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Deployments of the HydroC™ (CO2/CH4) on stationary and mobile platforms – Merging the trends in the field of platform and sensor development (2011)

Fietzek, Peer ; Kramer, S. ; Esser, D.

IEEXplore

In: In: Oceans 2011. IEEXplore, ., pp. 1-9. ISBN 978-1-4577-1427-6

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Publication Date: 2012-07-06

Description: Dissolved greenhouse gas measurements (GHG) are of increasing importance for science, monitoring agencies and industry. Sensors for dissolved carbon dioxide (CO2) and methane (CH4) are applied in a growing number of applications. At the same time the number of mobile platforms deployed in the field is growing. Modern mobile platforms can sample on spatial and temporal scales that previously were not easily accessible thereby providing cost efficient data. Furthermore a trend towards the interconnection of mixed platforms and sensors is recognizable. The connection between these trends is discussed on the basis of sensor integrations into platforms. An approach between sensor and platform manufacturers becomes necessary to achieve an intelligent combination of contemporary measuring devices and their carriers as well as to make the adaptations on both sides efficient. Instruments of the HydroC™ family were successfully deployed on versatile stationary and mobile platforms, such as AUVs and floats. Platform and application demands for the deployment of dissolved gas sensors on diverse platforms are discussed. Fields of improvement for the instruments are identified to make them more versatile and access further platforms in the future.

Type: Book chapter , NonPeerReviewed

Format: text

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Sediment Trapping by Dams Creates Methane Emission Hot Spots (2013)

Maeck, Andreas ; DelSontro, Tonya ; McGinnis, Daniel F. ; [et al.]

American Chemistry Society

In: Environmental Science & Technology, 47 (15). pp. 8130-8137.

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Publication Date: 2019-09-24

Description: Inland waters transport and transform substantial amounts of carbon and account for 18% of global methane emissions. Large reservoirs with higher areal methane release rates than natural waters contribute significantly to freshwater emissions. However, there are millions of small dams worldwide that receive and trap high loads of organic carbon and can therefore potentially emit significant amounts of methane to the atmosphere. We evaluated the effect of damming on methane emissions in a central European impounded river. Direct comparison of riverine and reservoir reaches, where sedimentation in the latter is increased due to trapping by dams, revealed that the reservoir reaches are the major source of methane emissions (0.23 mmol CH4 m–2 d–1 vs 19.7 mmol CH4 m–2 d–1, respectively) and that areal emission rates far exceed previous estimates for temperate reservoirs or rivers. We show that sediment accumulation correlates with methane production and subsequent ebullitive release rates and may therefore be an excellent proxy for estimating methane emissions from small reservoirs. Our results suggest that sedimentation-driven methane emissions from dammed river hot spot sites can potentially increase global freshwater emissions by up to 7%

Type: Article , PeerReviewed

Format: text

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