Natural gas drilling with high volu

Natural gas drilling with high volume horizontal hydraulic fracturing (hereafter referred to as fracking) has exploded onto the energy scene in the last 5 or 6 years, and the promise of vast stores of natural gas under American soil has prompted a true natural gas rush. Once the technology was developed, new drill rigs appeared all over landscapes in Pennsylvania, Ohio, West Virginia, Texas, and Wyoming.
Many have worries about the environmental consequences of this new approach to drilling; here are some of those concerns.
Drill Cuttings
During the drilling process, large amounts of ground up rock, mixed with drilling mud and brine, are pulled out of the well and transported off the site. This waste then gets buried in landfills. Beside the large waste volume that needs to be accommodated, a concern with drill cuttings is the presence of naturally occurring radioactive materials in them. Radium and uranium can be found in drill cuttings (and produced water – see below) from a proportion of wells, and these elements eventually leach out of the landfills into the surrounding ground and surface waters.
Water Use
Once a well has been drilled, large amounts of water are pumped into the well at very high pressure to fracture the rock in which the natural gas is located. During a single fracking operation on a single well (wells can be fracked multiple times over their lifetime), on average 4 million gallons of water are used. This water is pumped from streams or rivers and trucked to the site, bought from municipal water sources, or is reused from other fracking operation.
Many are concerned about these important water withdrawals, and worried that it may lower the water table in some areas, leading to dry wells and degraded fish habitat.
Fracking Chemicals
A long, varying list of chemical additives is added to the water in the fracking process. The toxicity of these additives is variable, and many new chemical compounds are created during the fracking process as some of the added ingredients break-down. Once the fracking water returns to the surface, it needs to be treated before disposal (see Water Disposal below). The amount of chemicals added represents a very small fraction of the total volume of fracking water (around 1%).
However, this very small fraction detracts from the fact that in absolute terms it is rather large volumes that are used. For a well requiring 4 million gallons of water, about 40,000 gallons of additives are pumped in. The greatest risks associated with these chemicals occur during their transportation, as tanker trucks must use the local roads to bring them to the drill pads. An accident involved spilled contents would have significant public safety and environmental consequences.
Water Disposal
A large proportion of the prodigious amounts of water pumped down the well flows back up when the well starts producing natural gas. Besides the fracking chemicals, brine that was naturally present in the shale layer comes back up, too. This amounts to a large volume of liquid that is released into a lined pond, then pumped into trucks and transported to either be recycled for other drilling operations, or to be treated. This “produced water” is toxic, containing fracking chemicals, high concentrations of salt, and sometimes radioactive materials like radium and uranium. Heavy metals from the shale are of concern too: produced water will contain lead, arsenic, barium, and strontium for example. Spills from failed retention ponds or botched transfers to trucks do happen and have an impact on local streams and wetlands. Then, the water disposal process is not trivial.
One method is injection wells. Waste water is injected into the ground at great depths under impermeable rock layers. The extremely high pressure used in this process is blamed for earthquake swarms in Texas, Oklahoma, and Ohio. The second way fracking waste water can be disposed of is in industrial wastewater treatment plants. There have been problems with ineffective treatments at Pennsylvania municipal water treatment plants, so that practice has now ended and only approved industrial treatment plants can be used.