152 research outputs found
Dew frequency across the US from a network of in situ radiometers
Dew formation is a ubiquitous process, but its importance to energy budgets or
ecosystem health is difficult to constrain. This uncertainty arises largely
because of a lack of continuous quantitative measurements on dew across
ecosystems with varying climate states and surface characteristics. This
study analyzes dew frequency from the National Ecological Observatory Network
(NEON), which includes 11 grasslands and 19 forest sites from 2015 to 2017.
Dew formation is determined at 30 min intervals using in situ radiometric
surface temperatures from multiple heights within the canopy along with
meteorological measurements. Dew frequency in the grasslands ranges from
15 % to 95 % of the nights with a strong linear
dependency on the nighttime relative humidity (RH), while dew frequency in
the forests is less frequent and more homogeneous (25±14 %, 1
standard deviation – SD). Dew mostly forms at the top of the canopy for the
grasslands due to more effective radiative cooling and within the canopy for the
forests because of higher within the canopy RH. The high temporal resolution of
our data showed that dew duration reaches maximum values
(∼6–15 h) for RH∼96 % and for a
wind speed of ∼0.5ms-1, independent of the ecosystem type.
While dew duration can be inferred from the observations, dew yield needs to
be estimated based on the Monin–Obukhov similarity theory. We find yields of
0.14±0.12mmnight-1 (1 SD from nine grasslands) similar to
previous studies, and dew yield and duration are related by a quadratic
relationship. The latent heat flux released by dew formation is estimated to
be non-negligible (∼10Wm-2), associated with a Bowen ratio
of ∼3. The radiometers used here provide canopy-averaged surface
temperatures, which may underestimate dew frequency because of localized cold
points in the canopy that fall below the dew point. A statistical model is
used to test this effect and shows that dew frequency can increase by an
additional ∼5 % for both ecosystems by considering a reasonable
distribution around the mean canopy temperature. The mean dew duration is
almost unaffected by this sensitivity analysis. In situ radiometric surface
temperatures provide a continuous, non-invasive and robust tool for studying
dew frequency and duration on a fine temporal scale.</p
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The role of the subtropical jet in deficient winter precipitation across the mid-Holocene Indus basin
The mid-Holocene (7-5 ka) was a period with an increased seasonal insolation cycle, resulting from decreased insolation during northern hemisphere winter. Here, a set of six CMIP5 models is used to show that the decreased insolation reduced the upper-tropospheric meridional temperature gradient, producing a weaker subtropical jet with less horizontal shear.
These effects work to reduce the baroclinic and barotropic instability available for perturbations to grow, and in consequence, storm-tracking results show that there are fewer winter storms over India and Pakistan (known as western disturbances). These western disturbances are weaker, resulting in a reduction in winter precipitation of around 15% in the north Indus Basin.
Combined with previous work showing greater northwestward extent of the Indian monsoon during the mid-Holocene, our GCM-derived results are consistent with the Indus Basin changing from a summer-growing season in the mid-Holocene to a winter-growing season in the present day
Formal Subdivision of the Holocene Series/Epoch: A Summary
The Holocene Series/Epoch is the most recent series/epoch in the geological timescale, spanning the interval from 11,700 yr to the present day. Together with the subadjacent Pleistocene, it comprises the Quaternary System/Period. The Holocene record contains diverse geomorphological, biotic, climatological and archaeological evidence, within sequences that are often continuous and extremely well-preserved at decadal, annual and even seasonal resolution. As a consequence, the Holocene is perhaps the most intensively-studied series/epoch within the entire Geological Time Scale. Yet until recently little attention had been paid to a formal subdivision of the Holocene. Here we describe an initiative by the Subcommission on Quaternary Stratigraphy (SQS) of the International Commission on Stratigraphy (ICS) to develop a formal stratigraphical subdivision of the Holocene, with three
new stages/ages, two underpinned by Global Boundary Stratotype Sections and Points (GSSPs) in an ice core, and a third in a speleothem. These stages/ages are defined along with their equivalent subseries/subepochs. The new stages/ages are the Greenlandian with its GSSP in the Greenland NGRIP2 ice core and dated at 11,700 yr b2k (before 2000 CE); the NorthGrippian with its GSSP in the Greenland NGRIP1 ice core and dated to 8236 yr b2k; and the Meghalayan, with its GSSP in a speleothem from Mawmluh Cave, northeastern India, with a date of 4250 yr b2k. This subdivision was formally ratified by the Executive Committee of the International Union of Geological Sciences (IUGS) on 14th June 2018.non
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The stability and calibration of water vapor isotope ratio measurements during long-term deployments
With the recent advent of commercial laser absorption spectrometers, field studies measuring stable isotope ratios of hydrogen and oxygen in water vapor have proliferated. These pioneering analyses have provided invaluable feedback about best strategies for optimizing instrumental accuracy, yet questions still remain about instrument performance and calibration approaches for multi-year field deployments. With clear scientific potential for using these instruments to carry out monitoring of the hydrological cycle, this study examines the long-term stability of the isotopic biases associated with three cavity-enhanced laser absorption spectrometers - calibrated with different systems and approaches - at two remote field sites: Mauna Loa Observatory, Hawaii, USA, and Greenland Environmental Observatory, Summit, Greenland. The analysis pays particular attention to the stability of measurement dependencies on water vapor concentration and also evaluates whether these so-called concentration dependences are sensitive to statistical curve-fitting choices or measurement hysteresis. The results suggest evidence of monthly-to-seasonal concentration-dependence variability - which likely stems from low signal-to-noise at the humidity-range extremes - but no long-term directional drift. At Mauna Loa, where the isotopic analyzer is calibrated by injection of liquid water standards into a vaporizer, the largest source of inaccuracy in characterizing the concentration dependence stems from an insufficient density of calibration points at low water vapor volume mixing ratios. In comparison, at Summit, the largest source of inaccuracy is measurement hysteresis associated with interactions between the reference vapor, generated by a custom dew point generator, and the sample tubing. Nevertheless, prediction errors associated with correcting the concentration dependence are small compared to total measurement uncertainty. At both sites, changes in measurement repeatability that are not predicted by long-term linear drift estimates are a larger source of error, highlighting the importance of measuring isotopic standards with minimal or well characterized drift at regular intervals. Challenges in monitoring isotopic drift are discussed in light of the different calibration systems evaluated
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The stability and calibration of water vapor isotope ratio measurements during long-term deployments
With the recent advent of commercial laser absorption spectrometers, field studies measuring stable isotope ratios of hydrogen and oxygen in water vapor have proliferated. These pioneering analyses have provided invaluable feedback about best strategies for optimizing instrumental accuracy, yet questions still remain about instrument performance and calibration approaches for multi-year field deployments. With clear scientific potential for using these instruments to carry out long-term monitoring of the hydrological cycle, this study examines the long-term stability of the isotopic biases associated with three cavity-enhanced laser absorption spectrometers – calibrated with different systems and approaches – at two remote field sites: Mauna Loa Observatory, Hawaii, USA, and Greenland Environmental Observatory, Summit, Greenland. The analysis pays particular attention to the stability of measurement dependencies on water vapor concentration and also evaluates whether these so-called concentration-dependences are sensitive to statistical curve-fitting choices or measurement hysteresis. The results suggest evidence of monthly-to-seasonal concentration-dependence variability – which likely stems from low signal-to-noise at the humidity-range extremes – but no long-term directional drift. At Mauna Loa, where the isotopic analyzer is calibrated by injection of liquid water standards into a vaporizer, the largest source of inaccuracy in characterizing the concentration-dependence stems from an insufficient density of calibration points at low humidity. In comparison, at Greenland, the largest source of inaccuracy is measurement hysteresis associated with interactions between the reference vapor, generated by a custom dew point generator (DPG), and the sample tubing. Nevertheless, prediction errors associated with correcting the concentration-dependence are small compared to total measurement uncertainty. At both sites, a dominant source of uncertainty is instrumental precision at low humidity, which cannot be reduced by improving calibration strategies. Challenges in monitoring long-term isotopic drift are also discussed in light of the different calibration systems evaluated.The final revised paper is available at: http://hdl.handle.net/1957/5787
Ecosystem fluxes of carbonyl sulfide in an old-growth forest: temporal dynamics and responses to diffuse radiation and heat waves
Carbonyl sulfide (OCS) has recently emerged as a tracer for terrestrial
carbon uptake. While physiological studies relating OCS fluxes to leaf
stomatal dynamics have been established at leaf and branch scales and
incorporated into global carbon cycle models, the quantity of data from
ecosystem-scale field studies remains limited. In this study, we employ
established theoretical relationships to infer ecosystem-scale plant OCS
uptake from mixing ratio measurements. OCS fluxes showed a pronounced diurnal
cycle, with maximum uptake at midday. OCS uptake was found to scale with
independent measurements of CO2 fluxes over a 60 m tall old-growth
forest in the Pacific Northwest of the US (45∘49′13.76′′ N,
121∘57′06.88′′ W) at daily and
monthly timescales under mid–high light conditions across the growing season
in 2015. OCS fluxes were strongly influenced by the fraction of downwelling
diffuse light. Finally, we examine the effect of sequential heat waves on
fluxes of OCS, CO2, and H2O. Our results bolster previous
evidence that ecosystem OCS uptake is strongly related to stomatal dynamics,
and measuring this gas improves constraints on estimating photosynthetic
rates at the ecosystem scale.</p
Evidence for solar cycles in a late Holocene speleothem record from Dongge Cave, China
The association between solar activity and Asian monsoon (AM) remains unclear. Here we evaluate the possible connection between them based on a precisely-dated, high-resolution speleothem oxygen isotope record from Dongge Cave, southwest China during the past 4.2 thousand years (ka). Without being adjusted chronologically to the solar signal, our record shows a distinct peak-to-peak correlation with cosmogenic nuclide 14C, total solar irradiance (TSI) and sunspot number (SN) at multi-decadal to centennial timescales. Further cross-wavelet analyses between our calcite δ18O and atmospheric 14C show statistically strong coherence at three typical periodicities of ~80, 200 and 340 years, suggesting important roles of solar activities in modulating AM changes at those timescales. Our result has further indicated a better correlation between our calcite δ18O record and atmospheric 14C than between our record and TSI. This better correlation may imply that the Sun–monsoon connection is dominated most likely by cosmic rays and oceanic circulation (both associated to atmospheric 14C), instead of the direct solar heating (TSI)
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Constraining surface carbon fluxes using in situ measurements of carbonyl sulfide and carbon dioxide
Understanding the processes that control the terrestrial exchange of carbon is critical for
assessing atmospheric CO₂ budgets. Carbonyl sulfide (COS) is taken up by vegetation during
photosynthesis following a pathway that mirrors CO₂ but has a small or nonexistent emission component,
providing a possible tracer for gross primary production. Field measurements of COS and CO₂ mixing ratios
were made in forest, senescent grassland, and riparian ecosystems using a laser absorption spectrometer
installed in a mobile trailer. Measurements of leaf fluxes with a branch-bag gas-exchange system were made
across species from 10 genera of trees, and soil fluxes were measured with a flow-through chamber. These
data show (1) the existence of a narrow normalized daytime uptake ratio of COS to CO₂ across vascular
plant species of 1.7, providing critical information for the application of COS to estimate photosynthetic
CO₂ fluxes and (2) a temperature-dependent normalized uptake ratio of COS to CO₂ from soils. Significant
nighttime uptake of COS was observed in broad-leafed species and revealed active stomatal opening prior
to sunrise. Continuous high-resolution joint measurements of COS and CO₂ concentrations in the boundary
layer are used here alongside the flux measurements to partition the influence that leaf and soil fluxes
and entrainment of air from above have on the surface carbon budget. The results provide a number of
critical constraints on the processes that control surface COS exchange, which can be used to diagnose the
robustness of global models that are beginning to use COS to constrain terrestrial carbon exchange.Keywords: surface fluxes, carbonyl sulfide, laser absorption spectrometry, carbon budget, instrument developmen
Evaluating the timing and structure of the 4.2 ka event in the Indian summer monsoon domain from an annually resolved speleothem record from Northeast India
A large array of proxy records
suggests that the “4.2 ka event” marks an approximately
300-year long period (∼3.9 to 4.2 ka) of
major climate change across the globe. However, the climatic manifestation of
this event, including its onset, duration, and termination, remains less
clear in the Indian summer monsoon (ISM) domain. Here, we present new oxygen
isotope (δ18O) data from a pair of speleothems (ML.1 and ML.2)
from Mawmluh Cave, Meghalaya, India, that provide a high-resolution record of
ISM variability during a period (∼3.78 and 4.44 ka) that fully
encompasses the 4.2 ka event. The sub-annually to annually resolved ML.1
δ18O record is constrained by 18 230Th dates with an
average dating error of ±13 years (2σ) and a resolution of ∼40 years, which allows us to characterize the ISM variability with
unprecedented detail. The inferred pattern of ISM variability during the
period contemporaneous with the 4.2 ka event shares broad similarities and
key differences with the previous reconstructions of ISM from the Mawmluh
Cave and other proxy records from the region. Our data suggest that the ISM
intensity, in the context of the length of our record, abruptly decreased at
∼4.0 ka (∼±13 years), marking the onset of a multi-centennial
period of relatively reduced ISM, which was punctuated by at least two
multi-decadal droughts between ∼3.9 and 4.0 ka. The latter stands out
in contrast with some previous proxy reconstructions of the ISM, in which the
4.2 ka event has been depicted as a singular multi-centennial drought.</p
Morphine paradoxically prolongs neuropathic pain in rats by amplifying spinal NLRP3 inflammasome activation
Pain after disease/damage of the nervous system is predominantly treated with opioids, but without exploration of the long-term consequences. We demonstrate that a short course of morphine after nerve injury doubles the duration of neuropathic pain. Using genetic and pharmacological interventions, and innovative Designer Receptor Exclusively Activated by Designer Drugs disruption of microglia reactivity, we demonstrate that opioid-prolonged neuropathic pain arises from spinal microglia and NOD-like receptor protein 3 inflammasome formation/activation. Inhibiting these processes permanently resets amplified pain to basal levels, an effect not previously reported. These data support the “two-hit hypothesis” of amplification of microglial activation—nerve injury being the first “hit,” morphine the second. The implications of such potent microglial “priming” has fundamental clinical implications for pain and may extend to many chronic neurological disorders
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