We review the current state of knowledge of quantified impacts of invasive alien plants on water quality, with a focus on South Africa. In South Africa, over 200 introduced plant species are regarded as invasive. Many of these species are particularly prominent in riparian ecosystems and their spread results in native species loss, increased biomass and fire intensity and consequent erosion, as well as decreased river flows. Research on the impact of invasive alien plants on water resources has historically focused on water quantity. However, although invasive alien plants also affect the quality of water, this aspect has not been well documented. Alien invasive plants increase evaporation rates, and reduce stream flow and dilution capacity. The biomass inputs of alien invasive plants, especially nitrogen fixers such as Acacia spp., alter nutrient cycles and can elevate nutrient concentrations in groundwater. Alien plant invasions alter the fire regimes in invaded areas by changing the size, distribution and plant chemistry of the biomass. More intense fires increase soil erosion and thereby decrease water quality. In contrast to riparian invasions, aquatic invasive plants have been more extensively studied in South Africa and their impacts on water quality have been relatively well monitored. Water quality in South Africa is rapidly deteriorating, and all factors that influence this deterioration need to be taken into account when formulating actions to address the problem. The changes in water quality brought about by alien plant invasions can exacerbate the already serious water quality problems.
Keywords:Heavy metals Oestradiol Human health Microbial pathogens Water quality abstract Water quality has deteriorated in the upper Olifants River system, South Africa, as a result of land use activities which include mining, agriculture and industries. A health risk assessment was conducted from 2009 to 2011 in the catchment to determine the possible risks local communities face from various pollutants such as microbials, heavy metals and oestrogen in the river water and vegetation. Aluminium and manganese accumulated in plants and vanadium and aluminium concentrations found in selective water samples posed significant health risks when consumed. A quantitative microbial risk assessment revealed that the combined risk of infection ranged from 1 to 26 percent with the Norovirus posing the overall greatest health risk. The anticipated disability adjusted life years resulting from drinking untreated water from these sites are in the order of 10,000 times greater than what is considered acceptable. The oestradiol activity, caused by endocrine disrupting compounds in the water, measured above the trigger value of 0.7 ng L −1 . Impoverished communities in the area, who partially depend on river water for potable and domestic use, are exposed to immune-compromising metals that increase their probability of infection from waterborne diseases caused by the excess microbial pathogens in the contaminated surface water.
Ammonium hexachloroplatinate (NH 4) 2 PtCl 6, owing to its low solubility in NH 4 Cl containing aqueous solutions, is an intermediate compound during the hydrometallurgical extraction of platinum. As a rare example of a water soluble and air stable platinum(IV) salt that is not hygroscopic, (NH 4) 2 PtCl 6, may be a convenient and economic platinum precursor for large-scale catalyst production. This report investigates the feasibility of (NH 4) 2 PtCl 6 as Pt precursor for synthesis of the electrocatalysts for polymer electrolyte membrane fuel cells (PEMFCs), i.e., the Pt supported on high surface area carbon (Pt/C). The Pt/C electrocatalysts with ~20 wt.% Pt loading are synthesized through a microwave assisted polyol synthesis approach. The reaction parameters, namely the reaction time and the reaction temperature are optimized. In terms of the electrochemical surface area, Pt/C electrocatalyst synthesized at a reaction temperature of 140 o C and a reaction time of 150 s using a Pt concentration of 5 mM exhibited the optimal performance. The process may be used to synthesize
Even with a reduction in the metal concentrations in river water from South Africa to Mozambique, the potential to cause adverse human health impacts from direct use of polluted river water is evident in both countries.
A water-assisted control of Pt nanoparticle
size during a surfactant-free,
microwave-assisted polyol synthesis of the carbon-supported platinum
nanoparticles (Pt/C) in a mixture of ethylene glycol and water using
(NH4)2PtCl6 as the Pt precursor is
demonstrated. The particle size was tuned between ∼2 and ∼6
nm by varying either the H2O volume percent or the Pt precursor
concentration during synthesis. The electrochemical surface area (ECSA)
and the oxygen-reduction reaction activity obtained for the Pt/C electrocatalyst
show a catalytic performance competitive to that of the state-of-the-art
commercial Pt/C electrocatalysts used for polymer electrolyte membrane
fuel cell electrodes (ECSA: ∼70 m2/g; half-wave
potential for oxygen reduction reaction: 0.83 V vs reversible hydrogen
electrode). The synthesized Pt/C electrocatalysts show durability
equivalent to or better than that of the commercial Pt/C. The durability
was found to improve with increasing particle size, with the ECSA
loss values being ∼70 and ∼55% for the particle sizes
of 2.1 and 4.3 nm, respectively. The study may be used as a route
to synthesize Pt/C electrocatalysts from a convenient and economic
Pt precursor (NH4)2PtCl6 and avoiding
the use of alkaline media.
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