Forget iPhone 14, the world's fastest phone is coming;  Check out this amazing technology

Forget iPhone 14, the world’s fastest phone is coming; Check out this amazing technology

The iPhone 14 series is one of the fastest smartphones on the planet. But it is nothing compared to what this technology can offer. Check out what the world’s fastest phone is set to hold.

With the launch of the iPhone 14 series, we saw what apple The A16 Bionic chipset is capable of this and is extremely fast. On the Android The side of things, we saw Samsung The Galaxy Z Fold 4 boasts a Snapdragon 8+ Gen 1 processor, which is a beast similar to the A16. With 5G knocking on our front door, the world is already wondering how fast the next generation will be. However, if smartphone makers must keep up with this surge battle Internet Speed ​​and processing power, they must first tackle a large obstacle. How devices are made to deliver that kind of speed and power. But a surprisingly simple new machine can change the rules and advances of the game we The fastest phone in the world, which makes you forget the iPhone 14. Read on to find out more about it.

The technology that can create the fastest phone in the world

Nanwerk, the gateway to nanotechnology, Reports on this wonderful technology. But first, let’s understand the problem with developing faster internet speeds for the next generation of smartphones. To receive such high frequency signals, smart phones They must be equipped with antennas that can operate in the tens of gigahertz range. But for this to happen, the filaments in these antennas must be braided with a thickness of one micrometer. Current industrial equipment isn’t capable of producing something like this, and even if extensive research and development could create something that could, it wouldn’t be cheap.

This is where researchers at the Harvard John A. Paulson School of Engineering and Applied Science (SEAS) came in. study Published in the journal Nature titled “3D-Printed Machines Manipulate Microscopic Bodies Using Capillary Forces,” and explains how a simple, cheap machine could be built to get the same results.

B0BDK62PDX

The machine is ridiculously simple. The surface tension of . is used Water To move and manipulate microscopic objects to create grooves, braids, and more, and to fabricate nanomaterials. “Our work offers a potentially inexpensive way to fabricate materials with microstructures and possibly nanomaterials. Unlike other microprocessing methods, such as laser tweezers, our devices can be easily fabricated,” said Venuthan Manoharan, professor of chemical engineering and Wagner family in chemical engineering and professor of physics at SEAS and senior author. Research, “We use a water tank and a 3D printer, like those in many public libraries.”

The machine is a 3D printed rectangular piece of plastic where the inside of the machine has been carved to create channels with wide and narrow sections. These channels intersect at different points. The walls of the canal are made of hydrophilic material and they attract water.

Now the easiest thing to do was to move the microparticles into these channels and create grooves, but the intersection, required to make braid formations, was still difficult. “The eureka moment came when we found that we could move objects by changing the cross-section of the trapping channels. It was a moment of loud screams in joy when – on our first attempt – we crossed two fibers using only a piece of plastic, a water tank, and a stage that moved up and down,” she said. Maya Faborg, SEAS Associate.

It’s still early days for the team, and now they’re aiming to process multiple fibers simultaneously. The goal is to make high-frequency conductors and to manufacture microscopic devices. This could really be the birth of this kind of fast processor which is unimaginable nowadays and may lead the way for the fastest phones in the world ever.

#Forget #iPhone #worlds #fastest #phone #coming #Check #amazing #technology

Leave a Comment

Your email address will not be published. Required fields are marked *