Surficial redistribution of fallout<sup>131</sup>iodine in a small temperate catchment

Landis, Joshua D.; Hamm, N. T.; Renshaw, Carl E.; Dade, W. Brian; Gartner, John

doi:10.1073/pnas.1118665109

Cited by 19 publications

(27 citation statements)

References 56 publications

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“…However, this is a minimum and approximate estimate as it assumes all leaf areas are projected orthogonal to rain direction and that no rain shadow is cast by nearby branches or tree crowns. By comparison, a full canopy cumulatively retains on the order of 40−90% of depositional flux as estimated either by the fraction of standing inventory found in vegetation 51,17,18 or from comparisons of precipitation Each unique accumulative atmospheric ratio history begins with the leaf-out date of the tree and is shown as a shaded 1-sigma confidence interval. For clarity, error bars on leaf symbols for oak (circle, ○) and for hemlock (square, □ ) depict larger 2-sigma propagated uncertainty.…”

Section: Quantitative Accumulation Of Atmosphericmentioning

confidence: 99%

Quantitative Retention of Atmospherically Deposited Elements by Native Vegetation Is Traced by the Fallout Radionuclides ⁷Be and ²¹⁰Pb

Landis

Renshaw

Kaste

2014

Environ. Sci. Technol.

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Atmospheric deposition is the primary mechanism by which remote environments are impacted by anthropogenic contaminants. Vegetation plays a critical role in intercepting atmospheric aerosols, thereby regulating the timing and magnitude of both contaminant and nutrient delivery to underlying soils. However, quantitative models describing the fate of atmospherically derived elements on vegetation are limited by a lack of long-term measurements of both atmospheric flux and foliar concentrations. We addressed this gap in understanding by quantifying weekly atmospheric deposition of the naturally occurring radionuclide tracers (7)Be and (210)Pb, as well as their activities in leaves of colocated trees, for three years in New Hampshire, U.S. The accumulation of both (7)Be and (210)Pb in deciduous and coniferous vegetation is predicted by a model that is based solely on measured atmospheric fluxes, duration of leaf exposure, and radioactive decay. Any "wash off" processes that remove (7)Be and (210)Pb from foliage operate with a maximum half-time of greater than 370 days (P > 99%), which is an order of magnitude longer than previously assumed. The retention of both (7)Be and (210)Pb on leaves is thus quantitative and permanent, coupling the fate of (7)Be, (210)Pb and similar atmospheric species to that of the leaf matter itself. These findings demonstrate that the long-standing paradigm of a short "environmental half-life" for atmospheric contaminants deposited on natural surfaces must be re-evaluated.

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Section: Quantitative Accumulation Of Atmosphericmentioning

confidence: 99%

Quantitative Retention of Atmospherically Deposited Elements by Native Vegetation Is Traced by the Fallout Radionuclides ⁷Be and ²¹⁰Pb

Landis

Renshaw

Kaste

2014

Environ. Sci. Technol.

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“…The transport and fate of radionuclide-tagged particles are controlled by the dynamics of fine-grained sediment transport in fluvial systems. Field observations have shown that finegrained sediment and atmospherically-deposited contaminants tend to accumulate in higher concentrations in channel margins that have been termed 'fine-grained channel margin' (FGCM) deposits (Skalak and Pizzuto, 2010;Landis et al, 2012a;Renshaw et al, 2013). However, the evolution of these deposits, such as the conditions under which they form and those under which they are eroded away, is not well established.…”

Section: Source Of Sedimentmentioning

confidence: 99%

“…The different sources of suspended sediment can be identified and quantified because of their different characteristic radionuclide activities. The activity of precipitation is expected to be greatest while sediment stored on the channel bed is expected to have a lower 7 Be activity than the channel margin deposits due to the relatively long (with respect to 7 Be's half-life) residence time on the streambed (Bonniwell et al, 1999;Landis et al, 2012a).…”

Section: Radionuclide Mass Balancementioning

confidence: 99%

“…If channel sediments are subsequently deposited onto the channel margins, the inventory of 7 Be activity of surface sediments increases, particularly near the channel's edge where deposition is greatest. This behavior is similar to many atmospherically deposited metals (Hawley et al ., ; Landis et al ., ; Renshaw et al ., ) and therefore 7 Be can be utilized as an effective tracer of particle‐reactive atmospheric contaminants. Field studies have confirmed this idea, demonstrating that 7 Be activity in sediment correlates with other atmospherically deposited metals, particularly in channel proximal areas (Landis et al ., ; Renshaw et al ., ).…”

Section: Introductionmentioning

confidence: 99%

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Joint isotopic mass balance: a novel approach to quantifying channel bed to channel margins sediment transfer during storm events

Underwood

Renshaw

Dade

et al. 2015

Earth Surf Processes Landf

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The important role of floodplains and the broader riparian zone in providing temporary storage for a large fraction of the annual sediment load of rivers is well established, but this understanding is largely based on observations of the long-term average behavior of the catchment. Here we combine measurements of the fallout radionuclides 7 Be and 210 Pb and the stable isotopes of hydrogen in water to quantify fine sediment mobilization and storage in a stream and its channel margins during individual intermediate-sized storm events with recurrence intervals of a few months or less. We demonstrate this method using five storm events in a small (~15 km 2 ), undeveloped, gravel-bedded tributary of the Connecticut River (USA). We estimate that in each storm, the mass of sediment deposited onto the margins accounts for almost 90% of the sediment mobilized from the bed, with the remainder of the mobilized bed sediment transported downstream as suspended load. The result that the bed is a net source of sediment to the stream and the margins a net sink is robust, but estimates of the mass of material eroded from the bed and deposited on the margins are less certain. The source of sediment to the bed remains unclear as, consistent with earlier studies, we observe only limited deposition of sediment to the bed during the storm events. The suspended sediment is organic-rich and thus its source may be associated with in-channel organic decay between storm events. Understanding the coupled interactions between discharge magnitude and frequency and sediment resupply at the event time scale has important implications for stream restoration efforts seeking to connect the channel and the broader riparian zone, and for the development of accurate sediment budgets and predictions of sediment flux from a watershed.

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“…Following the CNPP accident in 1986, the concentrations of fission products such as 131 I, 137 Cs, and 90 Sr in foodstuffs in Ukraine were more than 1,000 times the baseline fallout concentrations (Nesterenko et al 2010). As with observations of fallout, once these and other anthropogenic radionuclides were released into the environment, their activities steadily decreased owing to a combination of radioactive decay and biological and geochemical redistributions (e.g., Landis et al 2012).…”

Section: Radiological Doses To Humans and Societal Impactsmentioning

confidence: 99%

Fukushima Daiichi–Derived Radionuclides in the Ocean: Transport, Fate, and Impacts

Buesseler

Dai

Aoyama

et al. 2017

Annu. Rev. Mar. Sci.

235

122

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The events that followed the Tohoku earthquake and tsunami on March 11, 2011, included the loss of power and overheating at the Fukushima Daiichi nuclear power plants, which led to extensive releases of radioactive gases, volatiles, and liquids, particularly to the coastal ocean. The fate of these radionuclides depends in large part on their oceanic geochemistry, physical processes, and biological uptake. Whereas radioactivity on land can be resampled and its distribution mapped, releases to the marine environment are harder to characterize owing to variability in ocean currents and the general challenges of sampling at sea. Five years later, it is appropriate to review what happened in terms of the sources, transport, and fate of these radionuclides in the ocean. In addition to the oceanic behavior of these contaminants, this review considers the potential health effects and societal impacts.

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Surficial redistribution of fallout¹³¹iodine in a small temperate catchment

Cited by 19 publications

References 56 publications

Quantitative Retention of Atmospherically Deposited Elements by Native Vegetation Is Traced by the Fallout Radionuclides ⁷Be and ²¹⁰Pb

Quantitative Retention of Atmospherically Deposited Elements by Native Vegetation Is Traced by the Fallout Radionuclides ⁷Be and ²¹⁰Pb

Joint isotopic mass balance: a novel approach to quantifying channel bed to channel margins sediment transfer during storm events

Fukushima Daiichi–Derived Radionuclides in the Ocean: Transport, Fate, and Impacts

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Surficial redistribution of fallout131iodine in a small temperate catchment

Cited by 19 publications

References 56 publications

Quantitative Retention of Atmospherically Deposited Elements by Native Vegetation Is Traced by the Fallout Radionuclides 7Be and 210Pb

Quantitative Retention of Atmospherically Deposited Elements by Native Vegetation Is Traced by the Fallout Radionuclides 7Be and 210Pb

Joint isotopic mass balance: a novel approach to quantifying channel bed to channel margins sediment transfer during storm events

Fukushima Daiichi–Derived Radionuclides in the Ocean: Transport, Fate, and Impacts

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Surficial redistribution of fallout¹³¹iodine in a small temperate catchment

Quantitative Retention of Atmospherically Deposited Elements by Native Vegetation Is Traced by the Fallout Radionuclides ⁷Be and ²¹⁰Pb

Quantitative Retention of Atmospherically Deposited Elements by Native Vegetation Is Traced by the Fallout Radionuclides ⁷Be and ²¹⁰Pb