sink partitioning

Aerobic respiration and hypoxia in the Lower St. Lawrence Estuary: Stable isotope ratios of dissolved oxygen constrain oxygen sink partitioning

Technical note: Consistent calculation of aquatic gross production from oxygen triple isotope measurements

Effects of biological and physical factors on seasonal oxygen dynamics in a stratified, eutrophic coastal ecosystem

Contact Info

Product

Resources

About