Of Poverty and Plastic applies an interdisciplinary, 'field economics' approach to poverty analysis, using a mix of survey and ethnographic data to challenge received notions of the nature and extent ...of narrow income poverty and multiple deprivations experienced by those working in the informal waste recovery and plastic recycling economy of Delhi. A detailed analysis of specialization, capital, and value in various segments of this labour-intensive, 'green' informal market is undertaken, with explicit recognition of its wider social and political institutional context, and how it is shaped by unequal interactions with civil society and the state. In particular, the book focuses on the identity and agency of subordinate scheduled caste groups-living literally and metaphorically on the edge of the city-in negotiating 'a decent life' in today's neoliberal environment. The case studies of the ban on recycled polythene bags and the industrial relocation order illustrate the channels through which these actors collectively seek to resist the perceived anti-urban poor status quo, driven by powerful middle class coalitions through legislation or judicial fiat, with varying degrees of success. In doing so, the book exposes the complex, and at times contrary, policy reality binding poverty and deprivation, formal and informal markets, the state and citizenship in contemporary urban India.
A review is presented of the manufacture and use of different types of plastic, and the effects of pollution by these materials on animal, human and environmental health, insofar as this is known. ...Since 2004, the world has made as much plastic as it did in the previous half century, and it has been reckoned that the total mass of virgin plastics ever made amounts to 8.3 billion tonnes, mainly derived from natural gas and crude oil, used as chemical feedstocks and fuel sources. Between 1950 and 2015, a total of 6.3 billion tonnes of primary and secondary (recycled) plastic waste was generated, of which around 9% has been recycled, and 12% incinerated, with the remaining 79% either being stored in landfills or having been released directly into the natural environment. In 2015, 407 million tonnes (Mt) of plastic was produced, of which 164 Mt was consumed by packaging (36% of the total). Although quoted values vary, packaging probably accounts for around one third of all plastics used, of which approximately 40% goes to landfill, while 32% escapes the collection system. It has been deduced that around 9 Mt of plastic entered the oceans in 2010, as a result of mismanaged waste, along with up to 0.5 Mt each of microplastics from washing synthetic textiles, and from the abrasion of tyres on road surfaces. However, the amount of plastics actually measured in the oceans represents less than 1% of the (at least) 150 Mt reckoned to have been released into the oceans over time. Plastic accounts for around 10% by mass of municipal waste, but up to 85% of marine debris items – most of which arrive from land-based sources. Geographically, the five heaviest plastic polluters are P.R. China, Indonesia, Philippines, Vietnam and Sri Lanka, which between them contribute 56% of global plastic waste. Larger, primary plastic items can undergo progressive fragmentation to yield a greater number of increasingly smaller 'secondary' microplastic particles, thus increasing the overall surface area of the plastic material, which enhances its ability to absorb, and concentrate, persistent organic pollutants (POPs) such as dichlorodiphenyltrichloroethane (DDT) and polychlorinated biphenyls (PCBs), with the potential to transfer them to the tissues of animals that ingest the microplastic particles, particularly in marine environments.
Although fears that such microparticles and their toxins may be passed via food webs to humans are not as yet substantiated, the direct ingestion of microplastics by humans via drinking water is a distinct possibility – since 92% of samples taken in the USA and 72% in Europe showed their presence – although any consequent health effects are as yet unclear. Foodstuffs may also become contaminated by microplastics from the air, although any consequent health effects are also unknown. In regard to such airborne sources, it is noteworthy that small plastic particles have been found in human lung tissue, which might prove an adverse health issue under given circumstances. It is also very striking that microplastics have been detected in mountain soils in Switzerland, which are most likely windborne in origin. Arctic ice core samples too have revealed the presence of microplastics, which were most likely carried on ocean currents from the Pacific garbage patch, and from local pollution from shipping and fishing. Thus, sea ice traps large amounts of microplastics and transports them across the Arctic Ocean, but these particles will be released into the global environment when the ice melts, particularly under the influence of a rising mean global temperature.
While there is a growing emphasis toward the substitution of petrochemically derived plastics by bioplastics, controversy has arisen in regard to how biodegradable the latter actually are in the open environment, and they presently only account for 0.5% of the total mass of plastics manufactured globally. Since the majority of bioplastics are made from sugar and starch materials, to expand their use significantly raises the prospect of competition between growing crops to supply food or plastics, similarly to the diversion of food crops for the manufacture of primary biofuels. The use of oxo-plastics, which contain additives that assist the material to degrade, is also a matter of concern, since it is claimed that they merely fragment and add to the environmental burden of microplastics; hence, the European Union has moved to restrict their use.
Since 6% of the current global oil (including natural gas liquids, NGLs) production is used to manufacture plastic commodities – predicted to rise to 20% by 2050 – the current approaches for the manufacture and use of plastics (including their end-use) demand immediate revision. More extensive collection and recycling of plastic items at the end of their life, for re-use in new production, to offset the use of virgin plastic, is a critical aspect both for reducing the amount of plastic waste entering the environment, and in improving the efficiency of fossil resource use. This is central to the ideology underpinning the circular economy, which has common elements with permaculture, the latter being a regenerative design system based on 'nature as teacher', which could help optimise the use of resources in town and city environments, while minimising and repurposing 'waste'. Thus, food might be produced more on the local than the global scale, with smaller inputs of fuels (including transportation fuels for importing and distributing food), water and fertilisers, and with a marked reduction in the use of plastic packaging. Such an approach, adopted by billions of individuals, could prove of immense significance in ensuring future food security, and in reducing waste and pollution – of all kinds.
It's falling from the sky and in the air we breathe. It's in our food, our clothes, and our homes. It's microplastic and it's everywhere-including our own bodies. Scientists are just beginning to ...discover how these tiny particles threaten health, but the studies are alarming. In A Poison Like No Other, Matt Simon reveals a whole new dimension to the plastic crisis, one even more disturbing than plastic bottles washing up on shores and grocery bags dumped in landfills. Dealing with discarded plastic is bad enough, but when it starts to break down, the real trouble begins. The very thing that makes plastic so useful and ubiquitous - its toughness - means it never really goes away. It just gets smaller and smaller: eventually small enough to enter your lungs or be absorbed by crops or penetrate a fish's muscle tissue before it becomes dinner. Unlike other pollutants that are single elements or simple chemical compounds, microplastics represent a cocktail of toxicity: plastics contain at least 10,000 different chemicals. Those chemicals are linked to diseases from diabetes to hormone disruption to cancers. A Poison Like No Other is the first book to fully explore this public health threat, following the intrepid scientists who travel to the ends of the earth and the bottom of the ocean to understand the consequences of our dependence on plastic. As Simon learns from these researchers, there is no easy fix. But we will never curb our plastic addiction until we begin to recognize the invisible particles all around us.
Much of what you've heard about plastic pollution may be wrong. Instead of a great island of trash, the infamous Great Pacific Garbage Patch is made up of manmade debris spread over hundreds of miles ...of sea-more like a soup than a floating garbage dump. Recycling is more complicated than we were taught: less than nine percent of the plastic we create is reused, and the majority ends up in the ocean. And plastic pollution isn't confined to the open ocean: it's in much of the air we breathe and the food we eat. In Thicker Than Water: The Quest for Solutions to the Plastic Crisis, journalist Erica Cirino brings readers on a globe-hopping journey to meet the scientists and activists telling the real story of the plastic crisis. From the deck of a plastic-hunting sailboat with a disabled engine, to the labs doing cutting-edge research on microplastics and the chemicals we ingest, Cirino paints a full picture of how plastic pollution is threatening wildlife and human health. Thicker Than Water reveals that the plastic crisis is also a tale of environmental injustice, as poorer nations take in a larger share of the world's trash, and manufacturing chemicals threaten predominantly Black and low-income communities. There is some hope on the horizon, with new laws banning single-use items and technological innovations to replace plastic in our lives. But Cirino shows that we can only fix the problem if we face its full scope and begin to repair our throwaway culture. Thicker Than Water is an eloquent call to reexamine the systems churning out waves of plastic waste.
Beautyscapes Holliday, Ruth; Jones, Meredith; Bell, David
2019, 2019-07-04
eBook
Beautyscapes explores the global phenomenon of international medical travel, focusing on patient-consumers seeking cosmetic surgery outside their home country and on those who enable them to access ...treatment abroad, including surgeons and facilitators. It documents the journeys of those who travel for treatment abroad, as well as the nature and power relations of the IMT industry. Empirically rich and theoretically sophisticated, Beautyscapes draws on key themes of interest to students and researchers interested in globalisation and mobility to explain the nature and growing popularity of cosmetic surgery tourism. Richly illustrated with ethnographic material and with the voices of those directly involved in cosmetic surgery tourism, Beautyscapes explores cosmetic surgery journeys from Australia and China to East-Asia and from the UK to Europe and North Africa.
Single-use plastics, or SUPs (plastic bags, microbeads, cutlery, straws and polystyrene) are substantial sources of plastic marine pollution, yet preventable via legislative and non-legislative ...interventions. Various international legislative strategies have been reported to address plastic marine pollution from plastic bags and microbeads, but these have since been accompanied by recent increasing public awareness triggered by international agencies and organizations. The Sixth International Marine Debris Conference highlighted increasing intervention strategies to mitigate SUP pollution. This study presents new multi-jurisdictional legislative interventions to reduce SUPs since 2017 and incorporates emergence of new non-legislative interventions to mitigate other types of SUPs at individual and private-sector levels that complement or influence legislative interventions. Further, effectiveness of SUP bag interventions (e.g., bans vs. levies) to help reduce SUP marine pollution are presented and range between 33 and 96% reduction in bag use.
Display omitted
•Single use plastics (SUPs) contribute to 60-95% of global marine plastic pollution•Legislative (top-down) action to reduce SUPs is gaining momentum worldwide•Non-legislative (bottom-up) actions are also proliferating•Both legislative and non-legislative actions are effective and complimentary•Effectiveness of SUP bag reduction interventions vary depending on policy, ranging from 33–96%
Shows why plastics, in aggregate, have become a toxin to humans, wildlife, and the planet, and proposes novel solutions that involve neither traditional recycling nor giving up plastic.- Provides a ...realistic solution for our use of plastic: not to eliminate it, but to innovate it- Views plastic not only as a known environmental and health hazard but as a material critical to our future and therefore worth revising for future use- Explains what we must do-and by when-in order to be able to keep using plastic without harming the planet or our health- Shows the links between the environmental, toxicological, and socioeconomic challenges in our use of plastic, and how these dangers can be remedied by supply chain innovation- Introduces two significant disruptive innovations that if implemented, will save us from the growing problem posed by synthetics