Explore: Équation Dirac
Discover books, insights, and more — all in one place.
Learn more about Équation Dirac with top reads curated from trusted sources — all in one place.
AI-Generated Overview About “%C3%A9quation-dirac”:
Books Results
Source: The Open Library
The Open Library Search Results
Search results from The Open Library
1Symmetries of Maxwell's equations
By V. I. Fushchich
“Symmetries of Maxwell's equations” Metadata:
- Title: ➤ Symmetries of Maxwell's equations
- Author: V. I. Fushchich
- Languages: rus - English
- Number of Pages: Median: 214
- Publisher: D. Reidel
- Publish Date: 1987
- Publish Location: Dordrecht - Lancaster
“Symmetries of Maxwell's equations” Subjects and Themes:
- Subjects: ➤ Maxwell equations - Équation Dirac - Opérateur symétrique - Maxwell, Équations de - Symmetric operators - Dirac equation - Dirac, équations de - Algèbre Poincaré - Mathematical physics - Équation Maxwell - Physique mathématique - Symétrie - Symmetric functions
Edition Identifiers:
- The Open Library ID: OL22604119M
- Online Computer Library Center (OCLC) ID: 15520250
- Library of Congress Control Number (LCCN): 87009526
- All ISBNs: 9027723206 - 9789027723208
Access and General Info:
- First Year Published: 1987
- Is Full Text Available: No
- Is The Book Public: No
- Access Status: No_ebook
Online Marketplaces
Find Symmetries of Maxwell's equations at online marketplaces:
- Amazon: Audiable, Kindle and printed editions.
- Ebay: New & used books.
Wiki
Source: Wikipedia
Wikipedia Results
Search Results from Wikipedia
Dirac equation
In particle physics, the Dirac equation is a relativistic wave equation derived by British physicist Paul Dirac in 1928. In its free form, or including
Paul Dirac
the Dirac equation in 1928. It connected special relativity and quantum mechanics and predicted the existence of antimatter. The Dirac equation is one
Dirac–Kähler equation
physics, the Dirac–Kähler equation, also known as the Ivanenko–Landau–Kähler equation, is the geometric analogue of the Dirac equation that can be defined
Relativistic wave equations
comfortable with the "Dirac sea" of negative energy states). The natural problem became clear: to generalize the Dirac equation to particles with any
Schrödinger equation
turn introducing Dirac matrices. In a modern context, the Klein–Gordon equation describes spin-less particles, while the Dirac equation describes spin-1/2
Dirac sea
physicist Paul Dirac in 1930 to explain the anomalous negative-energy quantum states predicted by the relativistically-correct Dirac equation for electrons
Dirac delta function
In mathematical analysis, the Dirac delta function (or δ distribution), also known as the unit impulse, is a generalized function on the real numbers
Pauli equation
external electromagnetic field. It is the non-relativistic limit of the Dirac equation and can be used where particles are moving at speeds much less than
List of equations
Functional equation Functional equation (L-function) Constitutive equation Laws of science Defining equation (physical chemistry) List of equations in classical
Dirac equation in curved spacetime
In mathematical physics, the Dirac equation in curved spacetime is a generalization of the Dirac equation from flat spacetime (Minkowski space) to curved