Inland Waters as a Part of the Terrestrial Carbon Cycle – Estimations and Uncertainties

Inlandsvatten, exempelvis sjöar och floder, har en betydande roll för den globala kolcykeln. Förutom att dessa vatten transporterar kol mellan kontinenterna och havet så förekommer en mängd processer som påverkar kolomsättningen i dessa system. Inlandsvatten kan fånga in (fixera) koldioxid från atmosfären via fotosyntes, men en stor del av kolet i inlandsvatten transporteras från land. Detta kol kan antingen emitteras till atmosfären som koldioxid eller metan, lagras på botten av sjöar och reservoarer eller transporteras (exporteras) till havet genom floder och grundvatten. Genom att sammanställa litteratur som i huvudsak publicerats mellan 2007 och 2017 konkluderas att 3,6 Pg C y-1 transporteras till inlandsvatten från världens kontinenter. Av detta emitteras 2,3 Pg C y-1 till atmosfären innan det når havet, 0,15 Pg C y-1 sedimenteras i sjöar och dammar medan 1,1 Pg C-1 exporteras till havet. För att förstå hur människan påverkar kolomsättningen globalt krävs en korrekt beskrivning av de naturliga flödena av kol mellan hav, land och atmosfär. Förbättringspotential och osäkerheter gällande den kvantitativa uppskattningen om inlandsvatten som en del i den terrestra kolcykeln finns bland annat kopplat till små vattenansamlingar, då dessa inte är fullständigt kartlagda. En bättre geografisk spridning för den data som ligger till grund för globala uppskattningar krävs också för att förbättra förståelsen för inlandsvattens roll i den terrestra kolcykeln.Inland waters, for example lakes and rivers, play a considerable role in the global carbon cycle. In addition to transport carbon between the continents and the oceans, a number of processes occur during the transport along the hydrological chain. Inland water could directly take up carbon dioxide from the atmosphere though photosynthesis, but a vast amount of the carbon origins from land. The carbon could either be emitted to the atmosphere as carbon dioxide or methane, stored at the bottom of lakes or reservoirs and/or transported (exported) to the ocean through rivers or groundwater. In this study, publications from 2007 to 2017 were reviewed, and the conclusion is drawn that 3,6 Pg C y-1 are exported to inland waters from land. 2,3 Pg C y-1 are emitted to the atmosphere, 0,15 Pg C y-1 is buried in the sediments of lakes and reservoirs and 1,1 Pg C y-1 is exported to the ocean. To understand how human affects the global carbon budget, a correct description of the natural migration of carbon between the ocean, the continents and the atmosphere is needed. Potential of improvement and uncertainties related to the quantitative estimates of emission, sedimentation and export are to a large extent connected to the poor surveys of small lakes and ponds. A more representative global distribution of the data is also needed for a better understanding of the role of inland waters in the terrestrial carbon cycle

Inland Waters as a Part of the Terrestrial Carbon Cycle – Estimations and Uncertainties

Inlandsvatten, exempelvis sjöar och floder, har en betydande roll för den globala kolcykeln. Förutom att dessa vatten transporterar kol mellan kontinenterna och havet så förekommer en mängd processer som påverkar kolomsättningen i dessa system. Inlandsvatten kan fånga in (fixera) koldioxid från atmosfären via fotosyntes, men en stor del av kolet i inlandsvatten transporteras från land. Detta kol kan antingen emitteras till atmosfären som koldioxid eller metan, lagras på botten av sjöar och reservoarer eller transporteras (exporteras) till havet genom floder och grundvatten. Genom att sammanställa litteratur som i huvudsak publicerats mellan 2007 och 2017 konkluderas att 3,6 Pg C y-1 transporteras till inlandsvatten från världens kontinenter. Av detta emitteras 2,3 Pg C y-1 till atmosfären innan det når havet, 0,15 Pg C y-1 sedimenteras i sjöar och dammar medan 1,1 Pg C-1 exporteras till havet. För att förstå hur människan påverkar kolomsättningen globalt krävs en korrekt beskrivning av de naturliga flödena av kol mellan hav, land och atmosfär. Förbättringspotential och osäkerheter gällande den kvantitativa uppskattningen om inlandsvatten som en del i den terrestra kolcykeln finns bland annat kopplat till små vattenansamlingar, då dessa inte är fullständigt kartlagda. En bättre geografisk spridning för den data som ligger till grund för globala uppskattningar krävs också för att förbättra förståelsen för inlandsvattens roll i den terrestra kolcykeln.Inland waters, for example lakes and rivers, play a considerable role in the global carbon cycle. In addition to transport carbon between the continents and the oceans, a number of processes occur during the transport along the hydrological chain. Inland water could directly take up carbon dioxide from the atmosphere though photosynthesis, but a vast amount of the carbon origins from land. The carbon could either be emitted to the atmosphere as carbon dioxide or methane, stored at the bottom of lakes or reservoirs and/or transported (exported) to the ocean through rivers or groundwater. In this study, publications from 2007 to 2017 were reviewed, and the conclusion is drawn that 3,6 Pg C y-1 are exported to inland waters from land. 2,3 Pg C y-1 are emitted to the atmosphere, 0,15 Pg C y-1 is buried in the sediments of lakes and reservoirs and 1,1 Pg C y-1 is exported to the ocean. To understand how human affects the global carbon budget, a correct description of the natural migration of carbon between the ocean, the continents and the atmosphere is needed. Potential of improvement and uncertainties related to the quantitative estimates of emission, sedimentation and export are to a large extent connected to the poor surveys of small lakes and ponds. A more representative global distribution of the data is also needed for a better understanding of the role of inland waters in the terrestrial carbon cycle

Inland Waters as a Part of the Terrestrial Carbon Cycle – Estimations and Uncertainties

Inlandsvatten, exempelvis sjöar och floder, har en betydande roll för den globala kolcykeln. Förutom att dessa vatten transporterar kol mellan kontinenterna och havet så förekommer en mängd processer som påverkar kolomsättningen i dessa system. Inlandsvatten kan fånga in (fixera) koldioxid från atmosfären via fotosyntes, men en stor del av kolet i inlandsvatten transporteras från land. Detta kol kan antingen emitteras till atmosfären som koldioxid eller metan, lagras på botten av sjöar och reservoarer eller transporteras (exporteras) till havet genom floder och grundvatten. Genom att sammanställa litteratur som i huvudsak publicerats mellan 2007 och 2017 konkluderas att 3,6 Pg C y-1 transporteras till inlandsvatten från världens kontinenter. Av detta emitteras 2,3 Pg C y-1 till atmosfären innan det når havet, 0,15 Pg C y-1 sedimenteras i sjöar och dammar medan 1,1 Pg C-1 exporteras till havet. För att förstå hur människan påverkar kolomsättningen globalt krävs en korrekt beskrivning av de naturliga flödena av kol mellan hav, land och atmosfär. Förbättringspotential och osäkerheter gällande den kvantitativa uppskattningen om inlandsvatten som en del i den terrestra kolcykeln finns bland annat kopplat till små vattenansamlingar, då dessa inte är fullständigt kartlagda. En bättre geografisk spridning för den data som ligger till grund för globala uppskattningar krävs också för att förbättra förståelsen för inlandsvattens roll i den terrestra kolcykeln.Inland waters, for example lakes and rivers, play a considerable role in the global carbon cycle. In addition to transport carbon between the continents and the oceans, a number of processes occur during the transport along the hydrological chain. Inland water could directly take up carbon dioxide from the atmosphere though photosynthesis, but a vast amount of the carbon origins from land. The carbon could either be emitted to the atmosphere as carbon dioxide or methane, stored at the bottom of lakes or reservoirs and/or transported (exported) to the ocean through rivers or groundwater. In this study, publications from 2007 to 2017 were reviewed, and the conclusion is drawn that 3,6 Pg C y-1 are exported to inland waters from land. 2,3 Pg C y-1 are emitted to the atmosphere, 0,15 Pg C y-1 is buried in the sediments of lakes and reservoirs and 1,1 Pg C y-1 is exported to the ocean. To understand how human affects the global carbon budget, a correct description of the natural migration of carbon between the ocean, the continents and the atmosphere is needed. Potential of improvement and uncertainties related to the quantitative estimates of emission, sedimentation and export are to a large extent connected to the poor surveys of small lakes and ponds. A more representative global distribution of the data is also needed for a better understanding of the role of inland waters in the terrestrial carbon cycle

A Simplified Drying Procedure for Analysing Hg Concentrations

Mercury (Hg) in peatlands remains a problem of global interest. To mitigate the risks of this neurotoxin, accurate assessments of Hg in peat are needed. Treatment of peat that will be analysed for Hg is, however, not straightforward due to the volatile nature of Hg. The drying process is of particular concern since Hg evasion increases with the temperature. Samples are, therefore, often freeze-dried to limit Hg loss during the drying processes. A problem with freeze-drying is that cost and equipment resources can limit the number of samples analysed in large projects. To avoid this bottleneck, we tested if drying in a 60 degrees C-degree oven could be an acceptable alternative to freeze-drying. We both freeze-dried and oven-dried (60 degrees C) 203 replicate pairs of peat samples, and then examined the differences in total Hg concentration. The Hg concentration differed significantly between the two drying methods with a median Hg deficit in oven-dried samples of 4.2%. Whether a 4.2% deficit of Hg depends on one's purpose. The lower median Hg concentration in oven-dried samples has to be weighed against the upside efficiently drying large sets of peat samples. By freeze-drying a subset of the samples, we fitted a function to correct for Hg loss during oven-drying (y = 0.96x + 0.08). By applying this correction, the freeze-drying bottleneck could oven-dry large-scale inventories of total Hg in peatlands with results equivalent to freeze-drying, but only have to freeze-dry a subset

Limb salvage and reconstruction following a zebra attack

Animal bites are fairly rare events but can cause devastating traumatic injuries to the victim. In addition to the soft tissue, vascular, and orthopedic trauma inflicted by these occurrences, bite injuries also have the potential to introduce an inoculum of microbes, which may progress to an infection if not treated properly and expeditiously.We present the case of a healthy male who sustained multiple bite wounds from a domestic zebra to his left upper extremity. This attack caused severe damage, including devascularization of the arm at the brachial artery, disruption of the distal biceps and brachialis, stripping of the forearm nerves, and shearing of the overlying soft tissue. The patient was taken emergently to the operating room for revascularization of the extremity utilizing a vein bypass graft. The soft tissue injuries were addressed with numerous irrigation and debridement procedures, during which coverage of the vein bypass graft was obtained using a variety of techniques, including skin flaps, musculocutaneous advancements, and the application of an acellular dermal matrix (AlloDerm) and a collagen-glycosaminoglycan matrix (Integra).Wound cultures obtained intra-operatively during the irrigation and debridement procedures were notable for the growth of multiple microbes, including Rhodococcus spp., which have been documented to cause infection in immunocompromised patients. The patient in this case was treated with a prolonged course of antibiotics, and wound cultures negative for microbial growth were eventually obtained prior to final closure of his wound. The patient then underwent successful biceps reconstruction with a pedicled latissimus dorsi muscle transfer. This case documents the extraordinary multidisciplinary approach provided in the salvage, management, and eventual reconstruction of a mangled left upper extremity that had sustained devastating traumatic injuries resulting from a rather unusual source. Keywords: Zebra, Bite, Rhodococcus, Salvage, Reconstructio

Greenhouse gas emissions from urban ponds are driven by nutrient status and hydrology

Inland waters emit significant quantities of greenhouse gases (GHGs) such as methane (CH4) and carbon dioxide (CO2) to the atmosphere. On a global scale, these emissions are large enough that their contribution to climate change is now recognized by the Intergovernmental Panel on Climate Change. Much of the past focus on GHG emissions from inland waters has focused on lakes, reservoirs, and rivers, and the role of small, artificial waterbodies such as ponds has been overlooked. To investigate the spatial variation in GHG fluxes from artificial ponds, we conducted a synoptic survey of forty urban ponds in a Swedish city. We measured dissolved concentrations of CH4 and CO2, and made complementary measurements of water chemistry. We found that CH4 concentrations were greatest in high-nutrient ponds (measured as total phosphorus and total organic carbon). For CO2, higher concentrations were associated with silicon and calcium, suggesting that groundwater inputs lead to elevated CO2. When converted to diffusive GHG fluxes, mean emissions were 30.3 mg CH4.m-2 .d-1 and 752 mg CO2.m-2 .d-1 . Although these fluxes are moderately high on an areal basis, upscaling them to all Swedish urban ponds gives an emission of 8336 t CO2eq/yr (+/-1689) equivalent to 0.1% of Swedish agricultural GHG emissions. Artificial ponds could be important GHG sources in countries with larger proportions of urban land