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.

This book chapter advances SDGs 6, 14 and 15 by examining how sustainable materials for environmental remediation are useful tools for helping address goals relating to ecosystem health and pollution control.
Elsevier,

Alfredo de Jesús Martínez-Roldán, Rosa Olivia Cañizares-Villanueva, Chapter 7 - Wastewater treatment based in microalgae, Editor(s): Eduardo Jacob-Lopes, Mariana Manzoni Maroneze, Maria Isabel Queiroz, Leila Queiroz Zepka, Handbook of Microalgae-Based Processes and Products, Academic Press, 2020, Pages 165-184, ISBN 9780128185360, https://doi.org/10.1016/B978-0-12-818536-0.00007-5.

This book chapter advances SDGs 6 and 7 by explaining how to remove contaminants from wastewater using microalgae so that it is safe to release into the natural environment.
The COVID-19 pandemic has had growing environmental consequences related to plastic use and follow-up waste, but more urgent health issues have far overshadowed the potential impacts. This paper gives a prospective outlook on how the disruption caused by COVID-19 can act as a catalyst for short-term and long-term changes in plastic waste management practices throughout the world. The impact of the pandemic and epidemic following through the life cycles of various plastic products, particularly those needed for personal protection and healthcare, is assessed.

High-tech products like batteries and electronics contain a variety of valuable, scarce, and in some cases potentially harmful materials, but in only a few exceptional cases (such as lead-acid batteries) is the material being recovered efficiently. Cotributing to SDGs 7, 9 and 12, this special issue seeks to elucidate the technical and institutional difficulties inherent in recycling these products and provide a forum for sharing potential ways to overcome them. 

Elsevier, Current Research in Green and Sustainable Chemistry, Volume 3, June 2020
Obesity represents an important public health concern because it substantially increases the risk of multiple chronic diseases and thereby contributing to a decline in both quality of life and life expectancy. Besides unhealthy diet, physical inactivity and genetic susceptibility, environmental pollutants also contribute to the rising prevalence of obesity epidemic.
Elsevier, Current Research in Green and Sustainable Chemistry, Volume 3, June 2020
Bio-based aerogels with customizable porosities and functionalities constitute a significant potential for CO2 capture. Developing bio-based aerogels from different polysaccharides and proteins is a safe, economical, and environmentally sustainable approach. Polysaccharides are biodegradable, sustainable, renewable, and plentiful in nature. Because of these advantages, the use of bio-based aerogels with porosity and amine functionality has attracted considerable interest.
Elsevier, Current Research in Green and Sustainable Chemistry, Volume 3, June 2020
The successful conversion of lignocellulose into value-added products depends on overcoming the recalcitrance of its structure towards enzymatic digestion. The highly crosslinked structure of lignin, crystallinity of cellulose, and low digestibility of hemicellulose create the recalcitrance. Many studies have proved that an appropriate pretreatment method could enhance the digestibility of lignocellulosic biomass by weakening the strong network of its chemical bonds among the cellulose, hemicellulose, and lignin.
Beyond their traditional use as green solvents, new applications have become available for ionic liquids (ILs) in drug delivery. Their flexible tunability enables task-specific optimization of ILs at molecular level. Thus, ILs have been exploited to improve the solubility and permeability of drugs and relieve the polymorphic problems associated with crystalline active pharmaceutical ingredients (APIs). Controlled preparation of drug nanocarriers are also achieved by using ILs either as media or as functional agents.
The potential of electron-donating capability in methoxy groups of antioxidant containing protein (ACAP) as organic catalyst is restricted by its low isoelectric point. The goal of this study is to construct endure ACAP based metal-free organic catalyst for hydrogen production from electrolysis of noodle wastewater. The ACAP was coated thermomechanically on PVC sheet and its performance was tested during electrolysis of noodle wastewater. The morphological analysis, phase analysis, and elemental analysis of coated materials have shown a simultaneous pattern with electrolysis performances.
Although deployments of grid-scale stationary lithium ion battery energy storage systems are accelerating, the environmental impacts of this new infrastructure class are not well studied. To date, a small literature of environmental life cycle assessments (LCAs) and related studies has examined associated environmental impacts, but they rely on a variety of methods and system boundaries rather than a consistent approach.

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