Your search keyword '"TERRESTRIAL"' showing total 3 results

1. Reconstructing Terrestrial Paleoclimates: A Comparison of the Co‐Existence Approach, Bayesian and Probability Reconstruction Techniques Using the UK Neogene.

Author

Gibson, M. E., McCoy, J., O'Keefe, J. M. K., Nuñez Otaño, N. B., Warny, S., and Pound, M. J.

Subjects

NEOGENE Period, MARINE west coast climate, ATMOSPHERIC circulation, COINTEGRATION, MIOCENE Epoch, PROBABILITY theory, PLIOCENE Epoch

Abstract

Neogene sediments in the UK are ideally situated for understanding the early development of hydrological dynamics and atmospheric circulation that led to the modern oceanic climate of northwest Europe. Onshore Neogene fossiliferous deposits in the UK are limited to the solution pipe fills at Trwyn y Parc in Anglesey (Middle Miocene), the Brassington Formation of Derbyshire (Serravallian‐Tortonian), and the Coralline Crag Formation (latest Zanclean‐earliest Piacenzian) and Red Crag Formation (Piacenzian‐Gelasian) in southeast England. Palynoflora from these localities can be used to provide snapshots into the climate at the time of deposition, however, palaeobotanical‐based reconstructions are typically lacking in their poor estimation of error. Therefore, we present the first pre‐Quaternary application of two terrestrial climate reconstruction techniques: CREST (Climate Reconstruction SofTware) and CRACLE (Climate Reconstruction Analysis using Coexistence Likelihood Estimation), that use Bayesian and likelihood estimation probability respectively to generate a new palaeoclimate reconstruction, and compare this to Co‐existence Approach reconstructions from the UK and continental Europe. Our study shows how Mean Annual Temperature (MAT) declines by 3°–6°C, Mean Annual Precipitation (MAP) declines by 480–600 mm and Precipitation Seasonality approximately halves throughout the Neogene. CREST and CRACLE reconstructions overlap with the Co‐exisence Approach and have the advantage of providing uncertainty, rather than ranges. The UK appears to have had a milder, wetter, and less seasonal climate than continental Europe. This is likely due to the buffering effects of the Atlantic Ocean and North Sea ameliorating the UK Neogene climate despite regional and global changes in atmospheric and oceanic circulation. Key Points: A new probability‐based terrestrial Neogene climate reconstruction for the UKReconstructions are in line with previous terrestrial reconstructions and independent proxy reconstructions from the wider regionMiocene and Pliocene reconstructions align with predictions for future anthropogenic warming by 2100 [ABSTRACT FROM AUTHOR]

Published

2022

2. Arsenic speciation in the bracket fungus Fomitopsis betulina from contaminated and pristine sites.

Author

Button, Mark, Koch, Iris, Watts, Michael J., and Reimer, Kenneth J.

Subjects

HAZARDOUS waste sites, X-ray absorption near edge structure, ARSENIC, CHEMICAL speciation, INDUCTIVELY coupled plasma mass spectrometry, ARSENIC compounds

Abstract

Uptake, distribution and speciation of arsenic (As) were determined in the bracket fungus Fomitopsis betulina (previously Piptoporus betulinus), commonly known as the birch polypore, collected from a woodland adjacent to a highly contaminated former mine in the Southwest UK and at an uncontaminated site in Quebec, Canada, with no past or present mining activity. The fruiting body was divided into cap, centre and pores representing the top, middle and underside to identify trends in the distribution and transformation of As. Total As, determined by inductively coupled plasma–mass spectrometry (ICP–MS), was approximately tenfold higher in the mushroom from the contaminated compared to the uncontaminated site. Overall, accumulation of As was low relative to values reported for some soil-dwelling species, with maximum levels of 1.6 mg/kg at the contaminated site. Arsenic speciation was performed on aqueous extracts via both anion and cation high-performance liquid chromatography–ICP–MS (HPLC–ICP–MS) and on whole dried samples using X-ray absorption near edge structure (XANES) analysis. Seven As species were detected in F. betulina from the contaminated site by HPLC–ICP–MS: arsenite (AsIII), arsenate (AsV), dimethylarsinate (DMAV), methylarsonate (MAV), trimethylarsine oxide (TMAO), tetramethylarsonium ion (Tetra) and trace levels of arsenobetaine (AB). The same As species were observed at the uncontaminated site with the exception of TMAO and Tetra. Arsenic species were localized throughout the fruiting body at the contaminated site, with the cap and pores containing a majority of AsV, only the cap containing TMAO, and the pores containing higher concentrations of DMAV and MAV as well as tetra and a trace of AB. XANES analysis demonstrated that the predominant form of As at the contaminated site was inorganic AsIII coordinated with sulphur or oxygen and AsV coordinated with oxygen. This is the first account of arsenic speciation in F. betulina or any fungi of the family Fomitopsidaceae. [ABSTRACT FROM AUTHOR]

Published

2020

3. Horizon scanning for invasive alien species with the potential to threaten biodiversity in Great Britain.

Author

Roy, Helen E., Peyton, Jodey, Aldridge, David C., Bantock, Tristan, Blackburn, Tim M., Britton, Robert, Clark, Paul, Cook, Elizabeth, Dehnen‐Schmutz, Katharina, Dines, Trevor, Dobson, Michael, Edwards, François, Harrower, Colin, Harvey, Martin C., Minchin, Dan, Noble, David G., Parrott, Dave, Pocock, Michael J. O., Preston, Chris D., and Roy, Sugoto

Subjects

*INTRODUCED organisms & the environment, *BIODIVERSITY, *FRESHWATER invertebrates, *PLANTS

Abstract

Invasive alien species ( IAS) are considered one of the greatest threats to biodiversity, particularly through their interactions with other drivers of change. Horizon scanning, the systematic examination of future potential threats and opportunities, leading to prioritization of IAS threats is seen as an essential component of IAS management. Our aim was to consider IAS that were likely to impact on native biodiversity but were not yet established in the wild in Great Britain. To achieve this, we developed an approach which coupled consensus methods (which have previously been used for collaboratively identifying priorities in other contexts) with rapid risk assessment. The process involved two distinct phases: Preliminary consultation with experts within five groups (plants, terrestrial invertebrates, freshwater invertebrates, vertebrates and marine species) to derive ranked lists of potential IAS., Consensus-building across expert groups to compile and rank the entire list of potential IAS., Five hundred and ninety-one species not native to Great Britain were considered. Ninety-three of these species were agreed to constitute at least a medium risk (based on score and consensus) with respect to them arriving, establishing and posing a threat to native biodiversity. The quagga mussel, Dreissena rostriformis bugensis, received maximum scores for risk of arrival, establishment and impact; following discussions the unanimous consensus was to rank it in the top position. A further 29 species were considered to constitute a high risk and were grouped according to their ranked risk. The remaining 63 species were considered as medium risk, and included in an unranked long list. The information collated through this novel extension of the consensus method for horizon scanning provides evidence for underpinning and prioritizing management both for the species and, perhaps more importantly, their pathways of arrival. Although our study focused on Great Britain, we suggest that the methods adopted are applicable globally. [ABSTRACT FROM AUTHOR]

Published

2014