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The application of quantum theory to the interaction between electrons and radiation requires a quantum treatment of Maxwell’s field equations, which are the foundations of electromagnetism, and the relativistic theory of the electron formulated by Dirac (see above Electron spin and antiparticles). The resulting quantum field theory is known as quantum electrodynamics, or QED.
QED accounts for the behaviour and interactions of electrons, positrons, and photons. It deals with processes involving the creation of material particles from electromagnetic energy and with the converse processes in which a material particle and its antiparticle annihilate each other and produce energy. Initially the theory was beset with formidable mathematical difficulties, because the calculated values of quantities such as the charge and mass of the electron proved to be infinite. However, an ingenious set of techniques developed (in the late 1940s) by Hans Bethe, Julian S. Schwinger, Tomonaga Shin’ichirō, Richard P. Feynman, and others dealt systematically with the infinities to obtain finite values of the physical quantities. Their method is known as renormalization. The theory has provided some remarkably accurate predictions.
According to the Dirac theory, two particular states in hydrogen with different quantum numbers have the same energy. QED, however, predicts a small difference in their energies; the difference may be determined by measuring the frequency of the electromagnetic radiation that produces transitions between the two states. This effect was first measured by Willis E. Lamb, Jr., and Robert Retherford in 1947. Its physical origin lies in the interaction of the electron with the random fluctuations in the surrounding electromagnetic field. These fluctuations, which exist even in the absence of an applied field, are a quantum phenomenon. The accuracy of experiment and theory in this area may be gauged by two recent values for the separation of the two states, expressed in terms of the frequency of the radiation that produces the transitions:
Quantum Electrodynamics | Modern Physics for IIT JAM
An even more spectacular example of the success of QED is provided by the value for μe, the magnetic dipole moment of the free electron. Because the electron is spinning and has electric charge, it behaves like a tiny magnet, the strength of which is expressed by the value of μe. According to the Dirac theory, μe is exactly equal to μB = eℏ/2me, a quantity known as the Bohr magneton; however, QED predicts that μe = (1 + a)μB, where a is a small number, approximately 1/860. Again, the physical origin of the QED correction is the interaction of the electron with random oscillations in the surrounding electromagnetic field. The best experimental determination of μe involves measuring not the quantity itself but the small correction term μe − μB. This greatly enhances the sensitivity of the experiment. The most recent results for the value of a are
Quantum Electrodynamics | Modern Physics for IIT JAM
Since a itself represents a small correction term, the magnetic dipole moment of the electron is measured with an accuracy of about one part in 1011. One of the most precisely determined quantities in physics, the magnetic dipole moment of the electron can be calculated correctly from quantum theory to within about one part in 1010.

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FAQs on Quantum Electrodynamics - Modern Physics for IIT JAM

1. What is quantum electrodynamics (QED)?
Ans. Quantum electrodynamics (QED) is a quantum field theory that describes the interaction between electromagnetic radiation (light) and charged particles. It combines quantum mechanics with classical electrodynamics, providing a framework to understand and calculate various phenomena involving light and charged particles at the fundamental level.
2. How does quantum electrodynamics explain the behavior of electrons and photons?
Ans. Quantum electrodynamics explains the behavior of electrons and photons by treating them as quantum particles. Electrons are described as matter particles, while photons are described as force-carrying particles of light. QED mathematically formulates the interaction between these particles through the exchange of virtual photons, allowing for the calculation of probabilities and amplitudes of various processes, such as scattering and emission.
3. What are the key principles of quantum electrodynamics?
Ans. The key principles of quantum electrodynamics include: - The quantization of electromagnetic fields: QED treats the electromagnetic field as a collection of quantized particles (photons) that can be created or annihilated. - The Dirac equation: QED incorporates the Dirac equation, which describes the behavior of electrons as relativistic quantum particles. - Gauge symmetry: QED is symmetric under certain transformations, known as gauge transformations, ensuring the conservation of electric charge and electromagnetic interactions.
4. How is quantum electrodynamics experimentally validated?
Ans. Quantum electrodynamics has been experimentally validated through various high-precision experiments. One notable example is the measurement of the electron's magnetic moment, which has been found to agree with QED predictions to an extraordinary level of precision. Other experiments, such as electron-positron scattering and the Lamb shift, have also provided strong support for the predictions of QED.
5. What are the applications of quantum electrodynamics?
Ans. Quantum electrodynamics has numerous applications in modern physics. It is essential for understanding the behavior of electrons and photons in particle accelerators, such as the Large Hadron Collider (LHC). QED also plays a crucial role in the development of technologies like lasers, quantum computing, and advanced materials. Additionally, it provides a foundation for other quantum field theories, such as quantum chromodynamics (QCD) and the electroweak theory.
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