Graphene? Soybean!

February 3, 2017 by 37 Comments

True graphene is a one-atom thick layer of carbon. It’s incredibly conductive, transparent, and of course thin. It’s one of those materials that, if it were only cheaper, would be used in everything from batteries to water filtration. Researchers from CSIRO in Australia have found a novel, dirt-cheap, and simple way to make graphene, and it’s hacker-friendly, for certain values of hacker.

The method is to take a sheet of polycrystalline nickel foil, spread a thin layer of soybean oil on it, and heat it up to 800° C for three minutes. It’s cooled off, slid off the foil, and it’s done. While 800° is a lot hotter than a standard toaster oven, their setup isn’t really all that much different. Notably lacking are things like esoteric gasses, partial vacuums, and the like. The nickel foil has some kind of catalytic role in the process — you should read the original if you’re more of a chemist than we are. Continue reading “Graphene? Soybean!”

Making Graphene More Practical

July 20, 2016 by 2 Comments

[James Tour] and others at Rice University announced an improved form of graphene that uses nanoscale rivets. The material incorporates carbon nanotubes along with carbon spheres that encase iron nanoparticles. The nanotubes provide strength and higher conductivity overall, while the spheres let the material transfer more easily.

Typically, placing graphene on something involves using chemical vapor deposition on a polymer layer before transferring to another site. The polymer tends to degrade the graphene’s properties. This new material doesn’t require this intermediate step. In addition, the spheres allow interfacing to the graphene more readily.

Continue reading “Making Graphene More Practical”

Graphene Super Caps: Coming Soon?

December 10, 2015 by 29 Comments

If you read Hackaday regularly, you’ve probably heard that you can use a LASER to create graphene. There’s been a bit of research on how to make practical graphene supercapacitors using the technique (known as LIG or LASER-induced graphene). Researchers at Rice University have been working on this, and apparently they’ve had significant success inducing graphene capacitors on a Kapton substrate. The team has published a paper in Advanced Materials (which is behind a paywall) about their work.

In particular, Rice claims that they have easily produced supercapacitors with an energy density of 3.2 mW/cubic centimeter (that’s what the University’s website reports; they probably mean mW-hours/cubic centimeter) with capacitances near one millifarad per square centimeter. A key benefit of the construction method is that the capacitors continued to work after researchers bent them 10,000 times. A flexible capacitor is useful in wearable devices that would often flex, or in a device like a cell phone that could bend in your back pocket as you sit.

Continue reading “Graphene Super Caps: Coming Soon?”

Self Folding Graphene Paper

November 13, 2015 by 2 Comments

Origami, the art of folding paper into shapes, is the latest craft to fall to automation. Researchers in China have published a paper in Science Advances describing how they created graphene-based paper that can fold itself. According to their paper (that is, the paper they wrote, not their graphene paper), the new material can adopt a predefined shape, walk, or even turn a corner.

Active materials like shape memory polymers, aren’t new. But there are many practical problems with using such materials. Using MGMs (Macroscopic Graphene Materials), the researchers created paper that can change shape based on light. temperature, or humidity.

The video below shows a few uses including a self-folding box, a worm-like motion device, and a hand-like piece of paper making a grasping motion. The creators mention that there are a wide range of applications including robotics, artificial muscles, and sensing devices. After watching the video, we couldn’t help but wonder how cool a paper flower that opened in the sunlight would be.

We’ve covered how to make your own graphene in a home lab and even inside a DVD burner. We’ll be interested to see who is the first to hack some graphene paper and what you’ll use it for.

Continue reading “Self Folding Graphene Paper”

Better Capacitors Through Nanotechnology

October 25, 2015 by 29 Comments

Traditionally, capacitors are like really bad rechargeable batteries. Supercapacitors changed that, making it practical to use a fast-charging capacitor in place of rechargeable batteries. However, supercapacitors work in a different way than conventional (dielectric) capacitors. They use either an electrostatic scheme to achieve very close separation of charge (as little as 0.3 nanometers) or electrochemical pseudocapacitance (or sometime a combination of those methods).

In a conventional capacitor the two electrodes are as close together as practical and as large as practical because the capacitance goes up with surface area and down with distance between the plates. Unfortunately, for high-performance energy storage, capacitors (of the conventional kind) have a problem: you can get high capacitance or high breakdown voltage, but not both. That’s intuitive since getting the plates closer makes for higher capacitance but also makes the dielectric more likely to break down as the electric field inside the capacitor becomes higher with both voltage and closer plate spacing (the electric field, E, is equal to the voltage divided by the plate spacing).

[Guowen Meng] and others from several Chinese and US universities recently published a paper in the journal Science Advances that offers a way around this problem. By using a 3D carbon nanotube electrode, they can improve a dielectric capacitor to perform nearly as well as a supercapacitor (they are claiming 2Wh/kg energy density in their device).

cap1The capacitor forms in a nanoporous membrane of anodic aluminum oxide. The pores do not go all the way through, but stop short, forming a barrier layer at the bottom of each pore. Some of the pores go through the material in one direction, and the rest go through in the other direction. The researchers deposited nanotubes in the pores and these tubes form the plates of the capacitor (see picture, right). The result is a capacitor with a high-capacity (due to the large surface area) but with an enhanced breakdown voltage thanks to the uniform pore walls.

cap2To improve performance, the pores in the aluminum oxide are formed so that one large pore pointing in one direction is surrounded by six smaller pores going in the other direction (see picture to left). In this configuration, the capacitance in a 1 micron thick membrane could be as high as 9.8 microfarads per square centimeter.

For comparison, most high-value conventional capacitors are electrolytic and use two different plates: a plate of metallic foil and a semi-liquid electrolyte.  You can even make one of these at home, if you are so inclined (see video below).

We’ve talked about supercapacitors before (even homebrew ones), and this technology could make high capacitance devices even better. We’ve also talked about graphene supercaps you can build yourself with a DVD burner.

It is amazing to think how a new technology like carbon nanotubes can make something as old and simple as a capacitor better. You have to wonder what other improvements will come as we understand these new materials even better.

Continue reading “Better Capacitors Through Nanotechnology”

Laptop hardware hack

Laptop’s Aren’t Upgradable? Ha!

October 20, 2015 by 45 Comments

[MX372] is a pretty dedicated hardware hacker. Instead of chucking a 10 year old laptop with specs weaker than his latest cellphone — he decided to breath new life into it with a few hardware upgrades, and a switch to Linux of course.

Featuring a 1.1GHz Pentium M processor with a whopping 512mb DDR RAM, a dvd burner, a 40GB HDD, USB 2.0, BlueTooth, 802.11b/g wireless and even a FireWire port, his old Sony Vaio used to command a pretty hefty price tag. In fact, he’s pretty sure he paid $2,100 for it back in ’05. It was called an “ultrabook” before ultrabook actually meant a MacBook-Air sized laptop.

Still running Windows XP, it had gotten slower with age as all good computers do, and since XP is no longer supported, [MX372] thought it was time to switch it over to Linux. He started with Xubuntu 12, but quickly found Lubuntu instead. But, it still wasn’t that great. Continue reading “Laptop’s Aren’t Upgradable? Ha!”

Rod Logic And Graphene: Elusive Molecule-Scale Computers

October 19, 2015 by 23 Comments

I collect slide rules. You probably know a slide rule is a mechanical calculator of sorts. They usually look like a ruler (hence the name) and have a sliding part (hence the name) and by using logarithms you can multiply and divide easily by doing number line addition and subtraction (among other things).

It is easy to dismiss old technology like that out of hand as being antiquated, but mechanical computing may be making a comeback. It may seem ancient, but mechanical adding machines, cash registers, and even weapon control computers were all mechanical devices a few decades ago and there were some pretty sophisticated techniques developed to make them work. Perhaps the most sophisticated of all was Babbage’s difference engine, even though he didn’t have the technology to make one that actually functioned (the Computer History Museum did though; you should see it operating in person, but this is good too).

Continue reading “Rod Logic And Graphene: Elusive Molecule-Scale Computers”