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Werner Heisenberg considered the limits of how accurately one can measure properties of an electron or other microscopic particles. He determined that there is a fundamental limit to how accurately one can measure both a particle’s position and its momentum simultaneously. The more accurate the measurement of the momentum of a particle is known, the less accurate the position at that time is known and vice versa. This is what is now called the Heisenberg uncertainty principle. He...
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Shortly after de Broglie published his ideas that the electron in a hydrogen atom could be better thought of as being a circular standing wave instead of a particle moving in quantized circular orbits, Erwin Schrödinger extended de Broglie’s work by deriving what is now known as the Schrödinger equation. When Schrödinger applied his equation to hydrogen-like atoms, he was able to reproduce Bohr’s expression for the energy and, thus, the Rydberg formula governing hydrogen spectra.
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Fundamental Theorem of Algebra01:30

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The Fundamental Theorem of Algebra is central to the study of polynomial equations, asserting that every non-constant polynomial with complex coefficients has at least one complex zero. This means that a polynomial of degree n ≥ 1, written as:  with an ≠ 0, has at least one solution in the complex number system. Since the set of real numbers is a subset of complex numbers, this theorem applies equally to polynomials with real coefficients.Building on this result, the...
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Propagation of Uncertainty from Random Error00:59

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An experiment often consists of more than a single step. In this case, measurements at each step give rise to uncertainty. Because the measurements occur in successive steps, the uncertainty in one step necessarily contributes to that in the subsequent step. As we perform statistical analysis on these types of experiments, we must learn to account for the propagation of uncertainty from one step to the next. The propagation of uncertainty depends on the type of arithmetic operation performed on...
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Propagation of Uncertainty from Systematic Error01:10

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The atomic mass of an element varies due to the relative ratio of its isotopes. A sample's relative proportion of oxygen isotopes influences its average atomic mass. For instance, if we were to measure the atomic mass of oxygen from a sample, the mass would be a weighted average of the isotopic masses of oxygen in that sample. Since a single sample is not likely to perfectly reflect the true atomic mass of oxygen for all the molecules of oxygen on Earth, the mass we obtain from this...
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Norton's Theorem01:14

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Norton's theorem is a fundamental principle stating that a linear two-terminal circuit can be substituted with an equivalent circuit, which comprises a current source (ⅠN) in parallel with a resistor (RN). Here, ⅠN represents the short-circuit current flowing through the terminals, and RN stands for the input or equivalent resistance at the terminals when all independent sources are deactivated. This implies that the circuit illustrated in Figure (a) can be exchanged with the one depicted...
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Related Experiment Video

Updated: Nov 27, 2025

Quantum State Engineering of Light with Continuous-wave Optical Parametric Oscillators
09:23

Quantum State Engineering of Light with Continuous-wave Optical Parametric Oscillators

Published on: May 30, 2014

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An Information-Theoretic Perspective on the Quantum Bit Commitment Impossibility Theorem.

Marius Nagy1,2, Naya Nagy3

  • 1College of Computer Engineering and Science, Prince Mohammad Bin Fahd University, Al Khobar 31952, Saudi Arabia.

Entropy (Basel, Switzerland)
|December 3, 2020
PubMed
Summary
This summary is machine-generated.

Unconditionally secure quantum bit commitment is impossible. Cheating requires specific quantum uncertainty and entanglement, influenced by information leakage between participants.

Keywords:
bit commitmententanglemententropyprotocolquantum information theory

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Area of Science:

  • Quantum Information Theory
  • Quantum Cryptography

Background:

  • Quantum bit commitment is a cryptographic primitive essential for secure quantum communication.
  • Mayers' no-go theorem proves the impossibility of unconditionally secure quantum bit commitment.
  • Existing proofs focus on technical details, leaving room for alternative perspectives.

Purpose of the Study:

  • To explore alternative approaches to understanding the impossibility of quantum bit commitment.
  • To investigate the role of quantum entropy in circumventing security properties.
  • To identify the fundamental conditions enabling cheating in quantum bit commitment protocols.

Main Methods:

  • Utilizing quantum entropy analysis to probe security conditions.
  • Examining the relationship between uncertainty, entanglement, and cheating strategies.
  • Analyzing information leakage and hidden information within quantum systems.

Main Results:

  • Cheating the binding property necessitates equal uncertainty for both observers and the use of entanglement.
  • The ability to cheat depends on the degree of information leakage and hidden information.
  • Quantum entropy provides a framework for understanding the limitations of quantum bit commitment.

Conclusions:

  • Quantum bit commitment's security is fundamentally limited by information-theoretic principles.
  • Entanglement and observer-dependent uncertainty are key factors in protocol vulnerabilities.
  • Further research into quantum entropy can illuminate the boundaries of secure quantum protocols.