Nanotechnology in Air Pollution Treatment

Air Pollution

Air pollution is the introduction of contaminant to the natural environment causing negative effects on human, animal and ecosystem. Volcano ashes, forest fire, motor vehicles, and industrial facilities are the main sources of air pollutions. Carbon monoxide, sulfur dioxide, nitrogen dioxide and ozone are the main pollutants of major public concern – carbon monoxide from the combustion of fuel irritates lungs and leads to respiratory problem; sulfur dioxide emitted from industrial factories is the main element casuing acid rain; whilst methane of volatile organic compounds resulting from argricultural activities is an very efficient greenhouse gas leading to enhanced global warming.

Air Pollution as a Global Issue

According to World Health Organization, an estimated of seven million people died because of air pollution in 2012 (Khullar, 2014); whilst scientists found that toxic pollutants have shown to have tremendous impact on argriculture leading to a 50% drop in crop yields in India comparing to 1980 due to serious air pollution (Ghorayshi, 2014). To tackle this global issue, various nations have enforced education encouraging the conservation of energy and introduced laws restricting the emssions of toxic pollutants and greenhouse gas. However, measures adopted have shown to have little impact – In Beijing, air pollution has become a crisis impeding photosynthesis and potentially affect food supply and leads to nuclear winter for argriculture despite of the tremendous efforts made by the governemnt in addressing the issue (Kaiman, 2014).

Nanotechnology as an Effective Measure?

Nanoparticles are particles at 1-100 nanometers in length and their small size enables enormous possibilities for the future of science. The application of nanotechnology has extended to the territory of environment conservation through reducing air pollution, improving water purification, exploring renewal energy and introducing green construction. The following part shall examines background of the debute of green nanotechnology, context impact, and its adoption to tackle air pollution.

Emerging Innovation Management Practices

There has been an controversial relationship between environmental protection and economic growth – the story of China can be seen as a typical example. China has surpassed the US and became the world’s biggest economy by reaching US$17.6 trillion GDP in terms of purchasing power parity in 2014 (Guan, 2014), however, the big power’s rapid industrialization has come at the expenses of its environment and citizens’ health. China’s energy consumption has jumped 130% from 2000 to 2010, turning it to be the world’s largest source of carbon emissions with the concentration of hazardous particles forty times higher than the safe-level determined by the World Health Organinzation (Xu, 2014).

A World Bank study in 2007 estimated that pollution has caused 5.8% of China’s GDP for health care, premature death and material damages; and air pollution has led to the death of 700,000 people per year; a MIT study even revealed that air pollution alone has cost the country US$112 billion for the labor loss and health care expenses (Pei, 2013). Environmental degradation, shorter life expectancy and public pressure over air pollution have led to an urgent needs for China to look for solution for sustainable economic and environmental growth.

Effects of Technological Uses

Nanotechnology is considered to be an effective measure in tackling air pollution from the detection, prevention and reduction of problem.

Nanotechnology enables the development of a more sensitive and cost-effective sensor detecting pollutants at the molecular level to enhance the sustainability of environment and protect human health.

Pollution prevention means the reduction of pollutants at the source, and it can be achieved by the adoption of nanotechnology using less energy during manufacturing and avoiding the release of contaminants.

To reduce air pollution by employing nanotechnology, catalyst and membranes are the two ways doing it – toxic gases can be transferred to be harmless gases.

Context Impact and the Opportunity Presented by Globalization)

Despite of the benefits offered by nanotechnology, potential risk cannot be ignored, as some material in nanoscale can be toxic and harmful to human health – e.g. airborne nanoparticles inhaled will lead to lung disease (Ian et al., 2012) and worsen condition such as asthma and cancer. Thus, international stakeholders have been working together to explore the environmental applications and impact of nanotechnology. International Organization for Standardization (ISO) and the Organization for Economic Cooperation and Development (OECD) are the international organizations engaging in issues related to this disruptive technology.

The Environmental Protection Agency of the United States has been demonstrating to be an active role in evaluating the potential impacts of nanoscale materials on human health as well as the environment. The Agency is also actively pursuing a comprehensive regulatory approach under Toxic Substances Control Act including “Premanufacture notifications for new nanomaterials” and “an information gathering rule on new and existing nanomaterials” (Environmental Protection Agency 2015).

ISO has set up a technical committee to set international standards for terminology and metrology including “the specification for reference materials, test methodologies, modeling and simulation, and science-based health, safety and environmental practices” (Environmental Protection Agency 2015).

OECD endeavors to understand the properties and potential risks of nanomaterials by “testing and assessment, risk assessment and regulatory programmes, exposure assessment and mitigation, cooperation on the environmentally sustainable use of nanotechnology” (Environmental Protection Agency 2015).

How do they do it?

Detection:

An effective monitoring systems to rapidly detect and identify the source of pollution can help regulatory authorities to efficiently carry out measures to prevent further deterioration. Nanotechnology enables the detection of pollutants in a more effective and efficient way – Nanocontact sensor was introduced to detect metal ions without the need of pre-concentration, e.g. Polymer nanospheres were developed to measure organic contaminants in concentration as low as parts per billion concentration (Ian et al., 2012).

Prevention:

As air pollution has already been developed to be a global crisis and we do not have an effective way to significantly reduce the impact yet, the prevention of toxic gases emission serves as an important role to prevent further deterioration of atmospheric pollution.

Nanotechnology applied in our everyday life has reduced carbon emission – A National Nanotechnology Initiative study found that the United States has saved up an estimate of US$100 billion annually by the employment of nanotechnology-based home lighting, reduced 10% of total energy consumption and cut down 200-million tons of carbon emissions per year (Mehndiratta et al., 2012).

Mining causes air pollution by emitting particulate matter such as methane leading to global warming and sulfur dioxide causing acid rain. Mining activity can be reduced if we consume less fossil fuel. Nanostructural grapheme paper was introduced in 2011 and it is believed that it will be replacing metal material and bringing revolution to the electrical and automotive industries in the future because of it characteristics – “Compared to steel, the prepared GP is six times lighter, five to six times lower density, two times harder with 10 times higher tensile strength and 13 times higher bending rigidity” (Aloisio, 2011). The use of lighter weight nano-composite materials can significantly reduce weight of motor vehicles and airplanes, and it will result in less energy consumption – According to The Mitre Corp., the use of nanomaterials in airframes would reduce the weight of aircraft by 14.05% and lead to 9.8% reduction in fuel consumption (Nanowerk, 2010).

Nanotechnology has also contributed to the reduction in the use of toxic substances during production process. The development and application of microemulsions containing nano-sized compounds extracting specific molecules at the nanoscale level can be used as a substitute to volatile organic compounds which is commonly used in the cleaning industry but constantly blamed for its release of toxic pollutants (Ian el at., 2012).

Reduction:

Catalysts are used to transform vapors generating from vehicles and industrial activities into harmless gasses. Catalysts made from nanoparticles perform better than those made of larger particles as the precedence has a larger surface area allowing more chemicals to interact for a more effective result. Catalysts in use include a nanofibre catalyst made of manganese oxide removing volatile organic compounds emitting from industrial facilities (Zhao, 2009), gold nanoparticles embedded in a porous manganese oxide breaking down volatile organic compounds in the air under room temperature, and nanocatalyst containing cobalt and platinum removing nitrogen oxide from smokestacks (Boysen, n.d. a).

Nanostructure membranes such as carbon nanotubes are being explored and developed to separate carbon dioxide from exhaust streams of industrial plants, and trap greenhouse gas emissions caused by coal mining and power generation (Boysen, n.d. b). As carbon nanotubes can effectively trap gases at hundred times faster than the traditional membranes, it can be used in large-scale industrial plants and power stations (Zhao, 2009).

Adoption

Scientists have been working hard on the research and development of nanotechnology, and its been adopted in some of the areas such as gas leak detectors and ventilation control in factories, and nano-catalysts used on cars to transform harmful vapors into harmless gases.

Other than the above-mentioned adoption, nanotechnology has been applied in other occasions – Sheffield University has invented nanotech denim jeans to break down air borne pollutants with the power of a photocatalyst; and nanotech poster was also developed to absorb toxic compounds from cars and a 10m by 20m poster coated with microscopic and nanoparticles of titanium dioxide at an additional GBP100 to the cost of each poster (Westcott, 2014). The technology is still under development and it is believed that it will be applied on a wider range of products in the near future to help tackling with pollution issue.

Conclusion

Despite the various benefits brought to us by the adoption of nanotechnology, the potential risk and negative effects of it should not be neglected – chemicals in nano-size can be harmful to human health causing diseases such as asthma and cancer; nanoparticle pollution is also an emerging hot topic for investigation nowadays; also, the production of nanomaterials such as nanocatalyst and nanomembranes requires large amount of energy input nullifying its effects in reducing CO2 gas emission and preventing global warming if fossil fuels are used as energy input (Nanowerk, 2010). To save the planet with nanotechnology, we still have a prolonged way of studies and scientific researches ahead. As a member of this beautiful world, each of us can still contribute by reduce, reuse and recycle.

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