A Quantum Computing Renaissance

Volume 4 | Issue 7 | July 2024

Cosmology of Light Newsletter

Hello Friends,

The study of history suggests that renaissance requires multiple sources of inspiration that can equally become anchors for varied and harmonious development. The quantum computing industry, albeit young, is in need of additional sources of 'conceptual' inspiration so that a true renaissance may result. The quantum realm, after all, is that which separates the invisible from the visible and there has to be multiple ways to penetrate and leverage the possibilities that lie behind the surface.

It is in this vein that I share a recent Forbes article in which I highlight 15 unconsidered quantum computational opportunities. These can be seen to originate from interpreting the famed double-slit experiment from the 'top-down' as opposed to the 'bottom-up'. I also share a keynote address delivered at Namibia University of Science & Technology that emphasizes an unconsidered piece of the quantum puzzle. Finally, I am glad to note that I am continuing with a second 1-year term as the Forbes Technology Council quantum computing group leader.

Warmly,

Pravir

Driving a Quantum Computing Renaissance

Earlier this year I penned a brief research article - Leveraging the Double-Slit Experiment in Explore New Horizons for Quantum Computation - for the International Journal of Systems-Science & Technology based on a keynote that I delivered at Cambridge University in March this year. In viewing the action of photons based on 'function' related to Light it is possible to derive additional pathways for quantum computation, and I share a Forbes event - From the Near to the Far - in which I trace out additional trajectories of computing development. As a result of these trajectories unconsidered quantum computational opportunities arise.

Here I list a few from a set of 15 extracted from a recent Forbes article - investing in the Quantum Revolution: Key Opportunities for a Computing Renaissance.

Explore the concept of atoms as quantum computers: Investigate how atoms process and maintain genetic-type codes and how this inherent quantum computation contributes to the stability and functionality of living cells.
Augment traditional quantum computing models: Shift focus from traditional models to those that utilize the inherent "quantum computation" abilities of atoms.
Investigate quantum functional languages: Research the development of a new quantum-level language that is based on the function of atoms rather than just their form or number.
Explore the concept of integrated quantum computational intelligence (IQCI): Delve deeper into the theory that everything functions as a quantum computer, continually processing and evolving codes, implying inherent intelligence at the quantum level.
Investigate quantum intelligence: Research and understand how quantum intelligence manifests and evolves within complex natural quantum systems.
Shift the paradigm of quantum mechanics: Embrace a new understanding of quantum mechanics that goes beyond current qubit-based models, focusing on the integration of quantum intelligence.
Develop IQCI-based nano-cyborgs: Research and design nano-scale cyborgs that utilize quantum computational intelligence (IQCI).
Revolutionize energy sources: Explore the potential of IQCI-based nano-cyborgs to revolutionize energy sources by tapping into fundamental quantum patterns that repeat themselves in varying forms at the level of matter and life.

An Unconsidered Piece of the Quantum Puzzle

On July 24 I delivered a keynote address at the IEEE Conference on Emerging Trends in Networks and Computer Communications organized by the UNESCO Chair on Secure High Performance Computing for Higher Education and Research, Namibia University of Science & Technology, Windhoek, Namibia.

I spoke about a quaternary interpretation of quantum dynamics in which the quantum realm was approached from the sides of manifest matter and life, and that of antecedent layers of light. This interpretation highlights quantum wholes - atoms, molecules, molecular plans - endowed with innate computational ability driven by fourfold space-time-energy-gravity (aka knowledge-power-presence-harmony) quantum-object code, which serves as a fundamental blueprint for their functionality. I highlighted many implications for technology, particularly in the creation of nano-based Integrated Quantum Computational Intelligence (IQCI) devices, designed to interface directly with the quantum realm. This will significantly impact material science and life sciences by harnessing quantum intelligence inherent in natural systems.

A backup version of the presentation appears below.

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