The Sport is a new series of articles in which we examine some of the most interesting ideas and technologies from around the web.
We aim to bring you the latest news in engineering, technology, science, and other areas.
In this installment we take a look at a potential new antenna that uses graphene to absorb a signal from a mobile phone and then convert it into an electrical signal.
The concept is pretty simple.
A smartphone connects to a power source and transmits a signal to a receiver, which then converts the signal to electricity.
There’s a couple of ways to do this.
If you’re looking for a simple and cheap way to generate power from a smartphone signal, the best option is to just use a standard radio or antenna that can generate power on its own, and transmit it to the receiver.
However, if you’re interested in creating a device that can do more than just generate power, you’ll want to look for a more complex antenna.
Graphene is a promising material that is incredibly flexible.
It can be layered on top of a variety of other materials, which makes it a perfect conductor.
Its strength and density is a bit different from other materials like carbon fiber, but its conductivity is similar to carbon and its conductance is the same as copper.
Glimmer is a company that specializes in graphene, and it has developed a prototype antenna that converts signals from a cellphone to electrical signals.
The antenna is made of graphene, carbon, and titanium oxide.
Grams of graphene are approximately 0.1 millimeters thick, which means the antenna measures 1/32 of an inch in diameter.
When it comes to its density, graphene is actually the lightest of the three materials, according to Glimmers website.
The band gap between the graphene and the metal is about 20 nanometers.
That’s roughly the same gap as a human hair.
However it’s not just the density of the graphene that makes graphene attractive.
It’s also its conductive properties.
When you think of conductivity, you usually think of something like a rubber band.
But conductivity does not always refer to a specific material’s ability to conduct electricity.
It is, however, a property of a material that changes over time, as its density changes.
This means that conductivity changes as the material becomes more dense.
Gases, like water, move around in the air, which causes the conductivity of a substance to change over time.
If a material’s conductivity has been increased, it will become more conductive, so the amount of current it can transmit will also increase.
But if a material becomes conductive less, then the amount it can transfer will decrease.
For example, a carbon fiber made of titanium oxide is more conductible than a carbon weave made of carbon.
This is because titanium oxide’s conductance changes over a shorter period of time, which can cause it to become less conductive over time as well.
To illustrate this, we can use a graph of the conductance of a graphene fiber with a graphene weave made from carbon and a carbon-free fiber.
The graph shows that the conductances of the two materials are approximately the same, so they are essentially the same material.
However in the future, Glimms plan is to develop graphene that can be manufactured at a higher density, which will allow it to be used in more devices.
In fact, its design could be so good that it could be used as the basis for a high-speed wireless broadband network.
Graphene has been around for a while, but it wasn’t until a few years ago that it was recognized for its use in wireless communication.
Gorgon Electronics, a company based in Germany, developed a graphene antenna that allows a phone to transmit a signal and convert it to a high frequency radio frequency signal.
It uses a laser to focus light onto the graphene.
Then the laser pulses are combined with an electric current to create a beam of light that can travel up to 1.2 meters in the frequency band that is used by wireless networks.
In addition to being a great antenna, this antenna also converts a signal into a frequency that is capable of being transmitted wirelessly.
This makes it ideal for applications like cellular phone towers.
However for this project, Gorgons goal was to build a wireless power-generating antenna.
A power-gating antenna converts electrical signals to power that can then be transmitted.
However unlike an antenna, Goggon Electronics uses a transmitter instead of receiver.
This allows for a much higher signal-to-noise ratio, which increases signal transmission efficiency.
Theoretically, a transmitter is capable the receiver can convert the signals to energy that can go to a battery.
This reduces the amount that the receiver has to transmit to the phone and increases the amount the phone can transmit.
The main drawback of this antenna is that it is bulky, which restricts its usefulness in a wireless network.
However the antenna is still very