What is Moore’s Law in Metaverse and Nono Technology Terms

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7 min readMar 26


What is Moore's Law in Metaverse and Nono Technology Terms

The Metaverse transformation is not about virtual reality, improved gaming or NFTs: it is about a paradigm change over the underlying economic principles. Your value chain will be flipped upside down in this new normal through the technology underpinnings of web 3.0. Your firm must be quick to change to the new normal if you want to take the most of it.

The trending Metaverse subject is a big topic worldwide, as you might already be aware. It was recently listed as one of the top five emerging trends and technologies for 2022 by Gartner. The phrase “metaverse” was discussed by 40% more corporations in their filing papers during the first quarters of 2022 vs the ending of 2021, according to GlobalData. People usually wonder “Who is powering the Metaverse?” The answer is Moore’s Law

How was Moore’s Law born?

By the production of integrated circuits and PCBs (Printed Circuit Boards), which are essential to the operation of computers, Intel has contributed to leading and pioneering the field of computer engineering. Leaders in the semiconductor industry predicted that as time went on, computers would become more sophisticated. In particular, Gordon Moore, a co-founder of Intel, predicted that every year, twice as many transistors would be able to fit onto computer chips due to the dwindling size of circuitry to the nanometer scale (allowing integrated circuits to be made up of more transistors, resulting in more powerful computer systems). Hence, Moore’s Law was established.

What is Moore’s Law in simple terms?

Moore’s Law states that the quantity of transistors on a microprocessor doubles every two years. The law promises that we may anticipate the speed and capability of our computers to rise every 2 years because of this, and so we will pay less for them.

Gordon Earle Moore

Gordon Earle Moore

Another premise of Moore’s Law claims that this increase is exponential. Gordon Moore, a co-founder and former CEO of Intel, is credited with creating the law. In 1965, Gordon E. Moore — co-founder of Intel (INTC) — postulated that the transistor count that can be placed into a given unit of the area will double about every two years. The forecast was revised after 1975 to a transistor doubling every two years.

Engineers were able to consistently produce computer systems/chips with twice as many transistors, leading to the development of a number of more sophisticated technologies, including cloud computing, wearable technology, mobile technology, smart technology, faster processors, and more robust computers. In order to create more effective nanotechnology systems, engineers were able to reduce the size of transistors from millimetres to nanometers. Engineers are unable to keep pushing the limit on smaller transistors, and as a result, computer systems may have reached their limit in transistor capacity and power. However, feats in physics and engineering have been tried to push to their limit, and more authority results in more assets and more abilities to carry out advanced tasks via computers. Thus, industry leaders are stating that Moore’s Law and the Metaverse will collapse, and computers will no more have many more transistors per year.

What is Moore’s Law Example? What Contributions Did It Make?

Moore’s Law is basically an estimate anticipating the quick growth of increasingly complex technology, and the evolution of transistors. It served as a strategic stepping stone that enabled larger businesses to plan the adoption of technologies that could profit from more powerful computer systems. With the introduction of more potent computers, gaming consoles, cloud/data centres, and workstations, Moore’s Law has altered how end users and businesses have operated. This has led to changes in strategic plans (for businesses), increased capacities, and even the creation of new systems and apps which have benefited from more potent computational power (for consumers).

In addition, entire businesses have emerged as a result of Moore’s Law, including those for tiny wearable technology, Internet of Things gadgets, smart technology, and robust cloud systems whose circuits include an incredible number of transistors and enable previously unheard-of computational capability with Moores Law and the Metaverse. Such talents have contributed to building Big Data Analysis, Business Analytics, and even Artificial Intelligence businesses inside the world of SMEs and larger enterprises.

How is Moore’s Law Coming To An End?

Moore’s Law, anticipating the evolution of more robust computer networks is coming to end simply because researchers are unable to manufacture devices with smaller transistors. Computer chips need new developmental structures placed into them in the order to be as efficient if more neurons are to be employed. Although the development of more powerful computers is thought to be the most crucial component of a computer system, energy efficiency and device lifetime are equally crucial, necessitating the more efficient use of large quantities of transistors, particularly when it comes to large cloud data centres that power a significant portion of online web applications.

What’s Going To Happen Next?

Major chip manufacturing firms, such as Intel, have delayed their distribution of smaller transistors in the past, and have allowed longer time to pass between their chip generations. In other words, semiconductor manufacturers are reducing their chip development plans and rollouts. The strategic roadmaps that are tied to Moore’s Law and the anticipated rollout of more durable computer systems over the coming years are also being abandoned by industry executives. Yet, these estimates of more resilient computer systems are predicated on the estimate that Moore’s Law embodies. Moore’s Law, Who is powering the Metaverse, didn’t last forever, so manufacturers will still make computers that are physically more powerful — they just won’t do so as quickly.

Nanotechnology to Enhance Moore’s Law

Nanotechnology could be a breakthrough in allowing the semiconductor industry to cram more speed and power into tiny microchips while making them more energy-efficient and less affordable to manufacture. The semiconductor industry is struggling to create lithographic technology for features smaller than 22 nm and investigate new classes of transistors that use silicon nanowires or carbon nanotubes, as we have already addressed in this work. Basically, the best-known ways to incorporate nanotechnology with Moore’s law are:

1. DNA Scaffolding Tiny Circuit Board.

This method’s value comes from the fact that the strategically placed DNA nanostructures can act as scaffolds or tiny circuit boards for the precise assembly of parts, like carbon nanotubes, nanowires, and nanoparticles, at sizes that are much smaller than those made possible by traditional semiconductor fabrication methods. This offers up the prospect of building functioning devices that may be integrated into bigger structures, as well as permitting investigations of arrays of nanostructures with defined coordinates.

2. 3D Tri-Gates Transistor.

An Intel 3D transistor design was debuted in 2011 with its Ivy Bridge microarchitecture. The Tri-Gate design is termed 3D because the gateway wraps around elevated source-to-drain channels, called a “fin,” instead of living on top of the channel in the standard 2D planar design. In addition, numerous fins are used, which give more control of each stage.

3. Spintronics.

The field of spintronics, commonly referred to as spin electronics, is the study of the inherent spin of the electron, its magnetic moment, and its fundamental electronic charge in solid-state devices. Spintronics is a portmanteau term for spin transport electronics. Spin-charge coupling in metallic systems is the subject of the field of spintronics; multiferroics deals with comparable processes in insulators. Spintronic systems are most often realised in dilute magnetic semiconductors (DMS) and Heusler alloys which are of particular interest in the area of quantum computing and neuromorphic computing.

4. Single-Atom Transistor

T. Schimmel

Prof. Dr. Thomas Schimmel

- Research Unit Chair

- Research Unit: Scanning Probe Microscopy and Nanolithography

- Room: 0–124 or 6–12 c/o Institute of Applied Physics (APH), Campus Süd, Bldg. 30.23

- Research Unit Schimmel

A single-atom transistor is a device that can open and stop an electrical circuit by the controlled and reversible repositioning of one single atom. The single-atom transistor was designed and initially demonstrated in 2004 by Prof. Thomas Schimmel and his group of scientists at the Karlsruhe Institute of Technology. A single silver atom is reversibly pushed in and out of a tiny junction using a little voltage output applied to a control electrode, the so-called gate electrode, therefore closing and opening an electrical contact.

5. Carbon Nanotube (CNT).

Carbon nanotubes (CNTs) are cylindrical molecules made of sheets of single-layer carbon atoms that have been coiled up (graphene). They can be single-walled (SWCNT), with a diameter of 1 nanometre (nm), or multi-walled (MWCNT), consisting of many concentrically interconnected nanotubes, with sizes reaching more than 100 nm. Their length can extend up to many micrometres or even millimetres.

Future of Nanotechnology in Enhancing Moore’s Law

Now that you know Who is powering the Metaverse, it’s better to take the heads up! Determining if Moore’s Law and the Metaverse have an upper bound depends on future developments in electronics, material science, and physics. Moore’s prediction as early as 1965 indicates that he is a novel technical visionary who discreetly led the silicon revolution with his law. We predict that Moore’s Law’s presently recognised barriers will be strengthened by potential future nanotechnologies.



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