We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Risks Associated with the Presence of PVC in the Environment and Methods of Its Elimination
Summary
This review summarized the environmental risks posed by polyvinyl chloride (PVC) plastics, including the release of toxic additives and microplastic formation during degradation, and assessed current methods for its elimination from the environment.
Plastics have recently become an indispensable part of everyone's daily life due to their versatility, durability, light weight and low production costs. The increasing production and use of plastics poses a great danger due to the very long period of degradation, but also the negative impact on living organisms. Decomposing plastics lead to the formation of microplastics, which accumulate in the environment and living organisms becoming part of the food chain. Polyvinyl chloride (PVC) contamination of soil and water seriously threatens ecosystems around the world. The durability and low weight make microplastic particles easily transported with water or air and end up in the soil. Thus, the problem of microplastic pollution affects the entire ecosystem. Since microplastics are commonly found in both drinking and bottled water, humans are also exposed to the harmful effects of microplastics. Because of the existing risks associated with PVC microplastic contamination of the ecosystem, intensive research is underway to develop methods to clean and eliminate it from the environment. Pollution of the environment with plastic, especially microplastic, results in the reduction of both water and soil resources used for agricultural and utility purposes. This review provides an overview of PVC's environmental impact and disposal options.
Sign in to start a discussion.
More Papers Like This
Risks Associated with the Presence of Polyvinyl Chloride in the Environment and Methods for Its Disposal and Utilization
This review examines the environmental and health risks of polyvinyl chloride (PVC), one of the most common plastics. As PVC breaks down into microplastics, it contaminates soil, water, and even drinking water, entering the food chain and exposing humans to harmful effects. The paper surveys methods being developed to clean up and remove PVC microplastics from the environment.
Recent Studies and Technologies in the Separation of Polyvinyl Chloride for Resources Recycling: A Systematic Review
This systematic review summarizes research on technologies for separating polyvinyl chloride (PVC) from other plastics for recycling. Better PVC recycling is important for reducing microplastic pollution because PVC is one of the most common and problematic plastics, and when it breaks down it can release harmful chemical additives into the environment and our bodies.
Polyvinyl chloride (PVC), its additives, microplastic and human health: Unresolved and emerging issues
This paper examines PVC (polyvinyl chloride), one of the most commonly used plastics in Europe, and highlights that it fragments into microplastics more easily than other plastics and requires large amounts of potentially toxic chemical additives. The European Commission has recognized PVC's wide-ranging health and environmental problems, and the authors argue that human exposure to PVC microplastics and their chemical additives remains a serious unresolved public health concern.
Impacts of plastic products used in daily life on the environment and human health: What is known?
Researchers reviewed toxicity data for the most common plastics used in everyday products, finding that polyvinyl chloride (PVC) is the most hazardous due to its monomer and additive chemistry, that additives are generally more toxic than the plastic monomers themselves, and that benzene, phthalates, and lead stabilizers pose the greatest risks to wildlife and humans.
Generation of micro(nano)plastics and migration of plastic additives from Poly(vinyl chloride) in water under radiation-free ambient conditions
Researchers demonstrated that PVC plastic releases micro- and nano-sized particles and chemical additives into water even under radiation-free ambient conditions, with degradation driven by autocatalyzed oxidative processes that produce surface erosion and particle detachment.