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Basement heterogeneity in the Cathaysia crustal block, southeast China (2007)

Fletcher, Chris J. N. ; Chan, Lung. S. ; Sewell, Roderick J. ; [et al.]

In: Geological Society Special Publication 226: 145-155.

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Publication Date: 2007-10-08

Description: Isotope signatures and TDM model ages in Hong Kong and neighbouring Guangdong Province have indicated that the basement of the Cathaysia Block is probably an amalgamation of narrow crustal slices, ranging in age from latest Archaean to Mesoproterozoic. Inheritance ages from zircons contained within Mesozoic volcanic and plutonic rocks also show Proterozoic and Archaean components. Regional gravity survey studies display NNE- to NE-trending Bouguer anomalies that are indicative of sharp changes in rock densities at middle and lower crustal levels. The anomalies displayed on the gravity profile from Guangdong to Hong Kong have been modelled as narrow slices of Archaean and Proterozoic crust. A substantial E-W-trending Bouguer anomaly, which largely parallels the trend of the foliation in the Proterozoic schists of the region, is present to the east of Guangzhou. It is proposed that the basement of the Cathaysia Block consists of an amalgamation of NE- to NNE-trending Palaeo- to Mesoproterozoic and Archaean crustal terranes, which in places have retained the pre-amalgamation E-W-trending tectonic fabric. The discontinuities between the basement terranes, and the E-W structures have strongly influenced the geological evolution of the Phanerozoic sequences and igneous complexes in southeast China. These are most obviously manifest in the regional NE-trending fault and shear zones that displace the cover sequences.

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Quantifying the skill of CMIP5 models in simulating seasonal albedo and snow cover evolution (2015)

Chad W. Thackeray, Christopher G. Fletcher, Chris Derksen

Wiley

In: Journal of Geophysical Research JGR - Atmospheres

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Publication Date: 2015-06-05

Description: Effectively modeling the influence of terrestrial snow on climate in general circulation models (GCMs) is limited by imperfect knowledge and parameterization of arctic and sub-arctic climate processes, and a lack of reliable observations for model evaluation and improvement. This study uses a number of satellite-derived datasets to evaluate how well the current generation of climate models from the fifth Coupled Model Intercomparison Project (CMIP5) simulate the seasonal cycle of climatological snow cover fraction (SCF) and surface albedo over the Northern Hemisphere snow season (September – June). Using a variety of metrics, the CMIP5 models are found to simulate SCF evolution better than that of albedo. The seasonal cycle of SCF is well reproduced despite substantial biases in simulated surface albedo of snow-covered land (α sfc_snow ), which affect both the magnitude and timing of the seasonal peak in α sfc_snow during the fall snow accumulation period, and the springtime snow ablation period. Insolation-weighting demonstrates that the biases in α sfc_snow during spring are of greater importance for the surface energy budget. Albedo biases are largest across the boreal forest, where the simulated seasonal cycle of albedo is biased high in 15/16 CMIP5 models. This bias is explained primarily by unrealistic treatment of vegetation masking and subsequent overestimation (more than 50% in some cases) of peak α sfc_snow , rather than by biases in SCF. While seemingly straightforward corrections to peak α sfc_snow could yield significant improvements to simulated snow albedo feedbacks, changes in α sfc_snow could potentially introduce biases in other important model variables such as surface temperature.

Print ISSN: 0148-0227

Topics: Geosciences , Physics

Published by Wiley on behalf of American Geophysical Union (AGU).

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Kinetic Equilibrium and Stability Analysis of Dipolarization Fronts (2019)

Alex C. Fletcher, Chris Crabtree, Gurudas Ganguli, David Malaspina, Erik Tejero, Xiangning Chu

Wiley

In: Journal of Geophysical Research: Space Physics

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Publication Date: 2019

Description: Abstract Dipolarization fronts are typically observed with a density gradient of scale size comparable to an ion gyroradius, which naturally results in an ambipolar electric field in the direction of the gradient. Prevailing models ignore this ambipolar electric field, the separation of ion and electron scale physics, and consequent non‐Maxwellian plasma distributions with strong spatial gradients in velocity, all of which we investigate in this paper. We examine two dipolarization front events observed by the Magnetospheric Multiscale (MMS) mission (one with low plasma beta, one with high plasma beta), develop a rigorous kinetic equilibrium for dipolarization fronts, analyze the linear stability, and explore the nonlinear evolution and observable signatures with kinetic simulations. There are two major drivers of instability in the lower hybrid frequency range: the density gradient (lower hybrid drift instability) and the velocity shear (electron‐ion hybrid instability). We argue the electron‐ion hybrid mode is dominant, and consequently a dipolarization front approaches a steady or saturated state through the emission of waves that relax the velocity shear. A key aspect of these shear‐driven waves is a broadband frequency spectrum that is consistent with satellite observation.

Print ISSN: 2169-9380

Electronic ISSN: 2169-9402

Topics: Geosciences , Physics

Published by Wiley on behalf of American Geophysical Union (AGU).

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The influence of canopy snow parameterizations on snow albedo feedback in boreal forest regions (2014)

Chad W. Thackeray, Christopher G. Fletcher, Chris Derksen

Wiley

In: Journal of Geophysical Research JGR - Atmospheres

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Publication Date: 2014-08-12

Description: Variation in snow albedo feedback (SAF) among CMIP5 climate models has been shown to explain much of the variation in projected 21st Century warming over Northern Hemisphere land. Prior studies using observations and models have demonstrated both considerable spread in the albedo, and a negative bias in the simulated strength of SAF, over snow-covered boreal forests. Boreal evergreen needleleaf forests are capable of intercepting snowfall throughout the winter, and consequently exert a significant impact on seasonal surface albedo. Two satellite data products and tower-based observations of albedo are compared with simulations from multiple versions of the Community Climate System Model (CCSM4) to investigate the causes of weak simulated SAF over the boreal forest. The largest bias occurs in April-May, when simulated SAF is one-half the strength of SAF in observations. This is traced to two features of the canopy snow parameterizations used in the land model. First, there is no mechanism for the dynamic removal of snow from the canopy when temperatures are below freezing, which results in albedo values in midwinter that are biased high. Second, when temperatures do rise above freezing, all snow on the canopy is melted instantaneously, which results in an unrealistically early transition from a snow-covered to a snow-free canopy. These processes combine to produce large differences between simulated and observed monthly albedo, and are the source of the weak bias in SAF. This analysis highlights the importance of canopy snow parameterizations for simulating the hemispheric scale climate response to surface albedo perturbations.

Print ISSN: 0148-0227

Topics: Geosciences , Physics

Published by Wiley on behalf of American Geophysical Union (AGU).

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