Riken researchers controlled a three-qubit system. And that thing can be a revolution for AI research.

The breakthrough in quantum systems. Riken researchers controlled a three-qubit system in a silicon-based quantum computer. And they also made the error correction for that system. So why is this a fundamental thing? First thing is that the silicon-based quantum system is the thing that is needed, for the small-size quantum computer that operates at room temperature possible. 

There is the possibility to create hybrid systems that use magnets and high pressure to make the superconductor. That hybrid system can operate at room temperature. In that case, the high-power magnetic field will stabilize the wire and remove oscillation away from it. 

The AI uses the models of the brain for being effective. 

Do you know why we have three parts in our brains? The cerebrum has two parts or sections. And cerebellum is the part of the brain system. The odd number of data handling units guarantees that the system will not stuck. 

The AI model system will be stuck if there is an even quantity of data handling units. In that case, two parts of the system can make a different decisions. And if there is even quantity of the units that cause a fight. So in the brain cerebellum is required to choose the better solution if the sections of the cerebrum will get a different solution. 

The working artificial intelligence requires the system must have an odd number of data handling units. That thing denies the stuck of the system. 

But the ability to control the three-qubit system makes also possible to create the next-generation artificial intelligence. In that case, the system uses three qubits for emulating the human brain. The system will multiply data into three similar copies. And then that data will send through those qubits.

The reason why that quantum brain has three lines or qubits is simple. The use of three qubits denies the ability where the votes are tied if the system gets different solutions. Because there is an odd number of qubits. That means another possibility always has superior. 

In the case that. There is even a quantity of qubits that thing causes that system will halt. In that case, the system cannot make decisions. The odd number of qubits guarantees that the system will never halt because it cannot make decisions. Artificial intelligence requires a model where another side always gets superior. 

https://scitechdaily.com/quantum-breakthrough-researchers-demonstrate-full-control-of-a-three-qubit-system/

https://everyactioncausesthereaction.wordpress.com/2022/09/10/riken-researchers-controlled-a-three-qubit-system-and-that-thing-can-be-a-revolution-for-ai-research/

How to store data in quantum computers?

There are two ways to store data in quantum computers. They are different from each other. But they are both useful and they have their benefits. 

1) The data can store in the qubit. That thing requires that the qubit must be in a very stable environment. That storing the data is possible. The long-term storage of data is difficult. The reason for that is that the qubits are extremely sensitive to outcoming radiation and electromagnetic noise that destroys the data structure from the qubit. 

But if data is stored in the form of a qubit that data is ready to use right away. And those qubits can hover between the graphene layers for use in quantum computers. 

In error-detection systems, error detection can happen by using two quantum computers. There are two quantum lines and qubits will duplicate and then send to those lines at the same time. 

Then those computers will first compile the answers between those two data handling lines. And then they can compile the answers that different computers get. If there are no anomalies that thing makes sure that the answer is right. 

Or when the copy of the transmitted qubit is sent to the receiver. The receiver sends the checksum to the transmitter. Then the sender checks, that if the data is identical. If data is matching, nothing affected the qubit. While it travels between sender and receiver. So the data that is sent has maintained its shape while it traveled in the quantum channel. 

2) Data can store in the binary mode. The idea is that each layer or the state of the qubit will drive to the regular hard disks. So if we want to store 5 state qubits, we need five databases where the information from each layer or state of the qubits is stored. 

And the computer requires instructions on how to return those databases to qubits. Each of the databases must have a number that determines where each database must dump. So as an example database number three will be driven to the third layer of the qubit. 

So where to use those data storage models? 

The quantum computer might have two types of memory short-term memory or so-called fast operating memory. In that system, the qubits are a suitable way to store data. And the binary form of the data storage can use for long-term data storage. 

Short-term data storage is needed in error-tracking systems. The data will store in qubits when it will send to the quantum system. And in that process, the quantum computer takes the copy of the qubit. Then it sends the data to two quantum lines at the same time. Then that system compiles the answers. If there is a difference in those solutions. There is the possibility that something affects the qubit. 

But the error correlation system might also use binary storage. Of course, data like algorithms can store in binary mode. But there is the possibility that there is something like a heavy eruption of the sun. Or some strong gravitational wave that can disturb the qubit. 

There are developing systems. That can warn quantum computers about that kind of threat. But the AI-based system can also make it possible that the sensors like gravitational wave detectors and solar eruptions warning systems can send the warning to the quantum computer.

 And that thing makes it to back up the data to the binary storage. Storing data is important in the case,  that there is some kind of environmental anomalies. The quantum computers are the equipment of tomorrow. And they are advancing all the time. 

https://miraclesofthequantumworld.blogspot.com/

Quantum computers are taking the place of the number one simulator in the world.

Image 1) 

The image above this text portrays an advanced quantum computing system. Some of the quantum computers of tomorrow can use simply multi-channel radios. For their internal communication. In that system certain channel is a certain state of the qubit. And also the strength of the radio signal can determine the state of the qubit. That means a certain energy level is a certain state or level of the qubit.  

The thing that quantum computers are more effective tools to simulate and test quantum mechanics than binary computers is no surprise. The power of quantum computers is so superior that they can make the same calculations that take months by using binary computers in seconds. Quantum computers are the ultimate tools for creating new types of materials and enzymes, and they can map the DNA. 

And quantum computers can also use to control plasma at the fusion reactors. The thing is that quantum computers can also control nanomachines. The AI that is used to move nanomachines can run on the quantum server. That allows operating billions of nanomachines at the same time. Quantum computers can also control the data on the internet. And they can search and detect malicious code. 

The new solutions in nanotechnology require complicated AI software. And the power of quantum computers makes it possible to drive hard and complicated code and connect the data that is collected from sensors. 

The bright future of quantum computer-based AI means that when the number of the quantum computer increases their prices will get lower. The error detection in quantum computers is a similar process to binary computers. The system uses two or more data handling lines. And if those lines get the same result there are no errors. 

Image 2) Bacteriophage

Quantum computers operate with nanomachines by using similar WLAN systems with regular computers. The communication with WLAN systems will happen through binary computers that transform qubits to radio impulses. The thing is that by using the multi-channel radios. Is possible to send data in the form of qubits. In that case, every channel is a certain state of the qubit. And that makes the WLAN more effective. 

The nanomachine can be the genetically engineered bacteria that are controlled with microchips. The system can use bioelectricity or nano-size batteries for creating energy for those microchips.  The nano battery can be a virus where is small gold bites in the feet. When that gold hits with lead or some other base metal that gives electricity. That means the nanobatteries can create electricity also from hemoglobin. 

Image 3) Microchip on graphene.

The small-size or nanotechnical microchips require a new type of power source. The problem with nano-size microchips is that they need an extremely well-calculated energy level. If the electricity level is too high. That means the electric flow will jump over the switches. 

The newest microchips can create energy from graphene. That system captures the energy of the thermal movement of graphene. And that thing allows using that system also in the dark places. The IR radiation is one way to make the energy for that system. But there is the possibility to connect that graphene with miniature resistors. 

Or it can connect with living cells. When those cells will get nutrients their temperature will rise. And the thermal movement of graphene can cause by all possible thermal sources. That thing can use to control the nanomachines. If some medical nanomachine operates inside the human body it requires the WLAN system to communicate with computers.

https://scitechdaily.com/quantinuum-h1-quantum-computer-beats-classical-system-at-game-designed-to-test-quantum-mechanics/

https://www.thebrighterside.news/post/physicists-build-circuit-that-generates-clean-limitless-power-from-graphene

Image 1)https://scitechdaily.com/quantinuum-h1-quantum-computer-beats-classical-system-at-game-designed-to-test-quantum-mechanics/

Image 2)https://en.wikipedia.org/wiki/Bacteriophage

Image 3) https://www.thebrighterside.news/post/physicists-build-circuit-that-generates-clean-limitless-power-from-graphene

https://thoughtsaboutsuperpositions.blogspot.com/

The vibrating atoms are the new type of qubits.

Image 1) "MIT researchers have found a way to store quantum information in the vibrational motion of atom pairs, similar to the swinging motion of two pendula, connected by a spring. The quantum register contains hundreds of pairs of vibrating qubits that researchers can coherently control for over ten seconds. Credit: Sampson Wilcox/RLE" (ScitechDaily/MIT Physicists Have Discovered New Qubits for Quantum Computers Using Vibrating Atoms)

The time that the quantum computer can keep the superposition is the primary element in its speed. When the superposition is lost the system must re-adjust. That means the superposition must remake. The superposition of the vibrating atoms stays about ten seconds. And that thing is fundamental for quantum computing. Image 2 is the material that I mentioned in the past text. A laser ray that is pointed to the line of specific atoms can create atomic vibration. 

Image 2) (Phys.Org/Scientists weave atomically thin wires into ribbons)

Do you know, why there are used so uncommon material in quantum annealing systems? The thing is that the annealing system means that certain atoms are stressed by electromagnetic radiation. That makes them send radiation in their specific frequency. 

And if those atoms are not very common. That makes it easier to separate their annealing. From the "white noise". And that makes the system more accurate. But rare elements that can give unique wavelengths of radiation are expensive. 

Image 3) Atom superposition demonstration." MIT physicists find that pairs of atoms can hold a superposition of two vibrational states. Like two swinging pendula, the atoms can move in sync, and against each other, at the same time, making them robust qubits for quantum computing. Credit: Courtesy of the researchers." (ScitechDaily/MIT Physicists Have Discovered New Qubits for Quantum Computers Using Vibrating Atoms)

The vibrating atoms are making it possible to make flat and powerful quantum processing units. And that is a road to make quantum computers more common than they are today. Quantum computers are revolutionary machines that have abilities that are never even thought of. They can use to drive complicated AI solutions that are making analyzing the DNA easier. 

The fact is that quantum computers are turning more common. More people can use them. And that increases the power of those systems. 

More users bring more money. The investments bring more scientists for working in those quantum computer projects. And the thing is that the newest quantum computers are created by using the simulations driven on the quantum systems. 

And they are useful to make simulations of everything from cosmic formations to the actions of enzymes. Those systems can control drone swarms. And they can create new types of medicines. Also controlling nanomachines inside the human body is not more difficult than controlling drone swarms in nature. 

The fact is that quantum computers would not make cryptology useless. The thing is that the governments would just turn to use quantum computers for code making. And another thing is that code-breakers will also turn to quantum age. And they will start to use quantum computers to hack the codes that are made by using quantum computers. 

https://scitechdaily.com/mit-physicists-have-discovered-new-qubits-for-quantum-computers-using-vibrating-atoms/

Image 1) https://scitechdaily.com/mit-physicists-have-discovered-new-qubits-for-quantum-computers-using-vibrating-atoms/

Image 2) https://phys.org/news/2022-01-scientists-atomically-thin-wires-ribbons.html

https://thoughtsaboutsuperpositions.blogspot.com/

The IBM Unveils 127 qubit quantum computer.

That quantum computer is a big step to making fully commercial quantum computers. And those quantum computers would open new and bright visions for military and civil purposes. Quantum computers can hack any code that is made by using binary computers. And that thing means that they are causing a need to remake the entire security of the Internet. The history of quantum computers would repeat the history of binary computers. 

At first quantum computers are the systems that are locked at the calculation centers. But then they will turn to every-man machines and perhaps quite soon the regular personnel computers will turn to quantum computers. Things like programming language for quantum computers are bringing more users to them. The new programming language for quantum computers is making them easier to use. 

And user-friendly applications like AI-based code translators are bringing quantum computers to more users. That translator means that well-known computer code like C++, Python, or Jave can turn to quantum computers. And the new quantum programming language will benefit the abilities of the quantum systems. So while we are waiting for the personal quantum computers we can use quantum systems remotely. 

That thing makes it possible. That users can rent the time from the quantum computer centers. And that thing brings more money to the quantum computer projects. More projects and more solutions are bringing the quantum systems more common. But also more powerful and more multi-use. 

Quantum computers are only platforms. The abilities of quantum computers are determined by program code. And those systems might make the revolution in the civil and military systems needed to handle big entireties. The fact is that nobody expects that portable quantum computer have the same capacity as data-center-based fixed systems. 

In the same way. We don't think that a laptop is the same way powerful as a supercomputer.  But when we remember the advantage of supercomputers in the early 1980's systems had 1 mt. memory. We can say that modern laptop are far ahead of those computers. And the same thing will happen with quantum computers. 

The quantum network is at the door. The idea for the nanotube-based quantum network took from the nuclear test "Ivy Mike". 

When the first full-scale thermonuclear weapon detonated at the Marianna archipelago radiation from that bomb was conducted to the sensor by using a vacuum tube. That allowed those particles to reach the sensor before the particles that are traveling in the air. And that made it possible to observe the particles that were released from the hydrogen bomb. 

The quantum wires will protect against outside radiation effects. And then those nanotubes will be covered by electromagnetic fields. The electromagnetic fields are the thing that is covering the qubit against outcoming effects. The qubit could be an electron that rides with the laser rays in those nanotubes. So that thing makes it possible to create a system that connects quantum computers by using qubit-based connections. 

The quantum network can be a series of nanotubes. There might be a laser ray and a powerful electromagnetic field around those tubes. The purpose of those things is to minimize the outcoming errors that are affecting the nanotube. There would be an absolute gas vacuum in that tube. And that makes qubits possible to travel through that tube. '

Because the quantum computer sends photons through the vacuum. They are reaching sensors faster than photons that travel in the medium. The other way is to make the laser ray and the photon would ride in the tube in the fully controlled electromagnetic environment. 

https://www.eejournal.com/article/ibm-unveils-127-qubit-quantum-computer/

https://en.wikipedia.org/wiki/Ivy_Mike

Image 1:) https://www.eejournal.com/article/ibm-unveils-127-qubit-quantum-computer/

Image 2:) https://en.wikipedia.org/wiki/Ivy_Mike

https://thoughtsaboutsuperpositions.blogspot.com/

Silicon carbide can be a key to a new type of quantum network.

The dawn of quantum brains. 

There is new silicon-carbide-based material. That brings researchers one step closer to quantum networks. The link to that article is here and below this text. 

Maybe the futuristic quantum brains are looking like this. The 3D atomic structure where the electron-based qubits are transferring data in the electron chains and the atom-sized structures that act like neurons. 

The system would make the revolution in the quantum systems. Theoretically is possible to make a quantum computer that can operate at room temperature. The AI makes it possible to calculate how much power the resistance of the wires is sucking from the qubits at a certain distance. That makes it possible to calculate the point where the qubit delivers energy and where it reaches a certain state of the qubit. 

The problem with quantum computers is that they are loading information in electrons or some other particle. Then that thing will shoot to receive or data is sent by using superposition. In some visions, the qubit is shot through nanotubes to receivers.

But the problem is that the qubit requires extremely stable conditions. The outcoming radiation makes that qubit useless. Also, things like gravitational waves can affect the trajectory of the qubit. 

So, how to make more powerful quantum computers that can operate in higher temperatures. One version is to use the molecular structure where the electrons are traveling as they would travel in the normal wires. 

The idea of the quantum wires in this case is. That they are transporting qubits like other electrons. But in that case, the electron would transmit data in its internal structure. When an electron travels from another atom to the next atom. There is the possibility to calculate how much energy is delivered in that case. Theoretically is possible to transport the data of qubits by using the electron chains.

In that case, the electron transfers the information to the next electron. And that means the information can travel in the quantum computer like in regular electric wires. That means the superconducting wires can use as the data transporters in quantum computers. But in the wild visions, the quantum computer can operate also at room temperature. 

The room temperature operating quantum computer requires information on how much power the resistance of the wire sucks from qubits. And of course, the required information is what is the distance where the qubit reaches a certain energy level. That information allows the quantum computer can deliver information of the qubit at a certain point of that cable. 

There is one wild vision. That is connected with neurology and quantum computers. The idea is that the axons or qubit channels are surrounded by fast rotating plasma or quantum tornadoes. That thing makes the time dilation in the brains. And it makes it possible to create a system, that has more time to handle problems. But that thing is a theoretical way to connect quantum systems with biological brains. 

Sources: 

https://scitechdaily.com/new-silicon-carbide-qubits-bring-us-one-step-closer-to-quantum-networks/

Image)  https://scitechdaily.com/new-silicon-carbide-qubits-bring-us-one-step-closer-to-quantum-networks/

https://thoughtsaboutsuperpositions.blogspot.com/

The quantum tornadoes and quantum computers (Quantum tornadoes Part II)

The quantum tornadoes have a similar effect in the quantum world like a sonic whirl. That thing denies that the outcoming wave movement can affect particles like electrons that are traveling in it. 

The atom-size quantum tornadoes can use to turn the laser rays to screw. And that thing makes new possibilities for creating new quantum tools. The laser ray would shoot through the electromagnetic tornado. And that will affect the direction of the light. The electromagnetic tornado can use to create the laser ray that acts like an archimedean screw. Or it can use to make hollow laser rays. The hollow laser rays make it possible to shoot qubits through that quantum channel. 

But there could be possible usage. Also for the quantum tornado itself. It can use to cut molecules very accurately. And that thing can make the new visions for nanotechnology. The problem with nanotechnology is that the molecules must cut precisely at the right point. And the quantum tornado can be a useful tool for that thing. 

The quantum tornado acts like a tornado in our size world. When the electromagnetic whirl is forming around ions and atoms in the electromagnetic wave movement. That whirl affects the wave movement the same way as whirls are affecting air molecules. 

So the whirl is forming the channel in the wave movement. That channel minimizes the outcoming effect of the radiation. When the laser ray and qubit are sent inside that channel. That thing minimizes the effect of the outcoming radiation. 

The ion that rotates in a nanotube can use for creating stable quantum tornadoes. 

The problem with quantum tornadoes is that they are not very long-term phenomena. There is the possibility to make the superposition through the quantum tornado. In that vision, the quantum tornado protects the channel. That is formed between superpositioned and entangled particles. 

In that case, the quantum tornado is making it possible to protect information. That travels through that quantum entanglement. But as I wrote the quantum tornado is hard to stabilize. The electromagnetic whirl is forming around a rotating atom. Which temperature is near zero kelvin. 

There is the possibility to make the so-called stable quantum tornado by hovering the ion in the chamber or nanotube. The ion will stress by using radio-maser or coherent radio waves. Then that ion is put to rotate in the micro- or radio wave field that is shot through that nanotube. That thing makes it possible to create the long-term quantum tornado. 

If the slow qubit is shot in the quantum channel without a laser carrier. That thing makes the conditions that the energy is starting to flow out from the qubit very fast. So denying the outcoming radiation effect that thing increases the accuracy of the qubit. When the point of delivering energy or information of the qubit can determine very accurately. That gives more power to quantum systems. 

But that thing makes it possible to give more accurate radiation therapy than ever before. The electrons can shoot through the quantum tornadoes to the targeted cells. Then the system cuts the carrier radiation. And those electrons are starting to move the energy precisely to the target point. 

https://thoughtsaboutsuperpositions.blogspot.com/

Combining quantum- and nanotechnology is making the new type of machinery and systems possible.

Image: ()3D-graphene structure

The superpositioned and entangled particles can use as quantum circus saws. That makes them the new tools for nanotechnology. The nanosize machines are molecules. And the form of those molecules is the thing that makes them nanomachines.

When we are thinking as an example of the difference between nanomachines and chemical medicals the difference is that chemical medicine interacts with chemical reactions. That reaction neutralizes the medicine molecule. The nanomachine interacts with mechanical way. The typical interaction between nanomachine and the targeted cell is that nanomachine slips in the cell and starts to rotate. 

That system will destroy cell organelles and cut the membrane. Then that nanomachine can continue to other cells. And that thing makes wrong-used nanomachines extremely powerful weapons. One nanomachine can slip into the tissues and turn the victim to liquid. Because nanomachine itself will not interact, and that thing is chemically neutral it doesn't wake up chemical detectors that are normally alarming poison gasses. 

The superpositioned and entangled particles are the smallest and same way the most accurate tools in the world. They can use to affect the single chemical bond in the molecule. 

Those particles can cut the bonds of atoms very accurately. That allows cutting a certain chemical bond. And connect some other atom at that point. That thing will make the fundamental thing in molecular auto replication. If the other part of the double or higher number of bonds is cut. 

There is the possibility to connect a new atom to that point of the molecule. That atom can have the ability to make two bonds. And if one is connected with that released bond and one is touching with the other atoms. That can use to make the branches for the molecule.  That makes it possible to make new shapes for the molecule. 

The molecular auto replication bases the carbon. By making molecular machines. There is the possibility to bring some atoms that are touching and forming chemical bonds at certain points of the carbon chain. Those atoms can be brought in the wanted points by using ion cannon. And then the quantum circus saw will cut the needed bonds of the molecules and then those atoms in those positions. 

Including other atoms in graphene are increasing the abilities of that material. Graphene can position on the atom-size pillars over the layer. That thing gives it more abilities than if graphene is put straight over the layer.  If there are foreign atoms in the points where carbon lines are crossing, they are acting like miniature springs. The ability to make the 3D graphene structure allows making one of the hardest surfaces for the layers. 

The 3D graphene structure means that the multiple layers of the graphene are put over each other. Between those layers are other atoms that are acting like pillars between those layers. That makes this kind of nano-materials more capable than ever before. The pillars can position very accurately by using ion cannons, that is shooting them precisely in the right position. 

The new 2D qubits can make portable quantum computers possible.

Making the 2D qubits is the thing that makes it possible to create new and flat quantum processors. The base element for that 2D quantum structure can be the graphene where in the middle of carbon baskets is put the extremely small antenna that can transfer the data to the carbon structure. 

But the problem is how to separate signals from each line of the graphene. The ability to connect other materials or atoms with graphene makes it possible to create the 2D base for the qubit. In that case, the system bases the quantum annealing. The researchers are put the graphene on the gold film. But the ability to include other atoms inside the graphene structure itself can create the new type of qubits. 

In that case in graphene is connected with other elements than carbon. Which makes it easier to separate signals from each other. But the problem is, how to protect this system against outcoming electromagnetic stress? If the cosmic radiation hits the qubit that thing can destroy the quantum computer. 

()https://phys.org/news/2021-09-gold-quantum-qubits-2d-material.html

()https://phys.org/news/2021-09-adding-foreign-atoms-graphene-boosts.html

()https://phys.org/news/2020-11-d-graphene.html

Image:()()https://phys.org/news/2020-11-d-graphene.html

()https://kimmoswritings.blogspot.com/