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1. A simple CO 2 equilibration method for measuring blood oxygen isotope compositions

   https://doi.org/10.1002/rcm.9256  

   Green, Daniel R. ; Olack, Gerard ; Tütken, Thomas ; Leichliter, Jennifer ; Winkler, Daniela E. ; Clauss, Marcus ; Vonhof, Hubert ; Colman, Albert S. ( February 2022 , Rapid Communications in Mass Spectrometry)

   Blood water oxygen isotope compositions can provide valuable insights into physiological processes and ecological patterns. While blood samples are commonly drawn for medical or scientific purposes, blood fractions are infrequently measured for oxygen isotopic compositions (δ¹⁸O) because such measurements are time consuming and expensive.

   We sampled blood from sheep, goats, and iguanas raised in field and animal laboratories into serum, EDTA, heparin, and uncoated plastic vials commonly used in medical and scientific research, then separated red blood cell (RBC) and plasma or serum blood fractions. These were injected into helium‐flushed Exetainer tubes where they naturally outgassed endogenous CO₂(goat blood), or into He‐ and CO₂‐flushed tubes (iguana blood). The CO₂gas was sampled on a GasBench II system, and δ¹⁸O was measured by an isotope ratio mass spectrometer (IRMS).

   Repeated δ¹⁸O measurements were stable over multiple days. The addition of desiccated blood solids to water standards had little impact on their δ¹⁸O measurements, suggesting that organic molecular constituents within blood serum and plasma do not interfere with blood water δ¹⁸O values. We observed slight but statistically significant δ¹⁸O offsets between plasma, serum and RBC fractions. Mass‐dependent body water turnover times for iguanas were derived from the data.

   We demonstrate that a simple blood‐CO₂equilibration method using the GasBench can quickly, reliably and accurately characterize water δ¹⁸O in the plasma, RBC, and whole blood fractions of mammalian and reptilian blood samples (precision ≤ 0.1‰). This method will expand the application of blood stable isotope analysis in physiological and medical research.

    

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2. Modeling the Complete Nitrogen and Oxygen Isotopic Imprint of Nitrate Photolysis in Snow

   https://doi.org/10.1029/2023GL103778  

   Shi, Guitao ; Buffen, Aron M. ; Hu, Ye ; Chai, Jiajue ; Li, Yilan ; Wang, Danghe ; Hastings, Meredith G. ( June 2023 , Geophysical Research Letters)

   Snow nitrate is vulnerable to photolytic loss that causes isotopic alteration, and thus its isotopes can potentially track the extent of snow nitrate photolysis and its impacts in environments where loss is significant. Large increases in δ¹⁵N‐NO₃⁻below the snow surface have been attributed to photolysis and this behavior is generally consistent amongst theoretical as well as lab and field studies. Oxygen isotope ratios are thought to be influenced by photolysis as well as secondary condensed‐phase chemistry, but the competing effects have yet to be reconciled. Here we use a model that simulates nitrate burial, photolytic fractionation, and re‐oxidation in snow to quantitatively assess these processes with the aim of developing a consistent framework for interpreting the photolytic effects of the complete nitrate isotopic composition (δ¹⁵N, δ¹⁸O, and Δ¹⁷O). This study reveals that isotopic effects of nitrate photolysis and aqueous‐phase re‐oxidation chemistry are important sources of uncertainties in modeling δ¹⁸O‐NO₃⁻.

    

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3. Identifying the Sources and Drivers of Nitrous Oxide Accumulation in the Eddy‐Influenced Eastern Tropical North Pacific Oxygen‐Deficient Zone

   https://doi.org/10.1029/2022GB007310  

   Monreal, Patrick J. ; Kelly, Colette L. ; Travis, Nicole M. ; Casciotti, Karen L. ( June 2022 , Global Biogeochemical Cycles)

   Nitrous oxide (N₂O) is a powerful greenhouse gas, and oceanic sources account for up to one third of the total natural flux to the atmosphere. In oxygen‐deficient zones (ODZs) like the Eastern Tropical North Pacific (ETNP), N₂O can be produced and consumed by several biological processes. In this study, the concentration and isotopocule ratios of N₂O from a 2016 cruise in the ETNP were analyzed to examine sources of and controls on N₂O cycling across this region. Along the north‐south transect, three distinct biogeochemical regimes were identified: background, core‐ODZ, and high‐N₂O stations. Background stations were characterized by smaller variations in N₂O concentration and isotopic profiles relative to the other regimes. Core‐ODZ stations were characterized by co‐occurring N₂O production and consumption at anoxic depths, indicated by high δ¹⁸O‐N₂O (>90‰) and low δ¹⁵N₂O^β(<−10‰) values, and confirmed by a time‐dependent model, which indicated that N₂O production via denitrification was significant and may occur with a nonzero site preference. High‐N₂O stations, located at the periphery of a mesoscale eddy, were defined by N₂O reaching 126.07 ± 12.6 nM and low oxygen concentrations expanding into near‐surface isopycnals. At these stations, model results indicated significant N₂O production from ammonia‐oxidizing archaea and denitrification from nitrate at the N₂O maximum within the oxycline, while bacterial nitrification and denitrification from nitrite were insignificant. This study also represents the first in the ETNP to link N₂O production mechanisms to a mesoscale eddy through isotopocule measurements, suggesting the importance of eddies to spatiotemporal variability in N₂O cycling and emissions from this region.

    

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4. Nitrate Legacy in a Tropical and Complex Fractured Volcanic Aquifer System

   https://doi.org/10.1029/2023JG007554  

   Sánchez‐Gutiérrez, R. ; Sánchez‐Murillo, R. ; Esquivel‐Hernández, G. ; Birkel, C. ; Boll, J. ; Rojas‐Jiménez, L. D. ; Castro‐Chacón, L. ( August 2023 , Journal of Geophysical Research: Biogeosciences)

   Nitrate legacy is affecting groundwater sources across the tropics. This study describes isotopic and ionic spatial trends across a tropical, fractured, volcanic multi‐aquifer system in central Costa Rica in relation to land use change over four decades. Springs and wells (from 800 to 2,400 m asl) were sampled for NO₃⁻and Cl⁻concentrations, δ¹⁸O_water, δ¹⁵N_NO3, and δ¹⁸O_NO3. A Bayesian isotope mixing model was used to estimate potential source contributions to the nitrate legacy in groundwater. Land use change was evaluated using satellite imagery from 1979 to 2019. The lower nitrate concentrations (<1 mg/L NO₃⁻N) were reported in headwater springs near protected forested areas, while greater concentrations (up to ∼63 mg/L) were reported in wells (mid‐ and low‐elevation sites in the unconfined unit) and low‐elevation springs. High‐elevation springs were characterized by low Cl⁻and moderate NO₃⁻/Cl⁻ratios, indicating the potential influence of soil nitrogen (SN) inputs. Wells and low‐elevation springs exhibited greater NO₃⁻/Cl⁻ratios and Cl⁻concentrations above 100 μmol/L. Bayesian calculations suggest a mixture of sewage (domestic septic tanks), SN (forested recharge areas), and chemical fertilizers (coffee plantations), as a direct result of abrupt land use change in the last 40 years. Our results confirm the incipient trend in increasing groundwater nitrogen and highlight the urgent need for a multi‐municipal plan to transition from domestic septic tanks to regional sewage treatment and sustainable agricultural practices to prevent future groundwater quality degradation effectively.

    

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5. High‐precision measurement of phenylalanine and glutamic acid δ 15 N by coupling ion‐exchange chromatography and purge‐and‐trap continuous‐flow isotope ratio mass spectrometry

   https://doi.org/10.1002/rcm.9085  

   Zhang, Lin ; Lee, Wing‐man ; Kreider‐Mueller, Ava ; Kuhnel, Evelyn ; Baca, Jesus ; Ji, Chongxiao ; Altabet, Mark ( May 2021 , Rapid Communications in Mass Spectrometry)

   Nitrogen isotopic compositions (δ¹⁵N) of source and trophic amino acids (AAs) are crucial tracers of N sources and trophic enrichments in diverse fields, including archeology, astrobiochemistry, ecology, oceanography, and paleo‐sciences. The current analytical technique using gas chromatography‐combustion‐isotope ratio mass spectrometry (GC/C/IRMS) requires derivatization, which is not compatible with some key AAs. Another approach using high‐performance liquid chromatography‐elemental analyzer‐IRMS (HPLC/EA/IRMS) may experience coelution issues with other compounds in certain types of samples, and the highly sensitive nano‐EA/IRMS instrumentations are not widely available.

   We present a method for high‐precision δ¹⁵N measurements of AAs (δ¹⁵N‐AA) optimized for canonical source AA‐phenylalanine (Phe) and trophic AA‐glutamic acid (Glu). This offline approach entails purification and separation via high‐pressure ion‐exchange chromatography (IC) with automated fraction collection, the sequential chemical conversion of AA to nitrite and then to nitrous oxide (N₂O), and the final determination of δ¹⁵N of the produced N₂O via purge‐and‐trap continuous‐flow isotope ratio mass spectrometry (PT/CF/IRMS).

   The cross‐plots of δ¹⁵N of Glu and Phe standards (four different natural‐abundance levels) generated by this method and their accepted values have a linear regression slope of 1 and small intercepts demonstrating high accuracy. The precisions were 0.36‰–0.67‰ for Phe standards and 0.27‰–0.35‰ for Glu standards. Our method and the GC/C/IRMS approach produced equivalent δ¹⁵N values for two lab standards (McCarthy Lab AA mixture and cyanobacteria) within error. We further tested our method on a wide range of natural sample matrices and obtained reasonable results.

   Our method provides a reliable alternative to the current methods for δ¹⁵N‐AA measurement as IC or HPLC‐based techniques that can collect underivatized AAs are widely available. Our chemical approach that converts AA to N₂O can be easily implemented in laboratories currently analyzing δ¹⁵N of N₂O using PT/CF/IRMS. This method will help promote the use of δ¹⁵N‐AA in important studies of N cycling and trophic ecology in a wide range of research areas.

    

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