Sustainable transport

Sustainable transport plays a crucial role in realizing the Sustainable Development Goals (SDGs), specifically through SDG 9 (Industry, Innovation and Infrastructure), SDG 11 (Sustainable Cities and Communities), SDG 3 (Good Health and Well-being), and SDG 13 (Climate Action). By fostering an inclusive and sustainable transportation system, we can facilitate social and economic development, mitigate environmental damage, and improve the overall quality of life.

In the context of SDG 9, sustainable transport infrastructure fosters economic growth and innovation by enabling the movement of goods and services, promoting regional integration, and enhancing access to markets. It also drives industrial sustainability by fostering energy-efficient modes of transport and facilitating the transition to a low-carbon economy.

Under SDG 11, sustainable transport is key to creating sustainable cities and communities. It enhances urban mobility, reduces congestion, and mitigates air pollution, thereby improving the quality of life in urban areas. Public transportation, cycling, and walking, as components of sustainable transport, also promote social inclusion by ensuring everyone, including the poor, the disabled, and the elderly, can access opportunities and services.

For SDG 3, sustainable transport can improve public health. Reducing the reliance on private vehicles decreases air and noise pollution, mitigating respiratory diseases, and reducing stress levels. Furthermore, encouraging active transport modes, such as walking and cycling, can combat sedentary lifestyles and associated health issues, such as obesity and heart diseases.

In relation to SDG 13, sustainable transport plays a vital role in combating climate change. The transportation sector is one of the major contributors to greenhouse gas emissions, thus, shifting towards sustainable transport, such as electric vehicles or public transport, can significantly reduce carbon emissions and help mitigate the effects of climate change.

Despite its benefits, achieving sustainable transport requires addressing multiple challenges, such as the high upfront costs of sustainable transport infrastructure, the lack of institutional capacity, and resistance from vested interests. Policies and strategies should be implemented to encourage the use of sustainable transport and ensure its affordability and accessibility to all members of society.

The Blueprint for Business Leadership on the SDGs aims to inspire all business — regardless of size, sector or geography — to take leading action in support of the achievement of the Sustainable Development Goals (SDGs). It illustrates how the five leadership qualities of Ambition, Collaboration, Accountability, Consistency, and Intentional can be applied to a business' strategy, business model, products, supply chain, partnerships, and operations to raise the bar and create impact at scale. The Blueprint is a tool for any business that is ready to advance its principled approach to SDG action to become a leader. This chapter relates specifically to SDG 11.

Transportation geotechnics associated with constructing and maintaining properly functioning transportation infrastructure is a very resource intensive activity. Large amounts of materials and natural resources are required, consuming proportionately large amounts of energy and fuel. Thus, the implementation of the principles of sustainability is important to reduce energy consumption, carbon footprint, greenhouse gas emissions, and to increase material reuse/recycling, for example.

The internal combustion engine (ICE) does not efficiently convert chemical energy into mechanical energy. A majority of this energy is dissipated as heat in the exhaust and coolant. Rather than directly improving the efficiency of the engine, efforts are being made to improve the efficiency of the engine indirectly by using a waste heat recovery system. Two promising technologies that were found to be useful for this purpose were thermoelectric generators (TEGs) and heat pipes. Both TEGs and heat pipes are solid state, passive, silent, scalable and durable.
Elsevier,

Sustainable Materials and Technologies, Volume 1, December 01, 2014

This paper looks ahead, beyond the projected large-scale market penetration of vehicles containing advanced batteries, to the time when the spent batteries will be ready for final disposition. It describes a working system for recycling, using lead-acid battery recycling as a model. Recycling of automotive lithium-ion (Li-ion) batteries is more complicated and not yet established because few end-of-life batteries will need recycling for another decade. There is thus the opportunity now to obviate some of the technical, economic, and institutional roadblocks that might arise.

ICIS,

ICIS Special Report, September 2014

Record attempt has solar flair
An idea spawned a decade ago finally becomes a reality as Solar Impulse prepares for the first round-the-world flight by a plane producing zero emissions. Collaboration across several partners has been a key component to developing the materials and design of Solar Impulse. Innovations like this are vital to SDG 7.2 to increase substantially the share of renewable energy in the global energy mix.
Elsevier, Transport Policy, Volume 20, March 2012
The late 1990s and early 2000s witnessed a growing interest amongst UK academics and policy makers in the issue of transport disadvantage and, more innovatively, how this might relate to growing concerns about the social exclusion of low income groups and communities. Studies (predominantly in the United Kingdom) began to make more explicit the links policy between poverty, transport disadvantage, access to key services and economic and social exclusion (see for example Church and Frost, 2000; .

This paper describes the methodology and data used to determine greenhouse gas (GHG) emissions attributable to ten cities or city-regions: Los Angeles County, Denver City and County, Greater Toronto, New York City, Greater London, Geneva Canton, Greater Prague, Barcelona, Cape Town and Bangkok. Equations for determining emissions are developed for contributions from: electricity; heating and industrial fuels; ground transportation fuels; air and marine fuels; industrial processes; and waste.

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