Samuel Shaw
Overview
Explore the profile of Samuel Shaw including associated specialties, affiliations and a list of published articles.
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Snapshot
Articles
42
Citations
250
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0
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Recent Articles
1.
Neill T, Morris K, Harrison S, Apps P, Bryan N, Parry S, et al.
J Hazard Mater
. 2025 Feb;
489:137629.
PMID: 39983641
Colloids present a challenge for nuclear decommissioning and disposal due to their potential to mobilise radionuclides. Waste retrieval and decommissioning of storage ponds for spent nuclear fuel and silos for...
2.
Peter T, Takacs D, Saringer S, Szerlauth A, Sajdik K, Galbacs G, et al.
ACS ES T Water
. 2024 Dec;
4(7):3059-3067.
PMID: 39712466
Effective uranium (U) capture is required for the remediation of contaminated solutes associated with the nuclear fuel cycle, including fuel reprocessing effluents, decommissioning, or nuclear accident cleanup. Here, interactions between...
3.
Zhang J, Zhu M, Lloyd J, Shaw S, Coker V, Xie J, et al.
Environ Sci Technol
. 2024 Nov;
58(49):21653-21661.
PMID: 39602585
Molybdenum (Mo) is an essential nutrient for almost all organisms. However, at high concentrations, it can be toxic to animals and plants. This study investigated the interactions of Mo(VI) with...
4.
Lopez-Odriozola L, Shaw S, Abrahamsen-Mills L, Waters C, Natrajan L
Environ Sci Technol
. 2024 Sep;
58(40):17916-17925.
PMID: 39315992
The significant abundance of uranium in radioactive waste inventories worldwide necessitates a thorough understanding of its behavior. In this work, the speciation of uranyl(VI), (UO) in a gibbsite system under...
5.
White-Pettigrew M, Shaw S, Hughes L, Boothman C, Graham J, Abrahamsen-Mills L, et al.
ACS Earth Space Chem
. 2024 Mar;
8(3):483-498.
PMID: 38533191
Microbial ureolysis offers the potential to remove metals including Sr as carbonate minerals via the generation of alkalinity coupled to NH and HCO production. Here, we investigated the potential for...
6.
Eshun L, Coker V, Shaw S, Lloyd J
Environ Res
. 2023 Nov;
242:117667.
PMID: 37980994
Vivianite (Fe(PO)·8HO), a sink for phosphorus, is a key mineralization product formed during the microbial reduction of phosphate-containing Fe(III) minerals in natural systems, and also in wastewater treatment where Fe(III)-minerals...
7.
Barton F, Spencer B, Tartese R, Graham J, Shaw S, Morris K, et al.
Biofouling
. 2023 Oct;
39(8):785-799.
PMID: 37877442
Nuclear facility discharge pipelines accumulate inorganic and microbial fouling and radioactive contamination, however, research investigating the mechanisms that lead to their accumulation is limited. Using the Sellafield discharge pipeline as...
8.
Robinson C, Shaw S, Lloyd J, Graham J, Morris K
ACS ES T Water
. 2023 Oct;
3(10):3223-3234.
PMID: 37854271
Historical operations at nuclear mega-facilities such as Hanford, USA, and Sellafield, UK have led to a legacy of radioactivity-contaminated land. Calcium phosphate phases (e.g., hydroxyapatite) can adsorb and/or incorporate radionuclides,...
9.
Fallon C, Bower W, Powell B, Livens F, Lyon I, McNulty A, et al.
Sci Total Environ
. 2022 Dec;
862:160862.
PMID: 36521613
Uranium dioxide (UO) and metaschoepite (UO•nHO) particles have been identified as contaminants at nuclear sites. Understanding their behavior and impact is crucial for safe management of radioactively contaminated land and...
10.
Stagg O, Morris K, Townsend L, Kvashnina K, Baker M, Dempsey R, et al.
Environ Sci Technol
. 2022 Nov;
56(24):17643-17652.
PMID: 36449568
Over 60 years of nuclear activity have resulted in a global legacy of contaminated land and radioactive waste. Uranium (U) is a significant component of this legacy and is present...