Quantum Computing Keywords

We can start to focus in on qubit modalities by composing a working quantum computing vocabulary:

Table Of Contents
What Are Qubits?
What Is A Universal Quantum Computer?
What Is Quantum Annealing?
What Is Quantum Speedup?
What Is Quantum Edge?
What Is Quantum Supremacy?
What Is A Bloch Sphere?
What Is Coherence in Quantum Computing?
What Is DiVincenzo Criteria?
What Is Quantum Entanglement?
What Is Measurement In Quantum Computing?
What Are Quantum Dots?
What Is Quantum Error Correction?
What Is Quantum Indeterminacy?
What Is Quantum Tunneling?
What Is Superposition?
What Is Teleportation In Quantum Computing?
What Is A Topological Quantum Computer?

What Are Qubits?

The quantum equivalent of conventional digital bits are qubits (quantum bits). 

• The qubits are in a state of superposition and operate on quantum mechanics principles. 

• To alter the state of the qubits, we must use quantum mechanics concepts. 

• We can measure the state of the qubits at the conclusion of the computation by projecting them into conventional digital bits. 

What Is A Universal Quantum Computer?

A Quantum Turing Machine, also known as a Universal Quantum Computer, is an abstract machine that is used to simulate the effects of a quantum computer. 

• Any quantum algorithm may be described formally as a particular quantum Turing Machine, similar to the conventional Turing Machine. 

Quantum states defined in Hilbert space are used to represent internal states. 

• In Hilbert space, the transition function is a collection of unitary matrices. 

What Is Quantum Annealing?

Quantum Fluctuations are used to discover a heuristic method that finds a global minimum from a limited collection of candidate solutions. 

• Quantum Annealing may be used to tackle combinatorial optimization problems having a discrete search space with multiple local minima, such as the traveling salesman problem. 

• The system begins with the quantum parallelism superposition of all possible states and evolves using the time-dependent Schrodinger equation. 

• The amplitudes of all states may be altered by changing the transverse field (a magnetic field perpendicular to the axis of the qubit), resulting in Quantum Tunneling between them. 

The aim is to maintain the system as near to the Hamiltonian's ground state as possible. 

• The system achieves its ground state when the transverse field is eventually switched off, which corresponds to the solution of the optimization issue. 

• D-Wave Systems exhibited the first Quantum Annealer in 2011. 

What Is Quantum Speedup?

This is the best-case situation, in which no classical algorithm can outperform a quantum algorithm. 

• There are a few quantum algorithms that have a polynomial speedup in addition to factorization and discrete logarithms. 

• Grover's algorithm is one such algorithm. 

There have been reports on simulation methods for physical processes in quantum chemistry and solid-state physics. 

• The main ideal problem in polynomial time and an approximation method for Jones polynomial with a polynomial speedup and a solution to Pells' equation have been presented. 

• This area is changing. 

What Is Quantum Edge?

Quantum computers have a computational advantage. 

• The idea that quantum computers can execute certain calculations more quickly than traditional computers. 

What Is Quantum Supremacy? 

Quantum computers' prospective capacity to tackle issues that conventional computers can't. 

• Decoherence is the process by which the quantum information in a qubit is lost over time as a result of interactions with the environment. 

• Quantum Volume is a practical method to track and compare progress toward lower system-wide gate error rates for quantum computing and error correction operations in the near future. 

• It's a single-number metric that a concrete protocol can measure with a quantum computer of modest size n <=50 in the near future.

What Is A Bloch Sphere?

The Bloch sphere, named after scientist Felix Bloch, is a geometrical representation of the pure state space of a two-level quantum mechanical system (qubit) in quantum mechanics. 

• Antipodal points correspond to a pair of mutually orthogonal state vectors on the Bloch sphere, which is a unit sphere. 

The Bloch Sphere's interpretation is as follows: 

• The poles represent classical bits, and the notation |0 and |1 is used to denote them. 

• Unlike conventional bit representation, where these are the only conceivable states, quantum bits span the whole sphere. 

• As a result, quantum bits contain a lot more information, as shown by the Bloch sphere. 

• When a qubit is measured, one of the two poles collapses. 

Which of the two poles collapses depends on which direction the arrow in the Bloch representation points: 

• if the arrow is closer to the north pole, there is a greater chance of collapsing to that pole; similarly, 
• if the arrow is closer to the south pole, there is a greater chance of collapsing to that pole. 

This adds the concept of probability to the Bloch sphere: 

• the angle of the arrow with the vertical axes correlates to that probability. 

• If the arrow points to the equator, each pole has a 50/50 probability of collapsing.

What Is Coherence in Quantum Computing?

A qubit's coherence is defined as its capacity to sustain superposition across time. 

• It is therefore the lack of "decoherence," which is defined as any process that collapses a quantum state into a classical one, such as contact with the environment.

What Is  DiVincenzo Criteria?

The DiVincenzo criteria are a set of requirements for building a quantum computer that were originally suggested by theoretical physicist David P. DiVincenzo in his article "The Physical Implementation of Quantum Computation" in 2000. 

The DiVincenzo criteria are a collection of 5+2 requirements that must be met by an experimental setup in order to effectively execute quantum algorithms like Grover's search algorithm or Shor factorization. 

To perform quantum communication, such as that utilized in quantum key distribution, the two additional requirements are required.

1 – A physically scalable system with well-defined qubits.

2 – The ability to set the qubits' states to a simple fiducial state.

3 – Long decoherence periods that are relevant.

4 – A set of quantum gates that is “universal.”

5 – A measuring capability unique to qubits.

6 — Interconversion of stationary and flying qubits.

7 – The capacity to reliably transfer flying qubits between two points.

What Is Quantum Entanglement?

Quantum entanglement is a unique relationship that exists between two qubits. 

• Entanglement may be created in a variety of ways. 

• One method is to entangle two qubits by bringing them close together, performing an operation on them, and then moving them apart again. 

• You may move them arbitrarily far away from each other after they're entangled, and they'll stay intertwined. 

The results of measurements on these qubits will reflect this entanglement. 

• When measured, these qubits will always provide a random result of zero or one, regardless of how far apart they are. 

The first characteristic of entanglement is that it cannot be shared, which allows all of the applications that are derived from it to be created. 

• If two qubits are maximally entangled, no other person in the universe may share their entanglement. 

• The monogamy of entanglement is the name given to this feature.

Maximum coordination is the second characteristic of entanglement that gives it its strength. 

• When the qubits are measured, this characteristic is shown. 

• When two entangled qubits are measured in the same basis, no matter how far apart they are, the result is always the same. 

• This result is not predetermined; rather, it is entirely random and determined at the time of measurement.

What Is Measurement In Quantum Computing?

The act of seeing a quantum state is known as measurement. 

• This observation will provide traditional data, such as a bit. 

• It's essential to remember that the quantum state will change as a result of this measurement procedure. 

If the state is in superposition, for example, this measurement will cause it to ‘collapse' into a classical state: zero or one. 

• This process of collapsing occurs at random. 

• There is no way of knowing what the result will be until the measurement is completed. 

• However, the chance of each result may be calculated. 

This probability is a prediction about the quantum state that we can test by preparing it many times, measuring it, and calculating the percentage of each result.

What Are Quantum Dots?

Quantum dots may be thought of as "manufactured atoms." 

• They are semiconductor nanocrystals in which an electron-hole pair may be trapped. 

• Because the nanoscale size is equivalent to the wavelength of light, the electron may occupy distinct energy levels, exactly as in an atom. 

• The dots may be encased in a photonic crystal cavity and probed with laser light.

What Is Quantum Error Correction?

Quantum computers are always in touch with the outside world. This environment has the potential to disrupt the system's computational state, resulting in data loss. 

• Quantum error correction compensates for this loss by distributing the system's computational state over multiple qubits in an entangled state. 

• Outside classical observers may detect and correct perturbations using this entanglement without having to see the computational state directly, which would collapse it.

What Is Quantum Indeterminacy?

The basic condition of existence, backed up by all empirical evidence, in which an isolated quantum system, like as a free electron, does not have fixed characteristics until those attributes are seen in experiments intended to quantify them. 

• That is, unless those characteristics are measured, a particle does not have a particular mass, location, velocity, or spin. 

• Indeed, the particle does not exist until it is seen in a strict sense.

What Is Quantum Tunneling?

Due to the wave-like nature of particles, quantum tunneling is a quantum mechanical phenomenon in which particles have a limited chance of overcoming an energy barrier or transiting through an energy state usually prohibited by classical physics. 

• A particle's probability wave reflects the likelihood of locating the particle in a certain place, and there is a limited chance that the particle is on the opposite side of the barrier.

What Is Superposition?

Quantum physics' basic premise is superposition. 

• It asserts that quantum states, like waves in classical physics, may be joined together – superposed – to produce a new valid quantum state, and that every quantum state can be seen as a linear combination, a sum of other unique quantum states.

What Is Teleportation In Quantum Computing?

Quantum teleportation is a technique that uses entanglement to transmit qubits. 

• The following is how teleportation works: 

• Initially, Alice and Bob must create an entangled pair of qubits between them. 

• Alice next conducts a measurement on the qubit she wishes to transmit as well as the qubit that is entangled with Bob's qubit. 

• This measurement compresses the qubits and breaks the entanglement, but it also provides her with two classical outcomes in the form of two classical bits. 

• Alice transmits these two traditional bits to Bob over the traditional Internet. 

• Bob next applies to his qubit a rectification operation that is based on these two classical bits. 

• As a result, he is able to reclaim the qubit that was previously in Alice's control. 

It's worth noting that we've now sent a qubit without really utilizing a physical carrier capable of doing so. 

To accomplish this, you'll need entanglement, of course. 

It's also worth noting that quantum teleportation doesn't allow for communication faster than the speed of light. 

• This is because Bob will not be able to make sense of the qubit she has in her hands until he receives the classical measurement results from Alice. 

• The transmission of these traditional measurement results must take a certain length of time. 

• This time is also constrained by the speed of light.

What Is A Topological Quantum Computer?

A topological quantum computer is a theoretical quantum computer that uses anyons, which are two-dimensional quasiparticles whose world lines intersect to create braided in a three-dimensional spacetime (i.e., one temporal plus two spatial dimensions). 

• The logic gates that make up the computer are formed by these strands. 

• The benefit of utilizing quantum braiding over trapped quantum particles in a quantum computer is that the former is considerably more stable. 

• Small, cumulative perturbations may cause quantum states to decohere and create mistakes in computations, but they have no effect on the topological characteristics of the braiding. 

• This is comparable to the work needed to cut a string and reconnect the ends to create a new braid, rather than a ball (representing an ordinary quantum particle in four-dimensional spacetime) colliding with a wall. 

In 1997, Alexei Kitaev suggested topological quantum computing.

~ Jai Krishna Ponnappan

You may also want to read more about Quantum Computing here.

What Is A QPU?

What is a Quantum Processing Unit (QPU)? 

Despite its widespread use, the phrase "quantum computer" may be misleading. 

It conjures up thoughts of a whole new and alien kind of computer, one that replaces all current computing software with a future alternative. 

• This is a widespread, though massive, misunderstanding at the time of writing. 
• The potential of quantum computers comes from its capacity to significantly expand the types of problems that are tractable inside computing, rather than being a traditional computer killer. 
• There are significant computational problems that a quantum computer can readily solve, but that would be impossible to solve on any conventional computing device we could ever hope to construct. 

But, importantly, these sorts of speedups have only been observed for a few issues, and although more are expected to be discovered, it's very doubtful that doing all calculations on a quantum computer would ever make sense. 

For the vast majority of activities that use your laptop's clock cycles, a quantum computer is no better. 

In other words, a quantum computer is actually a co-processor from the standpoint of the programmer. 

• Previously, computers utilized a variety of coprocessors, each with its own set of capabilities, such as floating-point arithmetic, signal processing, and real-time graphics. 

• With this in mind, we'll refer to the device on which our code samples run as a QPU (Quantum Processing Unit). 

This, we believe, emphasizes the critical context in which quantum computing should be considered. 

A quantum processing unit (QPU), sometimes known as a quantum chip, is a physical (fabricated) device with a network of linked qubits. 

• It's the cornerstone of a complete quantum computer, which also comprises the QPU's housing environment, control circuits, and a slew of other components.

Programming for a QPU

Like other co-processors like the GPU (Graphics Processing Unit), QPU programming entails creating code that will mainly execute on a regular computer's CPU (Central Processing Unit). 

• The CPU only sends QPU coprocessor instructions to start tasks that are appropriate for its capabilities. 

• Fortunately (and excitingly), a few prototype QPUs are already accessible and may be accessed through the cloud as of this writing. 

• Furthermore, conventional computer gear may be used to mimic the behavior of a QPU for simpler tasks. 

Although emulating bigger QPU programs is impractical, it is a handy method to learn how to operate a real QPU for smaller code snippets. 

• Even when more complex QPUs become available, the fundamental QPU code examples will remain both useful and instructive. 

• There are a plethora of QPU simulators, libraries, and systems to choose from.

Quantum Processing Units (QPU) Make Quantum Computing Possible.

A quantum processing unit (QPU) is a physical or virtual processor with a large number of linked qubits that may be used to calculate quantum algorithms. 

• A quantum computer or quantum simulator would not be complete without it. 

• Quantum devices are still in their infancy, and not all of them are capable of running all Q#  programs. 

• As a result, while creating programs for various targets, you must keep certain constraints in mind. 

• Quantum mechanics, the study of atomic structure and function, is used to create a computer architecture. 

Quantum computing is a world apart from traditional computing ("classical computing"). 

• It can only answer a limited number of issues, all of which are based on mathematics and expressed as equations. 

• Quantum computer processing imitates nature at the atomic level, and one of its most promising applications is the investigation of molecule interactions in order to unravel nature's secrets. 

At Oxford University and IBM's Almaden Research Center in 1998, the first quantum computers were demonstrated. 

• There were around a hundred functional quantum computers across the globe by 2020. 

• Due to the exorbitant expense of creating and maintaining quantum computers, quantum computing will most likely be delivered as a cloud service rather than as hardware for enterprises to purchase. We'll have to wait and see. 

Quantum coprocessor and quantum cloud are two terms for the same thing. 

Because data rise at such a rapid rate, even the fastest supercomputers face a slew of issues. 

• Consider the classic traveling salesman dilemma, which entails determining the most cost-effective round journey between locations. 

• The first stage is to calculate all feasible routes, which yields a 63-digit number if the journey involves 50 cities. 

• Whereas traditional computers may take days or even months to tackle similar issues, quantum computers are projected to respond in seconds or minutes. 

• Quantum teleportation, binary values, rice, and the chessboard legend are all examples of quantum supremacy. 

Superposition and Entanglement of Qubits. 

Quantum computing relies on the "qubit," or quantum bit, which is made up of one or more electrons and may be designed in a variety of ways. 

• The situation that permits a qubit to be in several states at the same time is known as quantum superposition (see qubit). 

• Entanglement is a trait that enables one particle to communicate with another across a long distance. 

• The two major kinds of quantum computer designs are gate model and quantum annealing. 

 

Gate Model QC

 

"Quality Control Model" : 

Quantum computers based on the gate model have gates that are similar in principle to classical computers but have significantly different logic and design. 

• Google, IBM, Intel, and Rigetti are among the businesses working on gate model machines, each with its own qubit architecture. 

• Microwave pulses are used to train the qubits in the quantum device. 

• The QC chip does digital-to-analog and analog-to-digital conversion. 

IBM's Q Experience on the Cloud

• In 2016, IBM released a cloud-based 5-qubit gate model quantum computer to enable scientists to experiment with gate model programming. 

• The open source Qiskit development kit, as well as a second machine with 16 qubits, were added a year later. 

• A collection of instructional resources is available as part of the IBM Q Experience. 

• IBM Q Gate Model

Superconducting materials

• Superconducting materials, like those employed in the D-Wave computer, must be stored at subzero temperatures, and both photographs show the coverings removed to reveal the quantum chip at the bottom. 

• Intel's Tangle Lake gate model quantum processor, featuring a novel design of single-electron transistors linked together, was introduced in 2018. 

• At CES 2018, Intel CEO Brian Krzanich demonstrated the processor. 

D-Wave Systems

D-Wave Systems in Canada is the only company that provides a "quantum annealing" computer. 

• D-Wave computers are massive, chilled computers with up to 2,000 qubits that are utilized for optimization tasks including scheduling, financial analysis, and medical research. 

• To solve an issue, annealing is used to identify the best path or the most efficient combination of parameters. 

D-Wave Chips have 5,000 qubits in their newest quantum annealing processor. 

• A cooling mechanism is required, much as it is for gate type quantum computers. 

• It becomes colder all the way down to minus 459 degrees Fahrenheit using liquid nitrogen and liquid helium stages from top to bottom. 

Algorithms for Quantum Computing. 

Because new algorithms impact the construction of the next generation of quantum architecture, the algorithms for addressing real-world issues must be devised first. 

• Both the gate model and the annealing processes have challenges to overcome. 

• However, experts anticipate that quantum computing will become commonplace in the near future. 

State of Quantum Computing

Quantum computers are projected to eventually factor large numbers and break cryptographic secrets in a couple of seconds. 

• It is just a matter of time, according to scientists, until this becomes a reality. 

• When it occurs, it will have grave consequences since every encrypted transaction, as well as every current cryptocurrency system, will be exposed to hackers. 

• Quantum-safe approaches, on the other hand, are being developed. Quantum secure is one example of this. 

The United States, Canada, Germany, France, the United Kingdom, the Netherlands, Russia, China, South Korea, and Japan are the nations that are studying and investing in quantum computing as of 2020. 

The field of quantum computing is still in its infancy. 

When an eight-ton UNIVAC I in the 1950s developed into a chip decades later, it begs the question of what quantum computers would look like in 50 years.

~ Jai Krishna Ponnappan

You may also want to read more about Quantum Computing here.

How COSMOS-webb Is Mapping The Universe's Oldest Structures

When NASA's James Webb Space Telescope begins scientific operations in 2022, one of its first missions will be to record the universe's oldest structures. 

• COSMOS-Webb is the biggest mission Webb will undertake during its first year, with a broad and deep survey of half a million galaxies. 

• COSMOS-Near-Infrared Webb's Camera will scan a vast area of the sky—0.6 square degrees—with more than 200 hours of observation time (NIRCam). That's three full moons in size. 

• With the Mid-Infrared Instrument, it will map a smaller region at the same time (MIRI). 

"It's a huge swath of sky that's unique to the COSMOS-Webb mission. The majority of Webb projects go extremely deep, similar to pencil-beam surveys that examine small areas of sky "Caitlin Casey, an assistant professor at the University of Texas at Austin and the COSMOS-Webb program's co-leader, said. 

We can look at big-scale features at the beginning of galaxy formation since we're covering such a wide region. 

"We'll also search for some of the earliest galaxies, as well as trace the large-scale dark matter distribution of galaxies back to the beginning." 

• Dark matter is invisible because it does not absorb, reflect, or emit light. Because of the impact it has on things that we can see, we know dark matter exists.

• With multi-band, high-resolution near-infrared imaging and an unprecedented 32,000 galaxies in the mid infrared, COSMOS-Webb will investigate half a million galaxies. 

• This survey will be a major legacy dataset from Webb for scientists researching galaxies beyond the Milky Way, thanks to its fast public release of the data. 

COSMOS started as a Hubble mission in 2002 to photograph a considerably bigger region of sky, about the size of ten full moons. 

• The cooperation grew from there to encompass the majority of the world's main telescopes on Earth and in space. 

• COSMOS is now a multi-wavelength survey that spans the whole electromagnetic spectrum from X-ray to radio. 

• The COSMOS field is visible from observatories all around the globe because to its position in the sky. 

• Because it is located on the celestial equator, it may be examined from both the northern and southern hemispheres, yielding a wealth of information. 

"A lot of extragalactic scientists go to COSMOS to conduct their analyses because the data products are so widely available, and it covers such a large area of the sky," said Jeyhan Kartaltepe, assistant professor of physics and co-leader of the COSMOS-Webb program at Rochester Institute of Technology. 

We're utilizing Webb to expand our coverage in the near-to mid-infrared portion of the spectrum, and therefore stretching out our horizon, or how far away we can see. 

COSMOS-Webb will expand on past findings to achieve breakthroughs in three areas of research: changing our knowledge of the Reionization Era, searching for early, fully developed galaxies, and understanding how dark matter evolved with star content in galaxies. 

To revolutionize our knowledge of the post-reionization period. 

The cosmos was totally black soon after the big bang. 

• Stars and galaxies, which provide light to the universe, had not yet formed. 

• The cosmos was made out of a primordial soup of neutral hydrogen and helium atoms, as well as unseen dark matter. 

• This period is known as the cosmic dark ages. 

• The first stars and galaxies appeared after several hundred million years, providing energy to reionize the early cosmos. 

• This energy broke apart the hydrogen atoms that made up the cosmos, charging them and bringing the cosmic dark ages to an end. 

The Reionization Age is the name given to the new era in which the cosmos was filled with light. 

• The primary aim of COSMOS-Webb is to study the reionization period, which occurred between 400,000 and 1 billion years after the big bang. 

• Reionization most likely occurred in little bursts rather than all at once. 

• COSMOS-Webb will search for bubbles that indicate where the early universe's initial pockets of reionization occurred. 

The team wants to figure out how big these reionization bubbles are. 

• "Hubble did a fantastic job of locating a few of these galaxies out to early periods," Casey said, "but we need many more galaxies to understand the reionization process." Scientists have no idea what type of galaxies ushered in the Reionization Era, whether they were large or low-mass systems. 

• COSMOS-Webb will be able to locate extremely big, uncommon galaxies and study their distribution in large-scale structures, which will be a first. 

So, do the galaxies that cause reionization live in a cosmic metropolis, or are they generally equally dispersed across space? 

Only a large survey like COSMOS-Webb can assist scientists in answering this question. 

Finding early, fully developed galaxies. 

COSMOS-Webb will look for fully developed galaxies that stopped forming stars in the first 2 billion years after the big bang. 

• Hubble has discovered a few of these galaxies, which call into question current theories about how the universe came to be. 

• Scientists are baffled as to how these galaxies may contain ancient stars while not generating any new ones so early in the universe's existence. 

• Many of these unusual galaxies will be discovered by the team using a big survey like COSMOS-Webb. 

• They want to study these galaxies in depth in order to figure out how they might have developed so quickly and shut off star production so early. 

Discovering how dark matter developed in relation to star content in galaxies. 

COSMOS-Webb will provide scientists with information on how dark matter in galaxies has changed through time as the star composition of galaxies has changed. 

• Galaxies are made up of two kinds of stuff: visible matter that we see in stars and other objects, and unseen dark matter that is frequently more massive than the galaxy and may surround it in a halo. 

• In galaxy creation and evolution, these two types of matter are linked. 

• However, there is currently little understanding of how the dark matter mass in galaxies' halos originated and how that dark matter influences galaxies' formation. 

COSMOS-Webb will shed light on this process by enabling scientists to use "weak lensing" to directly detect these dark matter halos. 

• Gravity from any kind of mass, whether dark or bright, may act as a lens, bending the light we see from faraway galaxies. 

• Weak lensing alters the apparent form of background galaxies, allowing scientists to directly estimate the mass of the halo's dark matter when it's in front of other galaxies. 

• "For the first time, we'll be able to measure the relationship between dark matter mass and luminous mass of galaxies back to the first 2 billion years of cosmic time," said team member Anton Koekemoer, a research astronomer at the Space Telescope Science Institute in Baltimore who helped design the program's observing strategy and is in charge of constructing all of the images from the project. 

• "That's an important era for us to understand how galaxies' mass was initially set in place, and how dark matter halos drive it. And that, in turn, may help us comprehend galaxy formation in a more indirect way." 

Data sharing with the community in a timely manner COSMOS-Webb is a Treasury initiative, and its goal is to generate datasets of long-term scientific relevance. 

Treasury Programs aim to address a variety of scientific questions with a single, consistent dataset. 

Data obtained via a Treasury Program typically does not have an exclusive access period, allowing other researchers to analyze it right away. 

• "As a Treasury Program, you agree to release your data and data products to the community as soon as possible," Kartaltepe said. 

• "We're going to create this community resource and make it publicly accessible so that other scientists may utilize it in their research." 

• "A Treasury Program commits to making all of these scientific products publicly accessible so that anybody in the community, even at very tiny universities, may have the same, equal access to the data products and then simply conduct the work," Koekemoer said. 

COSMOS-Webb is a General Observers program in Cycle 1. 

• The General Observers programs were chosen via a competitive process utilizing a dual-anonymous review mechanism, similar to the one used to distribute Hubble time. 

• When it launches in 2021, the James Webb Space Telescope will be the world's top space scientific observatory. 

• Webb will explore beyond our solar system to distant planets orbiting other stars, as well as the enigmatic architecture and origins of our universe and our role in it. 

• Webb is a NASA-led multinational project involving ESA (European Space Agency) and the Canadian Space Agency as partners.

courtesy www.nasa.com

~ Jai Krishna Ponnappan

You may also want to read more about space based systems here.

Quantum Computers A Step Closer To Reality

Engineers make a significant advancement in the design of quantum computers. 

A significant roadblock to quantum computers becoming a reality has been overcome thanks to quantum engineers from UNSW Sydney. 

• They developed a novel method that they claim would allow them to manage millions of spin qubits—the fundamental units of information in a silicon quantum processor. 

• Until far, quantum computer engineers and scientists have only been able to demonstrate the control of a few qubits in a proof-of-concept model of quantum processors. 

• However, the team has discovered what they call "the missing jigsaw piece" in the quantum computer design, which should allow them to manage the millions of qubits required for very complicated computations, according to their new study, which was published today in Science Advances. 

• Dr. Jarryd Pla, a professor at UNSW's School of Electrical Engineering and Telecommunications, says his research group wanted to solve a problem that had plagued quantum computer scientists for decades: how to control millions of qubits without taking up valuable space with additional wiring, which consumes more electricity and generates more heat. 

"Controlling electron spin qubits depended on our providing microwave magnetic fields by sending a current through a wire directly near the qubit up to this point," Dr. Pla explains. 

• "If we want to scale up to the millions of qubits that a quantum computer would require to tackle globally important issues like the creation of new vaccines, this presents some serious difficulties." 

• To begin with, magnetic fields diminish rapidly with distance, so we can only control the qubits that are nearest to the wire. 

• As we brought in more and more qubits, we'd need to add more and more wires, which would take up a lot of space on the chip." 

• And, since the device must function at temperatures below -270°C, Dr. Pla claims that adding additional wires will create much too much heat in the chip, jeopardizing the qubits' stability. 

• "With this wiring method, we're only able to manage a few qubits," Dr. Pla explains. 

A thorough rethinking of the silicon chip structure was required to solve this issue. 

• Rather of putting thousands of control lines on a tiny silicon device with millions of qubits, the researchers investigated the possibility of using a magnetic field generated from above the chip to operate all of the qubits at the same time. 

• The concept of controlling all qubits at the same time was originally proposed by quantum computing experts in the 1990s, but until today, no one had figured out how to accomplish it in a practical manner. 

• "After removing the cable adjacent to the qubits, we devised a new method for delivering microwave-frequency magnetic control fields throughout the device. In theory, we could send control fields to as many as four million qubits "Dr. Pla agrees. 

A crystal prism termed a dielectric resonator was inserted immediately above the silicon chip by Dr. Pla and his colleagues. 

• When microwaves are directed into a resonator, the wavelength of the microwaves is reduced dramatically. 

• "Because the dielectric resonator reduces the wavelength to less than one millimeter, we now have a highly effective conversion of microwave power into the magnetic field that controls all of the qubits' spins." 

• The first is that we don't need a lot of power to create a strong driving field for the qubits, which means we don't produce a lot of heat. 

• The second is that the field is very consistent throughout the device, ensuring that millions of qubits have the same degree of control." Despite the fact that Dr. 

Pla and his team had created a prototype resonator technology, they lacked the silicon qubits with which to test it. 

• So he spoke to his UNSW engineering colleague, Scientia Professor Andrew Dzurak, whose team had proven the earliest and most precise quantum logic utilizing the same silicon fabrication process as traditional computer chips during the previous decade. 

• "When Jarryd presented me with his new concept, I was absolutely blown away," Prof. Dzurak recalls, "and we immediately went to work to see how we might combine it with the qubit devices that my team has created." Ensar Vahapoglu from my team and James Slack-Smith from Jarryd's were assigned to the project as two of our top Ph.D. students. 

"When the experiment turned out to be a success, we were ecstatic. This issue of controlling millions of qubits had been bothering me for a long time, since it was a significant stumbling block in the development of a full-scale quantum computer." 

• Quantum computers with thousands of qubits to address business issues, which were once just a pipe dream in the 1980s, may now be less than a decade away. 

• In addition, due of their capacity to simulate very complex systems, they are anticipated to offer fresh firepower to addressing global problems and creating new technologies. 

Quantum computing technology has the potential to help climate change, medicine and vaccine development, code decryption, and artificial intelligence. 

• The team's next goal is to utilize this new technique to make designing near-term silicon quantum computers easier. 

• "The on-chip control wire is removed, making room for more qubits and the rest of the components needed to create a quantum processor. 

• It simplifies the job of moving on to the next stage of manufacturing devices with tens of qubits "Prof. Dzurak agrees. 

• "While there are still technical hurdles to overcome before computers with a million qubits can be built," Dr. Pla adds, "we are thrilled that we now have a method to manage them."

~ Jai Krishna Ponnappan

You may also want to read more about Quantum Computing here.