Untargeted molecular analyses of complex mixtures are relevant for many fields of research, including geochemistry, pharmacology, and medicine. Ultrahigh-resolution mass spectrometry is one of the most powerful tools in this context. The availability of open scripts and online tools for specific data processing steps such as noise removal or molecular formula assignment is growing, but an integrative tool where all crucial steps are reproducibly evaluated and documented is lacking. We developed a novel, server-based tool (ICBM-OCEAN, Institute for Chemistry and Biology of the Marine Environment, Oldenburg−complex molecular mixtures, evaluation & analysis) that integrates published and novel approaches for standardized processing of ultrahigh-resolution mass spectrometry data of complex molecular mixtures. Different from published approaches, we offer diagnostic and validation tools for all relevant steps. Among other features, we included objective and reproducible reduction of noise and systematic errors, spectra recalibration and alignment, and identification of likeliest molecular formulas. With 15 chemical elements, the tool offers high flexibility in formula attribution. Alignment of mass spectra among different samples prior to molecular formula assignment improves mass error and facilitates molecular formula confirmation with the help of isotopologues. The online tool and the detailed instruction manual are freely accessible at www.icbm.de/icbm-ocean.
Patterns of Pore Water Chemistry which produced non-uniform groundwater flow conditions. We conclude that on mesotidal high energy beaches, the rapidly changing beach morphology produces zones with different approximations to steady-state conditions. Therefore, we suggest that zone-specific endmember sampling is the optimal strategy to reduce uncertainties of SGD-driven constituent fluxes.
Iron that precipitates under aerobic
conditions in natural aquatic
systems scavenges dissolved organic matter (DOM) from solution. Subterranean
estuaries (STEs) are of major importance for land–ocean biogeochemical
fluxes. Their specific redox boundaries, coined the “iron curtain”
due to the abundance of precipitated iron(III) (oxy)hydroxides, are
hot spots for the removal and redissolution of iron, associated nutrients,
and DOM. We used ultra-high-resolution electrospray ionization Fourier
transform ion cyclotron resonance mass spectrometry to molecularly
characterize the iron-coagulating fractions of 32 groundwater and
seawater DOM samples along a salinity gradient from a shallow STE
on Spiekeroog Island, North Sea, Germany, and linked our findings
to trace metal and nutrient concentrations. We found systematic iron
coagulation of large (>450 Da), oxygen-rich, and highly aromatic
DOM
molecules of terrestrial origin. The extent of coagulation increased
with growing terrestrial influence along the salinity gradient. Our
study is the first to show that the iron curtain may be capable of
retaining terrigenous DOM fractions in marine sediments. We hypothesize
that the iron curtain serves as an inorganic modulator for the supply
of DOM from groundwaters to the sea, and that the STE has the potential
to act as a temporal storage or even sink for terrigenous aromatic
DOM compounds.
The transport of dissolved organic matter (DOM) across the land-ocean-aquatic-continuum (LOAC), from freshwater to the ocean, is an important yet poorly understood component of the global carbon budget. Exploring and quantifying this flux is a significant challenge given the complexities of DOM cycling across these contrasting environments. We developed a new model, UniDOM, that unifies concepts, state variables and parameterisations of DOM turnover across the LOAC. Terrigenous DOM is divided into two pools, T1 (strongly-UV-absorbing) and T2 (non- or weakly-UV-absorbing), that exhibit contrasting responses to microbial consumption, photooxidation and flocculation. Data are presented to show that these pools are amenable to routine measurement based on specific UV absorbance (SUVA). In addition, an autochtonous DOM pool is defined to account for aquatic DOM production. A novel aspect of UniDOM is that rates of photooxidation and microbial turnover are parameterised as an inverse function of DOM age. Model results, which indicate that ~ 5% of the DOM originating in streams may penetrate into the open ocean, are sensitive to this parameterisation, as well as rates assigned to turnover of freshly-produced DOM. The predicted contribution of flocculation to DOM turnover is remarkably low, although a mechanistic representation of this process in UniDOM was considered unachievable because of the complexities involved. Our work highlights the need for ongoing research into the mechanistic understanding and rates of photooxidation, microbial consumption and flocculation of DOM across the different environments of the LOAC, along with the development of models based on unified concepts and parameterisations.
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