http://reviews.cnet.com/8301-13746_...imes-energy-of-lithium-researchers/?ttag=fbwpNon-biological objects aren't particularly good at extracting energy from sugar (unless you burn it, something we're attempting to reduce with electric vehicles...) so the researchers are using tailor-made enzymes to break down glucose and turn it into electricity.
These 13 different enzymes are combined with air and maltodextrin glucose in the battery. The only products are water and electricity.
The battery's stability over multiple charge and discharge cycles isn't known, though chief researcher on the project Y.H. Percival Zhang says it's as near as three years from commercialization.
The other unknown is whether such a battery would be scalable for use in electric vehicles. For the time being, the project seems to be focusing on batteries for smartphones and similar, or smaller-scale electronics for use in advanced medicine.
...mass commercialization of a sugar-based battery could lead to high prices and rising food costs...
They already are, but storing the energy a different way:zoobyshoe said:I suppose that it would be due to crops now grown as food being shunted to fuel sugar batteries.
http://en.wikipedia.org/wiki/Ethanol_fuel_in_BrazilBrazil’s 37-year-old ethanol fuel program is based on the most efficient agricultural technology for sugarcane cultivation in the world...
If you read the section called "2009–2013 crisis" it actually says the opposite, that sugar grown for methanol is being shunted to food use. And that is only due to a freak confluence of things that upset the system they had going. The cane intended for ethanol was planted quite apart from food considerations and didn't 'borrow' from it.AlephZero said:They already are, but storing the energy a different way:
http://en.wikipedia.org/wiki/Ethanol_fuel_in_Brazil
Supply and demand.zoobyshoe said:The article I posted seems to assume sugar batteries would, necessarily, have to impinge on the cane grown for food.
Wouldn't is follow, though, that more farmers would switch to sugar, thereby bringing the price down again?jesse73 said:Supply and demand.
If sugar batteries take off the demand will take off and at some point it will be more valuable to grow sugar to sell for batteries rather than food. Farmers grow sugar for the sake of profit.
zoobyshoe said:Wouldn't is follow, though, that more farmers would switch to sugar, thereby bringing the price down again?
No, I think all the people who used to manufacture batteries will welcome their new jobs as cane farmers. hehe.jesse73 said:And increasing the price by decreasing the supply of whatever they used to farm before switching.
I'm still baffled that people are growing corn for ethanol. It seems it's been determined many times over it's not a particularly good source for sugar, esp. compared to sugar cane. I guess it's a case of general lunacy, much like the defense budget. On the one hand there's this:jesse73 said:http://www.ase.tufts.edu/gdae/policy_research/EthanolCostMexico.html
relevant case
zoobyshoe said:If you read the section called "2009–2013 crisis" it actually says the opposite, that sugar grown for methanol is being shunted to food use. And that is only due to a freak confluence of things that upset the system they had going. The cane intended for ethanol was planted quite apart from food considerations and didn't 'borrow' from it.
The article I posted seems to assume sugar batteries would, necessarily, have to impinge on the cane grown for food. I don't see why that would have to be the case. And the sugar batteries sound really good. 10x better than lithium batteries, and their only bi-product, water.
^Enigman said:Process
Similar to how human bodies convert food to energy using enzymes, bio-batteries use enzymes to convert glucose into energy.[1] When glucose first enters the battery, it enters through the anode. In the anode the sugar is broken down, producing both electrons and protons.
Glucose → Gluconolactone + 2H+ + 2e−
These electrons and protons produced now play an important role in creating energy. They travel through the electrolyte, where the separator redirects electrons to go through the mediator to get to the cathode. On the other hand, protons are redirected to go through the separator to get to the cathode side of the battery.
The cathode then consists of an oxidation reduction reaction. This reaction uses the protons and electrons, with the addition of oxygen gas, to produce water.
O2 +4H+ + 4e− → 2H2O
There is a flow created from the anode to the cathode which is what generates the electricity in the bio-battery. The flow of electrons and protons in the system are what create this generation of electricity
http://en.wikipedia.org/wiki/Biobattery#Process
the research paper http://www.researchgate.net/publication/24420470_Bio-batteries_and_bio-fuel_cells_leveraging_on_electronic_charge_transfer_proteins/file/32bfe50e458665b76e.pdf
Only bi-product seems to be Gluconolactone
jesse73 said:Supply and demand.
If sugar batteries take off the demand will take off and at some point it will be more valuable to grow sugar to sell for batteries rather than food. Farmers grow sugar for the sake of profit.
A sugar-powered battery is a type of bio-battery that uses enzymes to convert sugar into electrical energy. This energy can then be used to power electronic devices.
The battery contains an enzyme called glucose oxidase, which breaks down sugar molecules into glucose and oxygen. The glucose is then further broken down by the enzyme to release electrons, which are used to generate electricity. The oxygen combines with protons to form water as a byproduct.
One of the main advantages is that sugar is a renewable and abundant resource. This makes sugar-powered batteries a more sustainable alternative to traditional batteries that use non-renewable resources. Additionally, sugar-powered batteries have a higher energy density compared to other bio-batteries, meaning they can store more energy in a smaller space.
One limitation is that sugar-powered batteries currently have a lower energy output compared to traditional batteries. This means they may not be suitable for high-demand devices. Additionally, the enzymes used in the battery may degrade over time, leading to a decrease in performance.
There are currently no known environmental concerns with sugar-powered batteries. However, the production of enzymes used in these batteries may have an impact on the environment. It is important to continue researching and developing more sustainable methods for producing these enzymes.