There are a variety of notations for the d'Alembertian. The most common are the box symbol (Unicode: U+2610☐BALLOT BOX) whose four sides represent the four dimensions of space-time and the box-squared symbol which emphasizes the scalar property through the squared term (much like the Laplacian). In keeping with the triangular notation for the Laplacian, sometimes is used.
Another way to write the d'Alembertian in flat standard coordinates is . This notation is used extensively in quantum field theory, where partial derivatives are usually indexed, so the lack of an index with the squared partial derivative signals the presence of the d'Alembertian.
Sometimes the box symbol is used to represent the four-dimensional Levi-Civita covariant derivative. The symbol is then used to represent the space derivatives, but this is coordinate chart dependent.
Applications
The wave equation for small vibrations is of the form
where u(x, t) is the displacement.
The wave equation for the electromagnetic field in vacuum is
alembert, operator, confused, with, alembert, principle, alembert, equation, special, relativity, electromagnetism, wave, theory, denoted, displaystyle, also, called, alembertian, wave, operator, operator, sometimes, quabla, operator, nabla, symbol, laplace, o. Not to be confused with d Alembert s principle or d Alembert s equation In special relativity electromagnetism and wave theory the d Alembert operator denoted by a box displaystyle Box also called the d Alembertian wave operator box operator or sometimes quabla operator 1 cf nabla symbol is the Laplace operator of Minkowski space The operator is named after French mathematician and physicist Jean le Rond d Alembert In Minkowski space in standard coordinates t x y z it has the form m m h m n n m 1 c 2 2 t 2 2 x 2 2 y 2 2 z 2 1 c 2 2 t 2 2 1 c 2 2 t 2 D displaystyle begin aligned Box amp partial mu partial mu eta mu nu partial nu partial mu frac 1 c 2 frac partial 2 partial t 2 frac partial 2 partial x 2 frac partial 2 partial y 2 frac partial 2 partial z 2 amp frac 1 c 2 partial 2 over partial t 2 nabla 2 frac 1 c 2 partial 2 over partial t 2 Delta end aligned Here 2 D displaystyle nabla 2 Delta is the 3 dimensional Laplacian and hmn is the inverse Minkowski metric with h 00 1 displaystyle eta 00 1 h 11 h 22 h 33 1 displaystyle eta 11 eta 22 eta 33 1 h m n 0 displaystyle eta mu nu 0 for m n displaystyle mu neq nu Note that the m and n summation indices range from 0 to 3 see Einstein notation We have assumed units such that the speed of light c 1 Some authors alternatively use the negative metric signature of with h 00 1 h 11 h 22 h 33 1 displaystyle eta 00 1 eta 11 eta 22 eta 33 1 Lorentz transformations leave the Minkowski metric invariant so the d Alembertian yields a Lorentz scalar The above coordinate expressions remain valid for the standard coordinates in every inertial frame Contents 1 The box symbol and alternate notations 2 Applications 3 Green s function 4 See also 5 References 6 External linksThe box symbol and alternate notations EditThere are a variety of notations for the d Alembertian The most common are the box symbol displaystyle Box Unicode U 2610 BALLOT BOX whose four sides represent the four dimensions of space time and the box squared symbol 2 displaystyle Box 2 which emphasizes the scalar property through the squared term much like the Laplacian In keeping with the triangular notation for the Laplacian sometimes D M displaystyle Delta M is used Another way to write the d Alembertian in flat standard coordinates is 2 displaystyle partial 2 This notation is used extensively in quantum field theory where partial derivatives are usually indexed so the lack of an index with the squared partial derivative signals the presence of the d Alembertian Sometimes the box symbol is used to represent the four dimensional Levi Civita covariant derivative The symbol displaystyle nabla is then used to represent the space derivatives but this is coordinate chart dependent Applications EditThe wave equation for small vibrations is of the form c u x t u t t c 2 u x x 0 displaystyle Box c u left x t right equiv u tt c 2 u xx 0 where u x t is the displacement The wave equation for the electromagnetic field in vacuum is A m 0 displaystyle Box A mu 0 where Am is the electromagnetic four potential in Lorenz gauge The Klein Gordon equation has the form m 2 c 2 ℏ 2 ps 0 displaystyle left Box frac m 2 c 2 hbar 2 right psi 0 Green s function EditThe Green s function G x x displaystyle G left tilde x tilde x right for the d Alembertian is defined by the equation G x x d x x displaystyle Box G left tilde x tilde x right delta left tilde x tilde x right where d x x displaystyle delta left tilde x tilde x right is the multidimensional Dirac delta function and x displaystyle tilde x and x displaystyle tilde x are two points in Minkowski space A special solution is given by the retarded Green s function which corresponds to signal propagation only forward in time 2 G r t 1 4 p r 8 t d t r c displaystyle G left vec r t right frac 1 4 pi r Theta t delta left t frac r c right where 8 displaystyle Theta is the Heaviside step function See also EditFour gradient d Alembert s formula Klein Gordon equation Relativistic heat conduction Ricci calculus Wave equation One way wave equationReferences Edit Theoretische Physik Aufl 2015 ed Berlin Heidelberg 2015 ISBN 978 3 642 54618 1 OCLC 899608232 S Siklos The causal Green s function for the wave equation PDF Retrieved 2 January 2013 External links Edit D Alembert operator Encyclopedia of Mathematics EMS Press 2001 1994 Poincare Henri 1906 Translation On the Dynamics of the Electron July via Wikisource originally printed in Rendiconti del Circolo Matematico di Palermo Weisstein Eric W d Alembertian MathWorld Retrieved from https en wikipedia org w index php title D 27Alembert operator amp oldid 1131251514, wikipedia, wiki, book, books, library,
