Polluted drinking water

While certain solid and liquid agricultural wastes occur in concentrated forms, low-level ground-water contamination in rural areas occurs as a result of the widespread leaching of excess nutrients applied to both arable and pastoral land as inorganic and organic fertilizers. The principal contaminant is nitrate, derived both from fertilizers and as a result of the transformation of organically bound nitrogen in the soil to inorganic forms by bacteria (mineralization) following the ploughing of established and temporary grasslands. The potential quantities of nitrate released for leaching by ploughing may be large, exceeding the total annual quantities of nitrogen normally applied as fertilizers. Increased sulphate and chloride concentrations derived from the use of ammonium sulphate and potassium chloride fertilizers may also occur in drainage water from farmland. The residues of pesticides and herbicides may be leached from the soil and examples of ground-water contamination have been reported.

The principal solid mining wastes that have a potential to pollute ground water come from coal and metal ore exploitation. In the former case, the waste rock, generally sandstone, causes oxidation of the disseminated sulphides leading to the formation of sulphate ions, a lowering of the pH of interstitial fluids, the mobilization of iron and manganese and the physical disintegration of the shale. This produces a leachate high in sulphate, iron and dissolved and suspended solids and low in pH. Drainage waters from collieries characteristically possess both high suspended and high dissolved solids, particularly iron and sulphate ions resulting from the oxidation of ferrous sulphides in the host rocks. Chloride concentrations may also be high because of connate water trapped within the sedimentary rocks. Discharge of such waters on to the ground surface may result in widespread contamination of previously potable ground-water resources.

The risk of infection of ground-water supplies by faecal bacteria from free ranging livestock is generally slight when livestock densities are low, as a result of the complete natural degradation of faeces and urine by soil bacteria when wastes are deposited in a disseminated manner. However, the problem is more serious where animals congregate in large numbers, for example around water holes or in stock yards, in which case large volumes of liquid and semi-solid faecal matter may readily infiltrate to the water table. Even in areas where wells are lined, the rate of production and the highly polluting nature of farmyard slurries and especially silage effluents, necessitate either their collection for treatment or confinement to avoid ground-water contamination.

Household wastes contain a high proportion of putrescible matter which is broken down by biodegradation, leading to an initial temperature rise within the waste mass and the generation of carbon dioxide and methane gases. The leachate contains high concentration of total organic carbon (TOC), of which often more than 80% is in the form of volatile fatty acids (acetic, butryric, etc) and give waste disposal sites their characteristic odour. As the wastes age, the organic carbon component of the leachate changes to higher molecular weight substances such as carbohydrates. The period of this change is between 5 to 10 years in humid, temperate climates, but probably a shorter period in warmer climates. Under arid conditions the rate of bacterial degradation may be limited by lack of moisture.

The composition of industrial wastes varies with the source, ranging from cyanide wastes from metallurgical operations, through sulphite-rich paper and pulp manufacturing wastes, mercury-rich materials from the electrical industry, to solid residues, such as polychlorinated biphenyls (PCBs), pesticide or herbicide residues and phenol-rich tar wastes, from the petrochemical industries. In many cases toxic substances are present which, if solubilized, may present major threats to ground-water quality. In some cases the total quantity of waste occurring is relatively small and co-disposal may afford a method of using the absorption and biodegradation processes in landfills to attenuate the leachate from the industrial materials.

When chlorine is added to the water it may reacts with pollution creating more dangerous chemicals, like chlorophenols. The water pipes in old buildings may contain lead, cadmium and mercury.