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.

A climate mitigation comprehensive solution is presented through the first high yield, low energy synthesis of macroscopic length carbon nanotube (“CNT”) wool from CO2 by molten carbonate electrolysis. The CNT wool is of length suitable for weaving into carbon composites and textiles. Growing CO2 concentrations, and the concurrent climate change and species extinction, can be addressed if CO2 becomes a sought resource rather than a greenhouse pollutant.
Elsevier, Sustainable Materials and Technologies, Volume 13, September 2017
Nanoscience is an inspiring and influential discipline of science which have accessible numerous novel and cost-effective yields and applications. Currently, nanotechnology research has been empowering more in agricultural sector, food process and medicinal industries. The surface area to volume ratio of nanoparticles is quite large which have 1–100 nm size. Nanomaterials have superior bioavailability than larger particles, resulting in greater utilization in single cells, tissues and organs.
This book chapter advances SDGs 12 and 15 by explaining how humans have a detrimental impact on natural habitat due to various activities including deforestation, urbanization, roads, the energy sector (renewable and coal), mining, and climate change. The most important form of habitat destruction is deforestation either to develop land for agriculture (70%) or to harvest lumber intensively.
Elsevier,

Sustainable Energy Technologies and Assessments, Volume 22, August 2017

Access to reliable, affordable and sustainable energy is essential for improving living standards, development and economic growth. From a healthcare perspective, energy is a critical parameter for delivering and improving healthcare services and life-saving interventions in the Global South. This review provides an estimation of the energy needs of different healthcare facilities as a function of patient capacity and services provided. It also presents the strengths and limitations of several energy sources that can be used to meet these needs.

Calibrated models can reasonably capture descriptions between input and output variables and can thus be used to estimate long term groundwater levels.
SDG Business Forum
In July the 2017 Sustainable Development Goals (SDG) Business Forum recognised the critical role of business in delivering on the promise of sustainable and inclusive development. In this article, we elaborate on the SDG business case, and how businesses can engage with the SDG framework; driving business growth and productivity, whilst contributing to the better world envisaged by the 2030 Agenda for Sustainable Development.
This chapter advances SDG 6, 11, and 12 by discussing the state-of-the-art of managing water supply and demand as a natural resource, and what indicators are being developed to identify water scarcity worldwide.
Elsevier, Sustainable Materials and Technologies, Volume 12, 1 July 2017
Material and product life cycles are based on complex value chains of technology-specific elements. Resource strategy aspects of essential and strategic raw materials have a direct impact on applications of new functionalized materials or the development of novel products. Thus, an urgent challenge of modern materials science is to obtain information about the supply risk and environmental aspects of resource utilization, especially at an early stage of basic research.
Elsevier,

Encyclopedia of Sustainable Technologies, Volume , 4 July 2017

This book chapter advances SDG 15 and 11 introducing a novel agricultural practice—vertical farming/urban agriculture, highlighting how it can help deliver safe and nutritious food for a growing world population in environmentally and socially sustainable ways.
Elsevier,

Gopalakrishnan, Varsha and Bakshi, Bhavik R., "Including Nature in Engineering Decisions for Sustainability", Editor(s): Martin A. Abraham, Encyclopedia of Sustainable Technologies, Elsevier (2017), Pages 107-116

Through the practice of biomimicry, engineering can both emulate and conserve the natural world. In this chapter, the author notes that our development practices have often "ignored or undervalued" nature, and describes the ways in which we can aim to build systems that are self-sustaining and resilient, much like earth's ecosystems. This chapter advances SDGs 7, 11 and 13.

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