History

Mathematical Formulations

Reduced Planck’s Constant

Planck’s Constant Value

Applications

Planck Constant and the Photoelectric Effect

On the basis of his work on this, Planck formulated a law, known as Planck’s radiation law that describes the spectral energy distribution of the electromagnetic radiation emitted by a black body at a definite temperature. Planck also determined the value of the Boltzmann constant from this derivation. E=hʋ                                                                                                                                     —(i) This is an extremely small amount of energy. Now, the wavelength λ, frequency ʋ, and the speed of light c are connected by the following formula. ʋ= Therefore, the Planck-Einstein relation can be rewritten as, E= This is another equation involving Planck’s constant. Now the de Broglie wavelength of any particle is associated with its linear momentum p by Planck’s constant as given by the below equation. λ= ħ= Since ω=2πʋ, therefore the energy of a photon with angular frequency ω is given by, E=ħω Utilizing equation (i). On the other hand, the linear momentum p can be expressed as, p=ħk Where k is the wavenumber or the spatial frequency of the wave. It is the number of waves that reside over a particular distance. In 1923, the Planck-Einstein relationship was generalized by French physicist and Nobel laureate Louis de Broglie. According to him, not only light but all matter could exhibit wave-like behavior, following the concept of wave-particle duality. Hence, Planck’s constant holds good for not only the quantum wavelength of photons but also that of any particle. This postulate, verified by experiments soon after, is valid throughout the quantum theory. It implies that the dynamics of any physical system cannot take any arbitrary value.  It should be a multiple of a very small value, better known as the “quantum of action” or Planck’s constant. This, in turn, goes on to explain why in many cases, such as for atoms or monochromatic light, only certain energy levels are allowed, and the intermediary levels are forbidden. Heisenberg’s Uncertainty Principle states that the momentum and the position of a particle cannot be simultaneously measured with high accuracy. It relies on Planck’s constant for its probabilistic calculations. The said constant determines the size of the confined area that can be produced by the fundamental forces to contain any particle within it. Time and energy also follow this rule. The reduced Planck’s constant is one of the four fundamental constants in the Hartree system of atomic units. It represents the dimension of action with a numerical value equal to unity by definition. The International Committee for Weights and Measures has proposed to redefine the standard kilogram in terms of Planck’s constant, owing to its invariant nature. This attempt to derive the definition of kilogram from entirely natural sources takes the help of Einstein’s mass-energy equivalence relation (E=mc2) along with the equation (i) cited above. The watt balance has been employed to give such an alternative definition. The instrument can accurately measure the mass of an object by the voltage and strength of an electric current. The expression for the Rydberg constant associated with atomic spectra contains h. According to him, light energy is not transferred as a continuous wave but as packets of energy or quanta which are the same as the energy elements mentioned by Max Planck in his theory. The kinetic energy of the photoelectrons (E) is directly proportional to the frequency of the incident light (f), the constant of proportionality being nothing else but Planck’s constant. This postulate which was later verified experimentally gave way to the modern version of the Planck-Einstein relation. E=hf He received the Nobel Prize in Physics in 1921 for his work. The work function for a particular metal, when substituted in the photoelectric equation, also allows the determination of Planck’s constant. The photoelectric equation is hf=ɸ + Ek where f is the frequency of the incident light, ɸ is the work function, and Ek is the maximum kinetic energy of the photoelectrons. The work function of a metal is the minimum energy required to emit an electron from a surface. Other than the multitude of significances cited above, it has provided scientists with an interesting and expanding research area. It has made theoretical physicists wonder what if the constant became zero at some point in time and space. What would be the consequences. Would it imply obvious destruction of quantization, giving rise to a continuous distribution of energy. Then, at that point, quantum Physics would give way to classical Physics, defining the classical limit. With Planck’s constant, the possibilities are endless. There could be more to come in the near future. https://physics.nist.gov/cgi-bin/cuu/Value?h http://hyperphysics.phy-astr.gsu.edu/hbase/uncer.html https://www.nist.gov/si-redefinition/kilogram/nist-do-it-yourself-kibble-balance