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Quantum Computing and Blockchain in Business

You're reading from   Quantum Computing and Blockchain in Business Exploring the applications, challenges, and collision of quantum computing and blockchain

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Product type Paperback
Published in Mar 2020
Publisher Packt
ISBN-13 9781838647766
Length 334 pages
Edition 1st Edition
Languages
Concepts
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Author (1):
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Arunkumar Krishnakumar Arunkumar Krishnakumar
Author Profile Icon Arunkumar Krishnakumar
Arunkumar Krishnakumar
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Table of Contents (20) Chapters Close

Preface 1. Introduction to Quantum Computing and Blockchain 2. Quantum Computing – Key Discussion Points FREE CHAPTER 3. The Data Economy 4. The Impact on Financial Services 5. Interview with Dr. Dave Snelling, Fujitsu Fellow 6. The Impact on Healthcare and Pharma 7. Interview with Dr. B. Rajathilagam, Head of AI Research, Amrita Vishwa Vidyapeetham 8. The Impact on Governance 9. Interview with Max Henderson, Senior Data Scientist, Rigetti and QxBranch 10. The Impact on Smart Cities and Environment 11. Interview with Sam McArdle, Quantum Computing Researcher at the University of Oxford 12. The Impact on Chemistry 13. The Impact on Logistics 14. Interview with Dinesh Nagarajan, Partner, IBM 15. Quantum-Safe Blockchain 16. Nation States and Cyberwars 17. Conclusion – Blue Skies 18. Other Books You May Enjoy
19. Index

The weirdness of quantum

Before we explore quantum computing, it would be good to understand the behavior of particles as described by quantum mechanics. Below, I describe an experiment that helps us to understand the counter-intuitive nature of quantum theory.

A scary experiment

The famous Quantum Slit experiment describes the behavior of photons/particles and how they interact with each other and themselves. As we will see, this posed a challenge to physicists attempting to describe their behavior.

In the 19th century, a British scientist, Thomas Young, postulated that light particles traveled in waves, rather than as particles. He set up a simple experiment where he cut two slits on a piece of metal and placed it as a blocker between a light source and a screen. He knew that if light traveled in the same manner as particles, then the particles that passed through the slits would hit the screen. Those that were blocked by the metal would bounce off the surface and would not reach the screen. Effectively, if the light was made of particles, then the screen should look like a spray of paint on a stencil. Figure 1 shows the experiment and the slit formation.

However, he assumed (before the experiment) that light was formed of waves, and the waves, when they passed through the slit, would interfere with one another and form patterns on the screen. The pattern would be defined based on how the waves passing through the slits interacted.

Where the waves interfered with each other (called constructive interference), the screen would display bright spots, and where peaks interfered with troughs (called destructive interference), they would form dark spots. Hence, the pattern would be slit shapes at the center followed by progressively darker slit shapes to the left and the right. Young successfully proved that light traveled in waves.

Figure 1: Young's double slit experiment

Einstein's photons – weirder now

Albert Einstein once more proved to be of great influence in the field of quantum mechanics. He proposed that light was made of photons – a discrete quantum of light that behaved like a particle. As a result, the experiment was repeated and this time, photons were passed through the slit one by one and the patterns still appeared. This could only happen if:

  • Photons travelled in waveforms.
  • All possible paths of these waveforms interfered with each other, even though only one of these paths could happen.

This supports the theory that all realities exist until the result is observed, and that subatomic particles can exist in superposition. As detectors were placed to observe photons passing through the slits, the patterns disappeared. This act of observation of particles collapses the realities into one.

We have discussed the three principles of quantum mechanics: superposition, entanglement, and interference. These principles are fundamental to the way in which particles are managed within a quantum computer.

Figure 2: A quantum computing timeline

The history of quantum computing and the key milestones are captured in Figure 2. The key takeaway is the contributions made to the field that have brought this technology to the brink of achieving impact at scale.

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