Sustainable consumption and production

Sustainable consumption and production (SCP) is at the core of the United Nations Sustainable Development Goals (SDGs), specifically addressed by SDG 12. This goal aims to "ensure sustainable consumption and production patterns," acting as a cross-cutting theme that feeds into other SDGs such as those related to climate change, poverty, health, and sustainable cities.

SCP involves using services and products in a way that minimizes environmental damage, preserves natural resources, and promotes social equity. The purpose is to decouple economic growth from environmental degradation, which means pursuing economic development in a way that can be sustained by the planet over the long term. SCP requires changes at all levels of society, from individuals to businesses to governments.

At the individual level, SCP implies making lifestyle choices that reduce environmental impact. This might include reducing, reusing, and recycling waste, choosing products with less packaging, and opting for more sustainable forms of transport like cycling or public transport.

For businesses, SCP entails adopting sustainable business models and practices. This could include improving resource efficiency, investing in renewable energy, designing products that are durable and recyclable, and ensuring fair labor practices.

At the government level, SCP involves implementing policies that support sustainable business practices and incentivize sustainable consumer behavior. This might involve regulations to reduce pollution, subsidies for renewable energy, and campaigns to raise awareness about sustainable consumption.

SCP also plays a role in several other SDGs. For example, sustainable production practices can help mitigate climate change (SDG 13) by reducing greenhouse gas emissions. Additionally, by reducing the pressure on natural resources, SCP supports the goals related to life below water (SDG 14) and life on land (SDG 15).

While progress has been made in certain areas, challenges remain in achieving the shift towards SCP. These include existing patterns of overconsumption, limited awareness about the impacts of consumption, and the need for technological innovation to enable more sustainable production.

Elsevier, Current Opinion in Environmental Sustainability, Volume 34, October 2018
Actions on climate change (SDG 13), including in the food system, are crucial. SDG 13 needs to align with the Paris Agreement, given that UNFCCC negotiations set the framework for climate change actions. Food system actions can have synergies and trade-offs, as illustrated by the case for nitrogen fertiliser. SDG 13 actions that reduce emissions can have positive impacts on other SDGs (e.g. 3, 6, 12, 14, 15); but such actions should not undermine the adaptation goals of SDG 13 and SDGs 1, 2, 5 and 10.
Activities in the food-energy-water nexus require ecosystem services to maintain productivity and prevent ecological degradation. This work applies techno-ecological synergy concepts in an optimization formulation to design a system for co-producing food and energy under constraints on ecological sustainability. The system includes land use activities and biomass conversion processes for the production of energy carriers, as well as supporting ecosystems that increase the supply of key ecosystem services.
Elsevier, Resources, Conservation and Recycling, Volume 137, October 2018
A policy and research agenda has emerged in recent years to understand the interconnected risks natural resource systems face and drive. The so-called ‘Food-Energy-Water’ (FEW) nexus has served as a focal point for the conceptual, theoretical and empirical development of this agenda. This special issue provides an opportunity to reflect on whether natural resource use, as viewed through the FEW-nexus lens, provides a useful basis for guiding integrated environmental management.
Elsevier,

Current Opinion in Green and Sustainable Chemistry, Volume 13, October 2018

A brief review of Chilean policies on sustainability along with the academic efforts related to green chemistry, in order with this new scenario are discussed. Topics considered are extraction processes, new solvents, CO2 transformation and emerging photovoltaics materials.

Dealing with current and future global challenges, corporate social responsibility has become a key element for sustainable and responsible companies. Roquette, a family-owned group, leader in plant-based ingredients for Food, Nutrition and Health markets, has implemented a sustainable development approach applicable to all its worldwide activities. This “sustainable journey” is based on 4 pillars: sourcing, innovating, biorefining and acting.

Bruce H. Lipshutz is currently a professor of chemistry at the University of California, Santa Barbara. His research program has, for decades, focused mainly on the development of new reagents and methodologies that are especially general and useful for the synthetic community. Of late, his group pays special attention to synthetic chemistry that is environmentally responsible.
The authors work at the Green Chemistry Centre of Excellence (GCCE) at the University of York and are all currently involved in the H2020-BBI-funded project ReSolve for the development of safer bio-based solvents. Solvent applications for dihydrolevoglucosenone (Cyrene) and 2,2,5,5-tetramethyloxloane (TMO) are among their prominent discoveries. Dr. James Sherwood leads the Alternative Solvents Technology Platform at the GCCE. His research interests include solvent effects in organic synthesis and the substitution of hazardous solvents with novel bio-based solvents. Dr.
In 2007, John Warner and Jim Babcock founded the Warner Babcock Institute for Green Chemistry and, with Amy Cannon, founded the green chemistry education nonprofit organization Beyond Benign. John is the recipient of the 2004 Presidential Award for Excellence in Science Mentoring and the 2014 Perkin Medal. In addition, John is one of the founders of the field of green chemistry and is co-author of the defining textbook Green Chemistry: Theory and Practice.
Elsevier, Sustainable Materials and Technologies, Volume 17, September 2018
An ability to separate battery electrode materials while preserving functional integrity is essential to close the loop of material use in lithium-ion batteries. However, a low-energy and low-cost separation system that selectively recovers electrode materials has not yet been established. In this study, froth flotation experiments were carried out with a variety of new and spent lithium-ion batteries using kerosene as the collector. The products were characterized using thermogravimetric and chemical analysis.
Waste Li foils in the spent experimental Li-coin-cells may bring the potential risk and the waste of Li-resource if they aren't reasonably treated in time. For this purpose, waste Li foils were recycled in the form of black LiFePO4/C powders with the recovery of about 80% in this work.

Pages