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mass–energy equivalence

mass–energy equivalence

noun

the principle that energy and mass, even though existing as different forms, are interchangeable forms of the same physical quantity, as represented by Einstein's signature equation, E = mc², in which E is energy, m is mass, and c is the speed of light.
mass-energy equivalence

mass-energy equivalence

An equation derived from Einstein's theory of Special Relativity expressing the relationship between the mass and energy of objects with mass. The equation is E = mc ², where E is the energy of the object in joules, m is its relativistic mass in kilograms, and c is the speed of light (approximately 3 × 10 ⁸ meters per second). Mass-energy equivalence entails that the total mass of a system may change, although the total energy and momentum remain constant; for example, the collision of an electron and a proton annihilates the mass of both particles, but creates energy in the form of photons. The discovery of mass-energy equivalence was essential to the development of theories of atomic fission and fusion reactions.

mass–energy equivalence

American

noun

Physics.

the principle that energy and mass, even though existing as different forms, are interchangeable forms of the same physical quantity, as represented by Einstein's signature equation, E = mc², in which E is energy, m is mass, and c is the speed of light.

mass-energy equivalence Scientific

An equation derived from Einstein's theory of Special Relativity expressing the relationship between the mass and energy of objects with mass. The equation is E = mc ², where E is the energy of the object in joules, m is its relativistic mass in kilograms, and c is the speed of light (approximately 3 × 10 ⁸ meters per second). Mass-energy equivalence entails that the total mass of a system may change, although the total energy and momentum remain constant; for example, the collision of an electron and a proton annihilates the mass of both particles, but creates energy in the form of photons. The discovery of mass-energy equivalence was essential to the development of theories of atomic fission and fusion reactions.

Example Sentences

Examples are provided to illustrate real-world usage of words in context. Any opinions expressed do not reflect the views of Dictionary.com.

The conversion between mass and energy is most identifiably represented by the mass-energy equivalence equation as stated by Albert Einstein:

From Textbooks • Feb. 14, 2019

Determine the binding energy in joules per nuclide using the mass-energy equivalence equation.

From Textbooks • Feb. 14, 2019

We next calculate the binding energy for one nucleus from the mass defect using the mass-energy equivalence equation:

From Textbooks • Feb. 14, 2019

This “missing” mass is the mass defect, which has been converted into the binding energy that holds the nucleus together according to Einstein’s mass-energy equivalence equation, E = mc2.

From Textbooks • Feb. 14, 2019

Substituting this quantity into the mass-energy equivalence equation yields:

From Textbooks • Feb. 14, 2019

Definitions and idiom definitions from Dictionary.com Unabridged, based on the Random House Unabridged Dictionary, © Random House, Inc. 2023