Anker’s New Battery Can Charge Your Phone, Tesla Model S, Or Phased Plasma Rifle In The 40-watt Range

- Apr 28, 2016-

Battery woes and range anxiety are a fact of life in the modern age. If you own a modern smartphone, chances are you’ve run short of battery power at least occasionally and had to scrabble for an outlet at an inconvenient time. Anker, the manufacturer for a wide range of battery products and chargers, knows your pain and wants to sell you a battery that’s pretty much guaranteed to handle anything up to and including your next backpacking trip across the Sahara, zombie apocalypse, or run-in with a Terminator sent to kill you and your mother.

The upcoming Anker PowerHouse is listed as a 434Wh battery (multiple sites are reporting that its also a 120,600mAh battery, though I’m uncertain where that figure is derived from, as it isn’t listed anywhere in the product literature). It’s compatible with USB, 12V car adapters, and a conventional three-prong cable, and can reportedly charge a phone up to 40x, a laptop up to 15x (only if that laptop has a smallish battery), run a mini-fridge for up to seven hours, or a 15V light for over a hundred hours.

Rechargeable battery technology has been improving incrementally in recent years, but we’re still working with the same heavy, dangerous, expensive materials. A group of researchers from The Netherlands has devised a new biological battery that charges and discharges with the aid of bacteria. They’ve tested this system on the small scale and managed 15 charge cycles in a row.

This “bioelectrochemical” battery consists of two parts. There’s a microbial electrical synthesis (MES) module that takes electrons and uses them to generate acetate. This is a metal salt that can be used to store electrical charge. The other side of the battery is a microbial fuel cell (utilizing various anaerobic bacteria) that processes that acetate via reduction/oxidation, resulting in the release of electrons. These are then fed into a circuit to harvest the power that was stored in the first step. More power can be added to the MES system to recharge, and the whole process starts over again.

The team tested this design by feeding power in over the course of 16 hours. It then provided power over the course of 8 hours. Does that sound like it might mesh well with any particular type of technology? Yep, it’s a great match for solar power, and indeed that’s the application the researchers have in mind. In areas that have lots of sunlight, there’s an almost unlimited supply of power during the day, but you have to store that power for use at night.

bac batteryThe bacterial battery described in the paper might be ideal for storing energy from solar power, but first some improvements need to be made. For one, the efficiency isn’t what we’d expect from a modern lithium-polymer battery. The team reports roughly 30-40% cycle efficiency, compared with upward of 80% in the best batteries we have now. The bacterial batteries would also need a bit more care than a lithium-ion system. If the bacteria inside were to die, the battery would stop working.

Despite these shortcomings, the study authors believe that this is an important first step. The study includes data from 15 charge cycles of the battery, and it maintained very consistent performance throughout. The self-renewing nature of bacterial colonies might mean this approach has better longevity than lithium-ion, which only works for a few hundred cycles.

With additional research, bioelectrochemical batteries may have similar capacity and efficiency compared with conventional ones, but with much lower costs and fewer volatile chemicals. Like so many other proposed battery technologies, this one is a few years off.

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