S A Parsons
Overview
Explore the profile of S A Parsons including associated specialties, affiliations and a list of published articles.
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35
Citations
188
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Recent Articles
1.
Golea D, Jarvis P, Jefferson B, Moore G, Sutherland S, Parsons S, et al.
Water Res
. 2020 Feb;
174:115613.
PMID: 32092546
Operational and financial constraints challenge effective removal of natural organic matter (NOM), and specifically disinfection by-product (DBP) precursors, at remote and/or small sites. Granular activated carbon (GAC) is a widely...
2.
Golea D, Upton A, Jarvis P, Moore G, Sutherland S, Parsons S, et al.
Water Res
. 2017 Feb;
112:226-235.
PMID: 28167408
The disinfection by-product (DBP) formation potential (FP) of natural organic matter (NOM) in surface water sources has been studied with reference to the key water quality determinants (WQDs) of UV...
3.
Bond T, Goslan E, Parsons S, Jefferson B
Environ Technol
. 2011 Apr;
32(1-2):1-25.
PMID: 21473265
Formation of harmful disinfection by-products (DBPs), of which trihalomethanes (THMs) and haloacetic acids (HAAs) are the major groups, can be controlled by removal of natural organic matter (NOM) before disinfection....
4.
Murray D, Jefferson B, Jarvis P, Parsons S
Environ Technol
. 2010 May;
31(4):455-66.
PMID: 20450120
Algal blooms are a significant problem in the UK, particularly in water sources that supply potable water treatment works. A wide range of methods to control algae have been tested...
5.
Bond T, Goslan E, Parsons S, Jefferson B
Water Res
. 2010 Jan;
44(5):1645-53.
PMID: 20042213
Potentially the most effective means of controlling disinfection by-products (DBPs) is to remove precursors before disinfection. To understand relationships between physical properties, treatability and DBP formation, nine natural organic matter...
6.
Martin B, Parsons S, Jefferson B
Water Sci Technol
. 2009 Nov;
60(10):2637-45.
PMID: 19923770
A new type of ion exchange media which is highly selective for phosphate, and can be easily regenerated has been investigated. The media consists of hydrated ferric oxide nanoparticles dispersed...
7.
Bond T, Henriet O, Goslan E, Parsons S, Jefferson B
Environ Sci Technol
. 2009 Sep;
43(15):5982-9.
PMID: 19731707
While natural organic matter (NOM) surrogates are established in disinfection byproduct (DBP) research, their use in fractionation studies is rare. To understand how surrogates relate to drinking waters, a range...
8.
Bond T, Goslan E, Jefferson B, Roddick F, Fan L, Parsons S
Water Res
. 2009 Apr;
43(10):2615-22.
PMID: 19375771
Formation of disinfection by-products (DBPs) can be controlled by removal of disinfection by-product precursors before disinfection. Variable success has been reported, depending on the treatment used and water tested. Chemical...
9.
Le Corre K, Valsami-Jones E, Hobbs P, Parsons S
Environ Technol
. 2008 Mar;
28(12):1317-24.
PMID: 18341142
The presence of white deposits in specific areas of wastewater treatment plants is generally the consequence of the spontaneous formation of a mineral called struvite. Struvite forms when the levels...
10.
Le Corre K, Valsami-Jones E, Hobbs P, Parsons S
Environ Technol
. 2008 Feb;
28(11):1245-56.
PMID: 18290534
A pilot scale reactor was designed and developed to study struvite crystallisation principles. The present work focuses on the possible impact of the reactor's operating parameters on struvite characteristics, and...