Chemicals and waste

The management of chemicals and waste is a crucial aspect of achieving the Sustainable Development Goals (SDGs), a collection of 17 interlinked global goals designed to be a "blueprint to achieve a better and more sustainable future for all" by 2030. These goals were set up in 2015 by the United Nations General Assembly and are intended to be achieved by the year 2030. They address global challenges, including those related to poverty, inequality, climate change, environmental degradation, peace, and justice.

SDG 12, which focuses on Responsible Consumption and Production, is directly related to the management of chemicals and waste. This goal aims to ensure sustainable consumption and production patterns, which includes the environmentally sound management of chemicals and waste. The mismanagement of these elements can have severe environmental and health impacts, thus undermining the objectives of SDG 12.

One of the critical links between chemical and waste management and the SDGs is to human health, as outlined in SDG 3, which aims to ensure healthy lives and promote well-being for all at all ages. Improper handling and disposal of chemicals and waste can lead to pollution and contamination, which can have direct adverse effects on human health. This includes increased risks of diseases, long-term health conditions, and impacts on the well-being of communities, especially those living in close proximity to waste disposal sites or industrial areas.

The impact of waste management also extends to climate change, addressed in SDG 13. Excessive waste generation, particularly organic waste in landfills, contributes to the production of greenhouse gases like methane, a potent contributor to global warming. Additionally, the production and disposal of plastics, electronic waste, and other non-biodegradable materials contribute significantly to carbon emissions. Effective management and reduction of waste are essential to mitigate climate change impacts.

The preservation of life below water (SDG 14) and life on land (SDG 15) is also heavily influenced by how chemicals and waste are managed. Pollution from chemicals and waste can severely impact aquatic ecosystems, harming marine life and biodiversity. Similarly, terrestrial ecosystems and wildlife are at risk from land pollution and habitat destruction caused by improper waste disposal and chemical spills.

Furthermore, SDG 8, which focuses on promoting sustained, inclusive, and sustainable economic growth, full and productive employment, and decent work for all, is impacted by the management of chemicals and waste. Workers in industries dealing with chemicals and waste are often exposed to hazardous conditions. Ensuring their safety and health is a key aspect of achieving this goal. Moreover, sustainable waste management can create new job opportunities and contribute to economic growth through recycling and waste-to-energy sectors.

The effective and environmentally sound management of chemicals and waste is not only essential for achieving SDG 12 but also intersects with several other SDGs. It is a fundamental component of sustainable development, impacting human health, climate change, biodiversity, and economic growth. Addressing these challenges requires a holistic approach, encompassing strict regulatory frameworks, technological innovation, public awareness, and international cooperation to ensure a sustainable future.

Elsevier, TrAC - Trends in Analytical Chemistry, Volume 111, February 2019
Following a decade of research on the environmental impacts of microplastics, a knowledge gap remains on the processes by which micro and nanoplastics pass across biological barriers, enter cells and are subject to biological mechanisms. Here we summarize available literature on the accumulation of microplastics and their associated contaminants in a variety of organisms including humans. Most data on the accumulation of microplastics in both field and lab studies are for marine invertebrates.
Microplastics (MP) (
Interest about interactions between microplastics and organisms is on the rise. Accessing organisms’ responses to these chemically “inert” compounds plays an important role in determining their potential toxicity. Microplastics from the environment tend to accumulate and move through living organisms, inducing a variety of biological effects, such as disturbances in energy metabolism, oxidative balance, antioxidative capacity, DNA, immunological, neurological and histological damage.
In the last decades, energy scarcity has become an important issue globally. Renewable energy sources have gained importance due to limited fossil fuel reserves and increased concerns on climate change. In this regard, municipal wastewater is a remarkable energy source since huge amounts of wastewater are generated and treated all over the world every day. Conventional activated sludge (CAS) process, which has been in use for more than a century, is the most widely applied treatment method for municipal wastewater.
Elsevier, TrAC - Trends in Analytical Chemistry, Volume 110, January 2019
The current paper critically reviews the state-of-the-science on (1) microplastics (MP) types and particle concentrations in freshwater ecosystems, (2) MP and nanoplastics (NP) uptake and tissue translocation, (3) MP/NP-induced effects in freshwater organisms, and (4) capabilities of MP/NP to modulate the toxicity of environmental chemicals. The reviewed literature as well as new data on MP and NP concentrations in the river Elbe and on particle uptake into human cells indicate an environmental relevance of small particles in the low nano- and micrometer range higher than that of larger MP.
Elsevier,

Encyclopedia of Ocean Sciences, Volume , 1 January 2019

The pollution of the marine environment by solid wastes, either directly introduced into the sea or discharged into the oceans from rivers or pipelines, is considered from the perspective of both their impacts and their regulation. The waste materials covered include dredged material, particulate wastes from sand/gravel extraction, and land reclamation, and industrial wastes including mining wastes, munitions, and plastics/litter.

Elsevier,

Plastics to Energy: Fuel, Chemicals, and Sustainability Implications, 2019, Pages 21-44

This book chapter addresses goals 7, 11 and 12 by introduces the main technologies available for recovery of chemicals and fuels from plastic waste, enabling cities and communities to become more sustainable and responsible by transforming this waste into a source of affordable energy.
This book chapter addresses goals 6, 9, and 12 and 14 by presenting the feasibility of traditional and nature-based in situ treatment processes for beverage effluents addressing the environmental problems associated with its management and providing the relevant socioeconomic and environmental values.
Elsevier,

Radioactivity in the Environment (Second Edition), 2019, Pages 635-656

This book chapter addresses goal 3 by discussing the decontamination measures needed after radiation exposure and the protection of first responders and the general public.
Elsevier,

TrAC - Trends in Analytical Chemistry, Volume 109, December 2018

Explore in-depth analysis on microplastic pollution in soil, its ecological risks, and innovative analytical methods for managing this emerging challenge.

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