Special Issue: Energy Transition of Buildings and Urban Activity Systems

Guest Editor: Professor Susan Krumdieck, Heriot-Watt University

Journal of Energy and Power Technology

http://www.lidsen.com/journals/jept

Energy transition must be executable, demonstrate metrics of wellbeing, and exhibit long-term viability (e.g. at least 100 years), while delivering 80% downshift in fossil fuel use and material lifecycle demand (e.g. products and waste). 

Context

Since the OPEC Oil Embargo in 1973, the OECD countries have understood the vulnerabilities of their energy supply to international suppliers. Successive US Presidents have made it a priority to explore and develop domestic oils, gas and renewable energy sources. Electricity generation shifted away from diesel power plants because of the oil shocks. The emergence of the fuel efficiency standards, and limited uptake of hybrid and compact vehicles has only marginally affected the demand for petroleum and diesel fuel. The oil price shock of 2007-2008 and the global economic recession arrested the growth in demand for transport fuels and for electricity in most countries. The biofuel mandates did not do much to cushion the global oil supply or price shock. Green recovery deals gave subsidies for wind and solar electricity generation, and while the growth has been impressive, the emissions every year from fossil fuels have not declined.

 

In 2015 the COP21 Paris Agreement between the partner countries called for reduction of emissions to achieve a 60% chance of keeping global warming below 2 oC by the end of the century. In simple terms, responding to the widely declared climate emergency will require 80% downshift in fossil fuel use across the entire globe by 2040. This is the energy transition.

 

Call for Research Action

Energy Transition requires wide ranging and sweeping changes in urban form, transport and organisation. The challenge is to deliver improved quality of life and access to activities, goods and services while using 80% less fossil fuel and materials. This is an unprecedented undertaking. The past 100 years of technical and economic research has not had the context of constrained energy and material consumption, let alone downshift. This is the time for extreme creativity and unfettered ingenuity, solidly grounded in science and engineering reality.

 

This special issue is a renaissance of resourcefulness and insight. We invite breakthrough thinking with rigorous analysis of specific projects in cities around the world. The special issue has a strict requirement: all of the concept projects in energy transition must be executable, demonstrate metrics of wellbeing, and exhibit long-term viability (e.g. at least 100 years), while delivering 80% downshift in fossil fuel use and material lifecycle demand (e.g. products and waste).

 

This may be the most challenging call for research ever issued. Most researchers may never have set themselves this kind of a challenge. The energy transition challenge requires adopting a change of perspective from modelling “sustainable solutions” to proposing and testing out “fossil fuel downshift transformations”.  Many countries of the world have declared Climate Emergencies. We urge researchers with the analytical tools and knowledge of existing systems to take up the energy transition challenge for cities and buildings.