Battery technology: a game-changer for the energy future?

As BP announces its investment in a developer of electric vehicle batteries with the potential to charge in five minutes, BP Magazine looks at the technology today and its potential for the future with eight, AA battery-size, facts.

As BP announces its investment in a developer of electric vehicle batteries with the potential to charge in five minutes, BP Magazine looks at the technology today and its potential for the future with eight, AA battery-size, facts.

1. Emerging technology

Put simply, batteries store energy in chemical form and convert it into electrical energy at the push of a button. Batteries have been around in some form for hundreds of years, from heavy lead acid blocks in vehicles to the small round discs in kitchen weighing scales.

So, why are they considered an emerging technology? Because we're now looking at batteries capable of being recharged thousands of times, lasting for many years and powering a two-tonne vehicle across the length of England – all of which requires capacities 100,000 times greater than the AA cell in your TV remote.

2. Innovative applications

Batteries are being used alongside other emerging technologies in areas such as robotics and renewable energy. Research is underway into how batteries can be used to store energy to balance out the intermittent outputof renewable energy plants. For example, BP has launched its first battery storage project with Tesla at one of its wind farms in the US to look at how the facility's energy can be stored and then used when not being produced.

Batteries are also transforming expectations of what's possible with electric vehicles (EVs). Their use in the area of electric mobility has arisen as the world looks for lower-carbon transport solutions. Customers want fewer emissions, along with improved fuel efficiency. Battery technologies may provide the answers for both.

3. The raw materials

Around 90% of today's rechargeable battery market is based on old lead-acid technology, such as the starter batteries in conventional cars. The other 10% is dominated by lithium-ion batteries, or LiBs for short, which, at the moment, are the leading technology for use in smartphones and electric mobility.

These batteries require more than just lithium, though, with other materials used in the electrodes, including cobalt, nickel and manganese.

4. Storing and releasing energy

Energy and power density are often conflated, but it's important to know the difference. Energy density is the amount of energy stored in a battery. In terms of electric mobility, the total energy that a battery can store relates directly to the range that the vehicle would have, i.e. the distance it could travel before it requires recharging. Therefore, the greater the storage capacity of the battery, the better the range of the car.

Power density is how quickly that battery can release its energy. For example, an electric car travelling at a steady, low speed could consume around 10-15 kilowatts (kW) of power, but, for acceleration, it could require hundreds of kilowatts, albeit for short bursts.

5. Falling costs

Until recently, almost half the cost of an electric vehicle was taken up by building the battery itself. With advances in technology, that cost has dropped in the past three years by about two-thirds to around $200 per kilowatt-hour (kWh). For a top-end car, the battery cost drops from around $45,000 to around $15,000.

This reduction has helped to accelerate the take-up of electric mobility. And costs are expected to fall even more dramatically; BP’s Technology Outlook predicts that buying, running and fuelling electric cars in Europe will become competitive with ICE (internal combustion engine)-driven models before 2050.

6. Capacity versus charging speed

Battery life remains a problem, both for smartphone users with 'phone anxiety' who want power that lasts longer than a day - and for potential electric vehicle owners with ‘range anxiety’ (the fear of running out of energy mid-journey without the means to recharge). Those drivers may want to go farther than 200 miles on a charge but don’t have access to home charging to top-up the battery overnight. They want solutions. 

Charging rates for LiB have remained stubbornly slow because of a trade-off between how much energy a battery holds and how quickly it can be charged. This means, at the moment, a battery is either designed for high capacity (energy density) that will allow the battery to last longer before recharging or, one that’s optimised for a fast charging rate. [For more, see 'the experts' view' below].

7. Finding the right chemistry

Almost all four-wheel battery electric vehicles these days use LiBs. But, battery developers are playing around with the fundamentals of the technology - the cathode and the anode (between which the electric charge moves) and the electrolyte solution (that carries the charge). They are hoping to discover the right combinations that will produce greater power and energy densities and, ultimately, could be a game changer for electric mobility.

8. Fast-charging future

Fast-charging batteries could encourage more car owners to make the switch to an electric vehicle.

Start-up companies, such as BP-partner StoreDot, which is using a new type of electrolyte and nanomaterials in LiBs, could potentially provide car manufacturers with a battery that can be charged in five minutes or less.

This technology, along with accessibility to a nationwide charging network, could speed up the adoption of electric vehicles. (comms.bp.com)