Is there warming in the pipeline? A multi-model analysis of the Zero Emissions Commitment from CO2 Biogeosciences DOI 10.5194/bg-17-2987-2020 25 June 2020 The Zero Emissions Commitment (ZEC) is the change in global temperature expected to occur following the complete cessation of CO 2 emissions. Here we use 18 climate models to assess the value of ZEC. For our experiment we find that ZEC 50 years after emissions cease is between −0.36 to +0.29 °C. The most likely value of ZEC is assessed to be close to zero. However, substantial continued warming for decades or centuries following cessation of CO 2 emission cannot be ruled out. Read more
RainNet v1.0: a convolutional neural network for radar-based precipitation nowcasting Geoscientific Model Development DOI 10.5194/gmd-13-2631-2020 23 June 2020 In this study, we present RainNet, a deep convolutional neural network for radar-based precipitation nowcasting, which was trained to predict continuous precipitation intensities at a lead time of 5 min. RainNet significantly outperformed the benchmark models at all lead times up to 60 min. Yet, an undesirable property of RainNet predictions is the level of spatial smoothing. Obviously, RainNet learned an optimal level of smoothing to produce a nowcast at 5 min lead time. Read more
Changing global cropping patterns to minimize national blue water scarcity Hydrology and Earth System Sciences DOI 10.5194/hess-24-3015-2020 18 June 2020 Previous studies on water saving through food trade focussed either on comparing water productivities among countries or on analysing food trade in relation to national water endowments. Here, we consider, for the first time, both differences in water productivities and water endowments to analyse national comparative advantages. Our study reveals that blue water scarcity can be reduced to sustainable levels by changing cropping patterns while maintaining current levels of global production. Read more
New observations of the distribution, morphology and dissolution dynamics of cryogenic gypsum in the Arctic Ocean The Cryosphere DOI 10.5194/tc-14-1795-2020 16 June 2020 Based on an observed omnipresence of gypsum crystals, we concluded that their release from melting sea ice is a general feature in the Arctic Ocean. Individual gypsum crystals sank at more than 7000 m d −1 , suggesting that they are an important ballast mineral. Previous observations found gypsum inside phytoplankton aggregates at 2000 m depth, supporting gypsum as an important driver for pelagic-benthic coupling in the ice-covered Arctic Ocean. Read more
Induced seismicity risk analysis of the hydraulic stimulation of a geothermal well on Geldinganes, Iceland Natural Hazards and Earth System Sciences DOI 10.5194/nhess-20-1573-2020 16 June 2020 This study presents a first-of-its-kind pre-drilling probabilistic induced seismic risk analysis for the Geldinganes (Iceland) deep-hydraulic stimulation. The results of the assessment indicate that the individual risk within a radius of 2 km around the injection point is below the safety limits. However, the analysis is affected by a large variability due to the presence of pre-drilling deep uncertainties. This suggests the need for online risk updating during the stimulation. Read more
Linking economic and social factors to peak flows in an agricultural watershed using socio-hydrologic modeling Hydrology and Earth System Sciences DOI 10.5194/hess-24-2873-2020 11 June 2020 We describe a socio-hydrologic model that couples an agent-based model (ABM) of human decision-making with a hydrologic model. We establish this model for a typical agricultural watershed in Iowa, USA, and simulate the evolution of large discharge events over a 47-year period under changing land use. Using this modeling approach, relationships between seemingly unrelated variables such as crop markets or crop yields and local peak flow trends are quantified. Read more
Comparing Palmer Drought Severity Index drought assessments using the traditional offline approach with direct climate model outputs Hydrology and Earth System Sciences DOI 10.5194/hess-24-2921-2020 11 June 2020 Many previous studies using offline drought indices report that future warming will increase worldwide drought. However, this contradicts observations/projections of vegetation greening and increased runoff. We resolved this paradox by re-calculating the same drought indices using direct climate model outputs and find no increase in future drought as the climate warms. We also find that accounting for the impact of CO 2 on plant transpiration avoids the previous overestimation of drought. Read more
N2O isotopocule measurements using laser spectroscopy: analyzer characterization and intercomparison Atmospheric Measurement Techniques DOI 10.5194/amt-13-2797-2020 10 June 2020 The latest commercial laser spectrometers have the potential to revolutionize N 2 O isotope analysis. However, to do so, they must be able to produce trustworthy data. Here, we test the performance of widely used laser spectrometers for ambient air applications and identify instrument-specific dependencies on gas matrix and trace gas concentrations. We then provide a calibration workflow to facilitate the operation of these instruments in order to generate reproducible and accurate data. Read more
Model-based climatology of diurnal variability in stratospheric ozone as adata analysis tool Atmospheric Measurement Techniques DOI 10.5194/amt-13-2733-2020 10 June 2020 We use the NASA GEOS-GMI chemistry climate model to construct a climatology of stratospheric ozone diurnal variations as a function of latitude, pressure and month, which can be used in a variety of data analysis tasks involving ozone observations made at different times of the day. The climatology compares well with previous modeling simulations and available observations, and to the authors’ knowledge is the first characterization of the diurnal cycle available for general ozone data analyses. Read more
Present and future changes in winter climate indices relevant for access disruptions in Troms, northern Norway Natural Hazards and Earth System Sciences DOI 10.5194/nhess-20-1847-2020 9 June 2020 We have studied changes in winter weather known to trigger road closures and isolation of small seaside communities in northern Norway. We find that snow amounts and heavy snowfall events have increased in the past, while future projections for 2040–2100 show a decrease in snow-related indices. Events of heavy water supply and zero crossings are expected to increase. Our results imply fewer dry-snow-related access disruptions in the future, while wet-snow avalanches and slushflows may increase. Read more
Simultaneous measurements of the relative-humidity-dependent aerosol lightextinction, scattering, absorption, and single-scattering albedo with ahumidified cavity-enhanced albedometer Atmospheric Measurement Techniques DOI 10.5194/amt-13-2623-2020 4 June 2020 We report the first demonstration of a humidified cavity-enhanced albedometer (H-CEA) that combines a broadband cavity-enhanced aerosol albedometer with a humidigraph system for simultaneous and accurate measurements of multiple optical hygroscopic parameters ( f (RH)ext,scat,abs,ω) at λ = 532 nm. The instrument is suitable for operating under high RH-conditions and has sampling advantages over independent measurements of different parameters with different instruments. Read more
Network-risk: an open GIS toolbox for estimating the implications of transportation network damage due to natural hazards, tested for Bucharest, Romania Natural Hazards and Earth System Sciences DOI 10.5194/nhess-20-1421-2020 4 June 2020 Natural hazards have an increasing impact on transportation networks. In order to analyze it we developed Network-risk – an open toolbox for ArcGIS. The toolbox links input data such as network datasets (also OpenStreetMap – OSM – data), traffic values or segments which can be affected, determining the difficulty to reach an area and enabling evaluation of socioeconomic implications. By testing Network-risk for Bucharest we show areas difficult to reach by emergency units in earthquakes. Read more
Effects of upwelling duration and phytoplankton growth regime on dissolved-oxygen levels in an idealized Iberian Peninsula upwelling system Nonlinear Processes in Geophysics DOI 10.5194/npg-27-277-2020 2 June 2020 The oceans are losing oxygen, and future changes may worsen this problem. We performed computer simulations of an idealized Iberian Peninsula upwelling system to identify the main fine-scale processes driving dissolved oxygen variability as well as study the response of oxygen levels to changes in wind patterns and phytoplankton species. Our results suggest that oxygen levels would decrease if the wind blows for long periods of time or if phytoplankton is dominated by species that grow slowly. Read more
Exploration of oxidative chemistry and secondary organic aerosol formation in the Amazon during the wet season:explicit modeling of the Manaus urban plume with GECKO-A Atmospheric Chemistry and Physics DOI 10.5194/acp-20-5995-2020 2 June 2020 The GoAmazon 2014/5 field campaign took place near the city of Manaus, Brazil, isolated in the Amazon rainforest, to study the impacts of urban pollution on natural air masses. We simulated this campaign with an extremely detailed organic chemistry model to understand how the city would affect the growth and composition of natural aerosol particles. Discrepancies between the model and the measurements indicate that the chemistry of naturally emitted organic compounds is still poorly understood. Read more
Wetropolis extreme rainfall and flood demonstrator: from mathematical design to outreach Hydrology and Earth System Sciences DOI 10.5194/hess-24-2483-2020 28 May 2020 Wetropolis is a table-top demonstration model with extreme rainfall and flooding, including random rainfall, river flow, flood plains, an upland reservoir, a porous moor, and a city which can flood. It lets the viewer experience extreme rainfall and flood events in a physical model on reduced spatial and temporal scales with an event return period of 6.06 min rather than, say, 200 years. We disseminate its mathematical design and how it has been shown most prominently to over 500 flood victims. Read more
Rapid collaborative knowledge building via Twitter after significantgeohazard events Geoscience Communication DOI 10.5194/gc-3-129-2020 28 May 2020 Among social media platforms, Twitter is valued by scholars to disseminate scientific information. Using two 2018 geohazard events as examples, we show that collaborative open data sharing and discussion on Twitter promote very rapid building of knowledge. This breaks down the traditional ivory tower of academia, making science accessible to nonacademics who can follow the discussion. It also presents the opportunity for a new type of scientific approach within global virtual teams. Read more
Microwave and submillimeter wave scattering of oriented ice particles Atmospheric Measurement Techniques DOI 10.5194/amt-13-2309-2020 26 May 2020 Microwave dual-polarization observations consistently show that larger atmospheric ice particles tend to have a preferred orientation. We provide a publicly available database of microwave and submillimeter wave scattering properties of oriented ice particles based on discrete dipole approximation scattering calculations. Detailed radiative transfer simulations, recreating observed polarization patterns, are additionally presented in this study. Read more
Dynamic projection of anthropogenic emissions in China: methodology and 2015–2050 emission pathways under a range of socio-economic, climate policy, and pollution control scenarios Atmospheric Chemistry and Physics DOI 10.5194/acp-20-5729-2020 26 May 2020 Future trends in air pollution and greenhouse gas emissions in China are of great concern to the community. Here we developed a sophisticated dynamic projection model to understand 2015–2050 emission pathways under a range of socio-economic, climate policy, and pollution control scenarios. By coupling strong low-carbon transitions and clean air policy, emissions of major air pollutants in China will be reduced by 58–87 % during 2015–2050. This work can support future co-governance policy design. Read more
A machine-learning-based cloud detection and thermodynamic-phaseclassification algorithm using passive spectral observations Atmospheric Measurement Techniques DOI 10.5194/amt-13-2257-2020 21 May 2020 A machine-learning (ML)-based approach that can be used for cloud mask and phase detection is developed. An all-day model that uses infrared (IR) observations and a daytime model that uses shortwave and IR observations from a passive instrument are trained separately for different surface types. The training datasets are selected by using reference pixel types from collocated space lidar. The ML approach is validated carefully and the overall performance is better than traditional methods. Read more
The catastrophic thermokarst lake drainage events of 2018 in northwestern Alaska: Fast-forward into the future The Cryosphere DOI 10.5194/tc-2020-106 21 May 2020 Northwestern Alaska has been highly affected by changing climatic patterns with new temperature and precipitation maxima over the recent years. In particular, the Baldwin and northern Seward peninsulas are characterized by an abundance of thermokarst lakes that are highly dynamic and prone to lake drainage, like many other regions at the southern margins of continuous permafrost. We used Sentinel-1 synthetic aperture radar (SAR) and Planet CubeSat optical remote sensing data to analyze recently observed widespread lake drainage. Read more
Quantification of seasonal and diurnal dynamics of subglacial channels using seismic observations on an Alpine glacier The Cryosphere DOI 10.5194/tc-14-1475-2020 19 May 2020 Our study addresses key questions on the subglacial drainage system physics through a novel observational approach that overcomes traditional limitations. We conducted, over 2 years, measurements of the subglacial water-flow-induced seismic noise and of glacier basal sliding speeds. We then inverted for the subglacial channel’s hydraulic pressure gradient and hydraulic radius and investigated the links between the equilibrium state of subglacial channels and glacier basal sliding. Read more
Summarizing the state of the terrestrial biosphere in few dimensions Biogeosciences DOI 10.5194/bg-17-2397-2020 19 May 2020 To closely monitor the state of our planet, we require systems that can monitor the observation of many different properties at the same time. We create indicators that resemble the behavior of many different simultaneous observations. We apply the method to create indicators representing the Earth’s biosphere. The indicators show a productivity gradient and a water gradient. The resulting indicators can detect a large number of changes and extremes in the Earth system. Read more
Intercomparison of wind observations from the European Space Agency’s Aeolus satellite mission and the ALADIN Airborne Demonstrator Atmospheric Measurement Techniques DOI 10.5194/amt-13-2075-2020 14 May 2020 This work reports on the first airborne validation campaign of ESA’s Earth Explorer mission Aeolus, conducted in central Europe during the commissioning phase in November 2018. After presenting the methodology used to compare the data sets from the satellite, the airborne wind lidar and the ECWMF model, the wind results from the underflights performed are analyzed and discussed, providing a first assessment of the accuracy and precision of the preliminary Aeolus wind data. Read more
The acidity of atmospheric particles and clouds Atmospheric Chemistry and Physics DOI 10.5194/acp-20-4809-2020 14 May 2020 Acid rain is recognized for its impacts on human health and ecosystems, and programs to mitigate these effects have had implications for atmospheric acidity. Historical measurements indicate that cloud and fog droplet acidity has changed in recent decades in response to controls on emissions from human activity, while the limited trend data for suspended particles indicate acidity may be relatively constant. This review synthesizes knowledge on the acidity of atmospheric particles and clouds. Read more
Drainage divide networks – Part 2: Response to perturbations Earth Surface Dynamics DOI 10.5194/esurf-8-261-2020 12 May 2020 Drainage divides are believed to provide clues about divide migration and the instability of landscapes. Here, we present a novel approach to extract drainage divides from digital elevation models and to order them in a drainage divide network. We present our approach by studying natural and artificial landscapes generated with a landscape evolution model and disturbed to induce divide migration. Read more
The benefits to climate science of including early-career scientists asreviewers Geoscience Communication DOI 10.5194/gc-3-89-2020 12 May 2020 Early-career scientists (ECSs) are rarely invited to act as peer reviewers. Participating in a group peer review of the IPCC Special Report on Ocean and Cryosphere in a Changing Climate, PhD students spent more time reviewing than more established scientists and provided a similar proportion of substantive comments. By soliciting and including ECSs in peer review, the scientific community would reduce the burden on more established scientists and may improve the quality of that process. Read more
Brief communication: Residence time of energy in the atmosphere Nonlinear Processes in Geophysics DOI 10.5194/npg-27-235-2020 30 April 2020 We deduce that after a global thermal perturbation, the Earth’s atmosphere would need about a couple of months to come back to equilibrium. Read more
Drainage divide networks – Part 1: Identification and ordering in digital elevation models Earth Surface Dynamics DOI 10.5194/esurf-8-245-2020 30 April 2020 Drainage divides are believed to provide clues about divide migration and the instability of landscapes. Here, we present a novel approach to extract drainage divides from digital elevation models and to order them in a drainage divide network. We present our approach by studying natural and artificial landscapes generated with a landscape evolution model and disturbed to induce divide migration. Read more
Authigenic formation of Ca–Mg carbonates in the shallow alkaline LakeNeusiedl, Austria Biogeosciences DOI 10.5194/bg-17-2085-2020 29 April 2020 Dolomite (CaMg(CO 3 ) 2 ) is supersaturated in many aquatic settings (e.g., seawater) on modern Earth but does not precipitate directly from the fluid, a fact known as the dolomite problem. The widely acknowledged concept of dolomite precipitation involves microbial extracellular polymeric substances (EPSs) and anoxic conditions as important drivers. In contrast, results from Lake Neusiedl support an alternative concept of Ca–Mg carbonate precipitation under aerobic and alkaline conditions. Read more
Oxygen and sulfur mass-independent isotopic signatures in black crusts: thecomplementary negative Δ33S reservoir of sulfate aerosols? Atmospheric Chemistry and Physics DOI 10.5194/acp-20-4255-2020 27 April 2020 Given their critical impact on radiative forcing, sulfate aerosols have been extensively studied using their isotope signatures (δ 34 S, ∆ 33 S, ∆ 36 S, δ 18 O, and ∆ 17 O). A striking observation is that ∆ 33 S > 0 ‰, implying a missing reservoir in the sulfur cycle. Here, we measured ∆ 33 S < 0 ‰ in black crust sulfates (i.e., formed on carbonate walls) that must therefore result from distinct chemical pathway(s) compared to sulfate aerosols, and they may well represent this complementary reservoir. Read more
Surface water and groundwater: unifying conceptualization and quantification of the two “water worlds” Hydrology and Earth System Sciences DOI 10.5194/hess-24-1831-2020 27 April 2020 We present a blueprint for a unified modelling framework to quantify chemical transport in both surface water and groundwater systems. There has been extensive debate over recent decades, particularly in the surface water literature, about how to explain and account for long travel times of chemical species that are distinct from water flow (rainfall-runoff) travel times. We suggest a powerful modelling framework known to be robust and effective from the field of groundwater hydrology. Read more
Statistical estimation of global surface temperature response to forcing under the assumption of temporal scaling Earth System Dynamics DOI 10.5194/esd-11-329-2020 23 April 2020 This paper presents efficient Bayesian methods for linear response models of global mean surface temperature that take into account long-range dependence. We apply the methods to the instrumental temperature record and historical model runs in the CMIP5 ensemble to provide estimates of the transient climate response and temperature projections under the Representative Concentration Pathways. Read more
Technical note: Preparation and purification of atmospherically relevant α-hydroxynitrate esters of monoterpenes Atmospheric Chemistry and Physics DOI 10.5194/acp-20-4241-2020 23 April 2020 This report describes a simple, safe and effective method to prepare nitrate esters of terpenes (carene, limonene, perillic alcohol, beta-pinene and alpha-pinene) which are key oxidation products in the atmosphere. These compounds are implicated in the formation of secondary organic aerosols. A compilation of the relevant spectroscopic data has been presented. The availability of these compounds and their characterization data will enable further study of the structure–reactivity relationships. Read more
Run-up, inundation, and sediment characteristics of the 22 December 2018 Sunda Strait tsunami, Indonesia Natural Hazards and Earth System Sciences DOI 10.5194/nhess-20-933-2020 21 April 2020 This article reports the results of a field survey carried out in the disaster area of the December 2018 Sunda Strait tsunami, Indonesia. It provides data covering run-up heights, inundations, tsunami directions, and sediment characteristics. The data can be used for the validation of hydrodynamic models, and they contribute to a better understanding of the Sunda Strait tsunami caused by the Anak Krakatau volcano. In addition, they are important for spatial planning and mitigation efforts. Read more
Supercooled liquid water cloud observed, analysed, and modelled at the top ofthe planetary boundary layer above Dome C, Antarctica Atmospheric Chemistry and Physics DOI 10.5194/acp-20-4167-2020 21 April 2020 Thin (~ 100 m) supercooled liquid water (SLW, water staying in liquid phase below 0 °C) clouds have been detected, analysed, and modelled over the Dome C (Concordia, Antarctica) station during the austral summer 2018–2019 using observations and meteorological analyses. The SLW clouds were observed at the top of the planetary boundary layer and the SLW content was always strongly underestimated by the model indicating an incorrect simulation of the surface energy budget of the Antarctic Plateau. Read more
Ramped thermal analysis for isolating biologically meaningful soil organic matter fractions with distinct residence times SOIL DOI 10.5194/soil-6-131-2020 16 April 2020 Soils contain one of the largest and most dynamic pools of carbon on Earth, yet scientists still struggle to understand the reactivity and fate of soil organic matter upon disturbance. In this study, we found that with increasing thermal stability, the turnover time of organic matter increased from decades to centuries with a concurrent shift in chemical composition. In this proof-of-concept study, we found that ramped thermal analyses can provide new insights for understanding soil carbon. Read more
Baroclinic and barotropic instabilities in planetary atmospheres: energetics, equilibration and adjustment Nonlinear Processes in Geophysics DOI 10.5194/npg-27-147-2020 16 April 2020 Baroclinic and barotropic instabilities are well known as the processes responsible for the production of the most important energy-containing eddies in the atmospheres and oceans of Earth and other planets. Linear and nonlinear instability theories provide insights into when such instabilities may occur, grow to a large amplitude and saturate, with examples from the laboratory, simplified numerical models and planetary atmospheres. We conclude with a number of open issues for future research. Read more
Description and Evaluation of the specified-dynamics experiment in the Chemistry-Climate Model Initiative Atmospheric Chemistry and Physics DOI 10.5194/acp-20-3809-2020 9 April 2020 Atmospheric composition is strongly influenced by global-scale winds that are not always properly simulated in computer models. A common approach to correct for this bias is to relax or nudge to the observed winds. Here we systematically evaluate how well this technique performs across a large suite of chemistry–climate models in terms of its ability to reproduce key aspects of both the tropospheric and stratospheric circulations. Read more
Real-time pollen monitoring using digital holography Atmospheric Measurement Techniques DOI 10.5194/amt-13-1539-2020 9 April 2020 We present the first validation of the only operational automatic pollen monitoring system based on holography, the Swisens Poleno. The device produces real-time images of coarse aerosols, and by applying a machine learning algorithm we identify a range of pollen taxa with accuracy >90 %. The device was further validated in controlled chamber experiments to verify the counting ability and the performance of additional fluorescence measurements, which can further be used in pollen identification. Read more
Technical note: LIMS observations of lower stratospheric ozone in the southern polar springtime of 1978 Atmospheric Chemistry and Physics DOI 10.5194/acp-20-3663-2020 7 April 2020 The Nimbus 7 limb infrared monitor of the stratosphere (LIMS) instrument operated from October 25, 1978, through May 28, 1979. This note focuses on the lower stratosphere of the southern hemisphere, subpolar regions in relation to the position of the polar vortex. Both LIMS ozone and nitric acid show reductions within the edge of the polar vortex at 46 hPa near 60° S from late October through mid-November 1978, indicating that there was a chemical loss of Antarctic ozone some weeks earlier. Read more
Terrestrial methane emissions from the Last Glacial Maximum to the preindustrial period Climate of the Past DOI 10.5194/cp-16-575-2020 7 April 2020 We investigate the changes in natural methane emissions between the Last Glacial Maximum and preindustrial periods with a methane-enabled version of MPI-ESM. We consider all natural sources of methane except for emissions from wild animals and geological sources. Changes are dominated by changes in tropical wetland emissions, high-latitude wetlands play a secondary role, and all other natural sources are of minor importance. We explain the changes in ice core methane by methane emissions only. Read more
Methane emissions from the Munich Oktoberfest Atmospheric Chemistry and Physics DOI 10.5194/acp-20-3683-2020 3 April 2020 We demonstrate for the first time that large festivals can be significant methane sources, though they are not included in emission inventories. We combined in situ measurements with a Gaussian plume model to determine the Oktoberfest emissions and show that they are not due solely to human biogenic emissions, but are instead primarily fossil fuel related. Our study provides the foundation to develop reduction policies for such events and new pathways to mitigate fossil fuel methane emissions. Read more
Deconvolution of boundary layer depth and aerosol constraints on cloud water path in subtropical stratocumulus decks Atmospheric Chemistry and Physics DOI 10.5194/acp-20-3609-2020 3 April 2020 Cloud water content and the number of droplets inside clouds covary with boundary layer depth. This covariation may amplify the change in water content due to a change in droplet number inferred from long-term observations. Taking this into account shows that the change in water content for increased droplet number in observations and high-resolution simulations agrees in shallow boundary layers. Meanwhile, deep boundary layers are under-sampled in process-scale simulations and observations. Read more
Back to the future II: tidal evolution of four supercontinent scenarios Earth System Dynamics DOI 10.5194/esd-11-291-2020 31 March 2020 We have confirmed that there is a supertidal cycle associated with the supercontinent cycle. As continents drift due to plate tectonics, oceans also change size, controlling the strength of the tides and causing periods of supertides. In this work, we used a coupled tectonic–tidal model of Earth’s future to test four different scenarios that undergo different styles of ocean closure and periods of supertides. This has implications for the Earth system and for other planets with liquid oceans. Read more
Scaling carbon fluxes from eddy covariance sites to globe: synthesis andevaluation of the FLUXCOM approach Biogeosciences DOI 10.5194/bg-17-1343-2020 26 March 2020 We test the approach of producing global gridded carbon fluxes based on combining machine learning with local measurements, remote sensing and climate data. We show that we can reproduce seasonal variations in carbon assimilated by plants via photosynthesis and in ecosystem net carbon balance. The ecosystem’s mean carbon balance and carbon flux trends require cautious interpretation. The analysis paves the way for future improvements of the data-driven assessment of carbon fluxes. Read more
“This bookmark gauges the depths of the human”: how poetry can help to personalise climate change Geoscience Communication DOI 10.5194/gc-3-35-2020 24 March 2020 To many non-specialists, the science behind climate change can appear confusing and alienating, yet in order for global mitigation efforts to be successful it is not just scientists who need to take action, but rather society as a whole. This study shows how poets and poetry offer a method of communicating the science of climate change to the wider society using language that they not only better understand, but which also has the potential to stimulate accountability and inspire action. Read more
Methanethiol, dimethyl sulfide and acetone over biologically productive waters in the southwest Pacific Ocean Atmospheric Chemistry and Physics DOI 10.5194/acp-20-3061-2020 24 March 2020 Methanethiol (MeSH) is a reduced sulfur gas originating from phytoplankton, with a global ocean source of ~ 17 % of dimethyl sulfide (DMS). It has been little studied and is rarely observed over the ocean. In this work, MeSH was measured at much higher levels than previously observed (3–36 % of parallel DMS mixing ratios). MeSH could be a significant source of atmospheric sulfur over productive regions of the ocean, but its distribution, and its atmospheric impact, requires more investigation. Read more
Changing suspended sediment in United States rivers and streams: linking sediment trends to changes in land use/cover, hydrology and climate Hydrology and Earth System Sciences DOI 10.5194/hess-24-991-2020 17 March 2020 Between 1992 and 2012, concentrations of suspended sediment decreased at about 60 % of 137 US stream sites, with increases at only 17 % of sites. Sediment trends were primarily attributed to changes in land management, but streamflow changes also contributed to these trends at > 50 % of sites. At many sites, decreases in sediment occurred despite small-to-moderate increases in the amount of anthropogenic land use, suggesting sediment reduction activities across the US may be seeing some success. Read more
Assimilation of surface observations in a transient marine ice sheet model using an ensemble Kalman filter The Cryosphere DOI 10.5194/tc-14-811-2020 17 March 2020 Marine-based sectors of the Antarctic Ice Sheet are increasingly contributing to sea-level rise. The basal conditions exert an important control on the ice dynamics. For obvious reasons of inaccessibility, they are an important source of uncertainties in numerical ice flow models used for sea-level projections. Here we assess the performance of an ensemble Kalman filter for the assimilation of transient observations of surface elevation and velocities in a marine ice sheet model. Read more
Time-lapse monitoring of root water uptake using electrical resistivitytomography and mise-à-la-masse: a vineyard infiltration experiment SOIL DOI 10.5194/soil-6-95-2020 17 March 2020 The use of non-invasive geophysical imaging of root system processes is of increasing interest to study soil–plant interactions. The experiment focused on the behaviour of grapevine plants during a controlled infiltration experiment. The combination of the mise-à-la-masse (MALM) method, a variation of the classical electrical tomography map (ERT), for which the current is transmitted directly into the stem, holds the promise of being able to image root distribution. Read more