Power supply for electric car charging.  Electric car charging station. Close up of the power supply plugged into an electric car being charged.

Keeping electric car design on the right road

Pushing nanoscale battery developments in the right direction can help create a sustainable transport sector.

Does it really help to drive an electric car if the electricity you use to charge the batteries come from a coal mine in Germany, or if the batteries were manufactured in China using coal?

Researchers at NTNU’s Industrial Ecology Programme have looked at all of the environmental costs of electric vehicles to determine the cradle-to-grave environmental footprint of building and operating these vehicles.

In the 6 December issue of Nature Nanotechnology, the researchers report on a model that can help guide developers as they consider new nanomaterials for batteries or fuel cells.   The goal is to create the most environmentally sustainable vehicle fleet possible, which is no small challenge given that there are already an estimated 1 billion cars and light trucks on the world’s roads, a number that is expected to double by 2035.

With this in mind, the researchers created an environmental life-cycle screening framework that looked at the environmental and other impacts of extraction, refining, synthesis, performance, durability and recycleablility of materials.

An early life-cycle screening of lithium-ion batteries and proton exchange membrane hydrogen fuel cells for electric vehicles. Source: Nature Nanotechnology

An early life-cycle screening of lithium-ion batteries and proton exchange membrane hydrogen fuel cells for electric vehicles. Source: Nature Nanotechnology

This allowed the researchers to evaluate the most promising nanomaterials for lithium-ion batteries (LIB) and proton exchange membrane hydrogen fuel cells (PEMFC) as power sources for electric vehicles.  “Our analysis of the current situation clearly outlines the challenge,” the researchers wrote. “The materials with the best potential environmental profiles during the material extraction and production phase…. often present environmental disadvantages during their use phase… and vice versa.”

The hope is that by identifying all the environmental and other costs of different materials used to build electric cars that designers and engineers can “make the right design trade-offs that optimize LIB and PEMFC nanomaterials for EV usage towards mitigating climate change,” the authors wrote.

They encouraged material scientists and those who conduct life-cycle assessments to work together so that electric cars can be a key contributor to mitigating the effects of transportation on climate change.

Reference: Nanotechnology for environmentally sustainable electromobility
Linda Ager-Wick Ellingsen, Christine Roxanne Hung, Guillaume Majeau-Bettez, Bhawna Singh, Zhongwei Chen, M. Stanley Whittingham, Anders Hammer Strømman. Nature Nanotechnology (2016) 11,1039–1051. doi:10.1038/nnano.2016.237