Your search keyword '"Knights, Kate V."' showing total 7 results

1. The collection of drainage samples for environmental analyses from active stream channels

Author

Johnson, Christopher C., primary, Flight, Dee M.A., additional, Ander, E. Louise, additional, Lister, Thomas R., additional, Breward, Neil, additional, Fordyce, Fiona M., additional, Nice, Sarah E., additional, and Knights, Kate V., additional

Published

2024

2. Contributors

Author

Adamo, Paola, primary, Agrelli, Diana, additional, Albanese, Stefano, additional, Ander, E. Louise, additional, Auriemma, Giovanni, additional, Ayuso, Robert A., additional, Belkin, Harvey E., additional, Benvenuti, Marco, additional, Breward, Neil, additional, Caporale, Antonio Giandonato, additional, Chen, Wei, additional, Ciani, Francesco, additional, Cicchella, Domenico, additional, Costagliola, Pilario, additional, De Feudis, M., additional, De Vivo, Benedetto, additional, Devi, Ningombam Linthoingambi, additional, Di Bonito, Marcello, additional, Ding, Yang, additional, Doherty, Angela L., additional, Donatelli, Anna, additional, Finkelman, Robert B., additional, Flight, Dee M.A., additional, Foley, Nora K., additional, Fordyce, Fiona M., additional, Gianni, Roberto, additional, Groenenberg, J.E., additional, Huang, Huanfang, additional, Huang, Xuelian, additional, Johnson, Christopher C., additional, Knights, Kate V., additional, Laor, Efraim, additional, Lastrucci, Lorenzo, additional, Lattanzi, Pierfranco, additional, Lessard, Robert, additional, Lima, Annamaria, additional, Lister, Thomas R., additional, Liu, Hong-Xia, additional, Liu, Wei, additional, Lofts, S., additional, Lyles, Mark B., additional, Manno, Maurizio, additional, Nepi, Chiara, additional, Nice, Sarah E., additional, Orem, William H., additional, Pignotti, Lia, additional, Plumlee, Geoffrey S., additional, Qi, Shihua, additional, Qian, Zhe, additional, Qu, Chengkai, additional, Reeder, Shaun, additional, Rimondi, Valentina, additional, Roberts, Eric, additional, Salminen, Reijo, additional, Selinus, Olle, additional, Smith, B., additional, Stuart, Marianne, additional, Sun, Wen, additional, Swyngedouw, Chris, additional, Trick, Julian K., additional, Xing, Xinli, additional, Xiong, Junwu, additional, Yang, Dan, additional, Zampella, Mariavittoria, additional, Zeng, Fa-Ming, additional, Zhang, H., additional, Zhang, Jiaquan, additional, Zhang, Yuan, additional, and Zhou, Hong, additional

Published

2024

3. Contributors

Author

Adamo, Paola, primary, Agrelli, Diana, additional, Albanese, Stefano, additional, Ander, E. Louise, additional, Ayuso, Robert A., additional, Bareschino, Piero, additional, Belkin, Harvey E., additional, Breward, Neil, additional, Cicchella, Domenico, additional, Crout, Neil, additional, De Vivo, Benedetto, additional, Devi, Ningombam Linthoingambi, additional, Di Bonito, Marcello, additional, Doherty, Angela L., additional, Finkelman, Robert B., additional, Flight, Dee M.A., additional, Foley, Nora K., additional, Fordyce, Fiona M., additional, Govil, Pradip K., additional, Groenenberg, Jan E., additional, Huang, Liuqin, additional, Iadarola, Monica, additional, Jiang, Hongchen, additional, Johnson, Christopher C., additional, Knights, Kate V., additional, Krishna, Aradhi K., additional, Lessard, Robert, additional, Lima, Annamaria, additional, Lister, Thomas R., additional, Liu, Hong-Xia, additional, Lofts, Sthephen, additional, Lyles, Mark B., additional, Nice, Sarah E., additional, Orem, William H., additional, Pepe, Francesco, additional, Piatak, Nadine M., additional, Plumlee, Geoffrey S., additional, Qi, Shihua, additional, Qu, Chengkai, additional, Reeder, Shaun, additional, Salminen, Reijo, additional, Sears, Cynde, additional, Selinus, Olle, additional, Smith, Barry, additional, Stuart, Marianne, additional, Sun, Wen, additional, Swyngedouw, Chris, additional, Trick, Julian K., additional, Wu, Geng, additional, Xing, Xinli, additional, Yang, Dan, additional, Yang, Jian, additional, Young, Scott D., additional, Zampella, Mariavittoria, additional, Zeng, Fa-Ming, additional, Zhang, Hao, additional, Zhang, Yuan, additional, and Zhang, Jia-Quan, additional

Published

2018

4. The Collection of Drainage Samples for Environmental Analyses From Active Stream Channels

Author

Johnson, Christopher C., primary, Flight, Dee M.A., additional, Ander, E. Louise, additional, Lister, Thomas R., additional, Breward, Neil, additional, Fordyce, Fiona M., additional, Nice, Sarah E., additional, and Knights, Kate V., additional

Published

2018

5. International Union of Geological Sciences Manual of Standard Methods for Establishing the Global Geochemical Reference Network

Author

Demetriades, Alecos, Johnson, Christoper C., Smith, David B., Ladenberger, Anna, Adánez Sanjuan, Paula, Argyraki, Ariadne, Stouraiti, Christina, Caritat, Patrice de, Knights, Kate V., Prieto Rincón, Gloria, and Simubali, Gloria Namwi

Subjects

baseline studies, sampling, data conditioning, geochemical surveys, sample preparation, stream water, rock, stream sediment, humus, floodplain sediment, reference materials, project management, analytical methods, sample storage, map production, data management, quality control, overbank sediment, residual soil

Abstract

Source web page: https://www.globalgeochemicalbaselines.eu/content/174/iugs-manual-of-standard-methods-for-establishing-the-global-geochemical-reference-network-/ SYNOPSIS “Everything in and on the Earth - mineral, animal and vegetable - is made from one, or generally some combination of, the natural chemical elements occurring in the rocks of the Earth’s crust and the surficial materials derived from them. Everything that is grown, or made, depends upon the availability of the appropriate elements. The existence, quality and survival of life depends upon the availability of elements in the correct proportions and combinations. Because natural processes and human activities are continuously modifying the chemical composition of our environment, it is important to determine the present abundance and spatial distribution of the elements across the Earth’s surface in a much more systematic manner than has been attempted hitherto” (Darnley et al., 1995, p.x). Although such a global database is urgently needed for multi-purpose use, the systematic attempt is still in its infancy because of the non-existence of a manual of comprehensive and standardised methods of sampling and other supporting procedures. The current ‘International Union of Geological Sciences Manual of Standard Methods for Establishing the Global Geochemical Reference Network’ fills this gap. The Manual follows the concept of 7356 Global Terrestrial Network grid cells of 160x160 km, covering the land surface of Earth, with five random sites within each grid cell for the collection of samples. This allows the establishment of the standardised Global Geochemical Reference Network with respect to rock, residual soil, humus, overbank sediment, stream water, stream sediment and floodplain sediment. Apart from the instructions for the collection of samples, the Manual covers sample preparation and storage, development of reference materials, geoanalytical methods, quality control procedures, geodetic and parametric levelling of existing geochemical data sets, data conditioning for the generation of time-independent geochemical data, management of data and map production, and finally project management. This Manual presents, for the first time a comprehensive overview of the standardised methods that should be employed across the land surface of the Earth to map the distribution of chemical elements in rock, soil, sediment and water. The methods described herein, apart from their use for Establishing the Global Geochemical Reference Network, can be used in other geochemical surveys at any mapping scale. The URL of the pdf file is: https://www.globalgeochemicalbaselines.eu/datafiles/file/IUGS-CGGB_2022_Manual_of_Standard_Methods_for_Establishing_the_GGRN.pdf IUGS APPROVAL FOR PUBLICATION The Executive Committee of the International Union of Geological Sciences at its 77th meeting in Paris (16-18 March 2022), unanimously approved the “International Union of Geological Sciences Manual of Standard Methods for Establishing the Global Geochemical Reference Network” to be published as a formal IUGS Publication for its 60th Anniversary celebration. The IUGS Executive Committee members John Ludden (President), Hassina Mouri (Vice President), Daekyo Cheong (Vice President), Stanley C. Finney (Secretary-General), Hiroshi Kitazato (Treasurer), Qiuming Cheng (Past President), Silvia Peppoloni (Councillor), Claudia Inés Mora (Councillor), Jennifer McKinley (Councillor), and Ludwig Stroink (Councillor) are thanked for approving the publication of this Manual. Supplementary material The supplementary material provided in different Chapters and Annexes is very important and should be consulted: Chapter 2 Supplementary material Chapter 2 Annexe A2.1 Supplementary material Chapter 3.2 Annexe A3.2.1 Supplementary material Chapter 7 Supplementary material Chapter 8 Supplementary material An innovation for this freely available publication is the provision of the original MicrosoftTM Word files, Original figures, and PowerPoint presentations with embedded figures: Chapter files: Word text; Original figures; PowerPoint presentations, CITATION: Demetriades, A., Johnson, C.C., Smith, D.B., Ladenberger, A., Adánez Sanjuan, P., Argyraki, A., Stouraiti, C., Caritat, P. de, Knights, K.V., Prieto Rincón, G. & Simubali, G.N. (Editors), 2022. International Union of Geological Sciences Manual of Standard Methods for Establishing the Global Geochemical Reference Network. IUGS Commission on Global Geochemical Baselines, Athens, Hellenic Republic, Special Publication, 2, 515 pp.; https://doi.org/10.5281/zenodo.7307696.

Published

2022

6. The collection of drainage samples for environmental analyses from active stream channels

Author

De Vivo, Benedetto, Belkin, Harvey E., Lima, Annamaria, Johnson, Christopher C., Flight, Dee M.A., Ander, E. Louise, Lister, Thomas R., Breward, Neil, Fordyce, Fiona M., Nice, Sarah E., Knights, Kate V., De Vivo, Benedetto, Belkin, Harvey E., Lima, Annamaria, Johnson, Christopher C., Flight, Dee M.A., Ander, E. Louise, Lister, Thomas R., Breward, Neil, Fordyce, Fiona M., Nice, Sarah E., and Knights, Kate V.

Abstract

The collection of drainage samples from active stream channels for geochemical mapping is now a well-established procedure that has readily been adapted for environmental studies. This account details the sampling methods used by the British Geological Survey in order to establish a geochemical baseline for the land area of Great Britain. This involves the collection of stream sediments, waters and panned heavy mineral concentrates for inorganic chemical analysis. The methods have been adapted and used in many different environments around the world. Detailed sampling protocols are given and sampling strategy, equipment and quality control are discussed.

Published

2017

7. Investigating the high Zr values in the fine fraction of stream sediments in Nigeria

Author

Key, Roger M., Johnson, Chris C., Horstwood, Matthew S.A., Lapworth, Daniel J., Knights, Kate V., Kemp, Simon J., Adekanmi, Michael, Arisekola, Tunde, Everett, Paul, Key, Roger M., Johnson, Chris C., Horstwood, Matthew S.A., Lapworth, Daniel J., Knights, Kate V., Kemp, Simon J., Adekanmi, Michael, Arisekola, Tunde, and Everett, Paul

Abstract

Regional geochemical surveys in Nigeria have consistently found very high concentrations of Zr in the fine (<150μm) fraction of stream sediments irrespective of underlying bedrock in upstream catchment areas. For example, mean/maximum Zr values of about 0.2%/2.3% and 0.3%/2.6% were determined in about 1600 analysed stream sediments collected from two 160X160 km2 Global Reference Network (GRN) cells[1] in central (the ‘Minna Cell‘) and SW (the ’South-western Cell‘) Nigeria respectively [2, 3]. X-ray diffraction (XRD) studies on a sub-set of the analysed stream sediments showed that Zr is predominantly found in detrital zircons grains. The main proximal source rocks for the analysed stream sediments are the widespread Pan-African, late Neoproterozoic ‘Older Granites’ of Nigeria, their Palaeoproterozoic-Neoproterozoic migmatitic gneiss country rocks and a local cover of Cretaceous siliciclastic sedimentary strata. However, these rocks are not enriched in zircon so the zircon enrichment in the stream sediment must be due to surficial processes. A combination of tropical/chemical weathering and physical weathering involving a combination of wind winnowing during the dry season and flash flooding during the rainy season has effectively broken down bedrock silicate minerals and removed much of the resultant clay phases. The weathering has formed quartz-rich stream sediments enriched in resistant ‘heavy’ minerals, including zircon. U-Pb LA-MC-ICP-MS dating with cathodoluminescence (CL) imaging on detrital zircons from four stream sediment samples (and on zircons extracted from underlying Pan-African ‘Older Granites’) confirms a local bedrock source for the stream sediment zircons. None of the examined zircon grains show significant signs of rounding which you might expect from transported distal material. Detrital zircon grains collected from two stream sediment samples with Older Granite-dominated catchment geology give 630-640 Ma age populations identical to the determine

Published

2011