advanced_tools:group_theory:poincare_group
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advanced_tools:group_theory:poincare_group [2018/03/21 11:25] jakobadmin [Researcher] |
advanced_tools:group_theory:poincare_group [2020/09/07 06:41] (current) 14.161.7.200 [Why is it interesting?] |
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| - | ====== Poincare Group $ \quad \color{red}{P(1, 3)} = \color{blue}{T(4)} \color{magenta}{\rtimes} \color{green}{SO(1, 3)}$ ====== | + | <WRAP>$ \color{red}{P(1, 3)} = \color{blue}{T(4)} \color{magenta}{\rtimes} \color{green}{SO(1, 3)}$ </WRAP> |
| + | ====== Poincare Group ====== | ||
| - | <tabbox Why is it interesting?> | ||
| - | The double cover of the Poincare group is the fundamental spacetime symmetry of modern physics and is a crucial component of the [[models:standard_model|standard model of particle physics]]. | ||
| - | The Poincare group is the set of all transformations that leave the speed of light invariant. Thus, the Poincare group yields all possible transformations between allowed frames of reference. This is incredibly useful, when we want to write down fundamental laws of nature. The fundamental laws should be valid in all allowed frames of reference, otherwise they would be quite useless. | + | <tabbox Intuitive> |
| - | In practice, we can use our knowledge of all transformations inside the Poincare group to write down equations that are invariant under all these transformations. These equations then hold in all allowed frames of reference. This is such a strong restriction on the possible equations that is is almost enough to derive the most important equations of fundamental physics: the Dirac equation, the Klein-Gordon equation and the Maxwell-Equations. | + | The Poincare [[advanced_tools:group_theory|group]] is the mathematical tool that we use to describe the [[basic_tools:symmetry|symmetry]] of [[models:special_relativity|special relativity]]. |
| - | <blockquote>"//The Hilbert space of one-particle states is always an irreducible | + | The starting point for Einstein on his road towards what is now called special relativity was the experimental observation that the speed of light has the same value in all inertial frames of reference. This curious fact of nature was discovered by the famous [[experiments:michelson_morley|Michelson-Morley experiment]]. |
| - | representation space of the Poincare group. [...] **The construction of the unitary irreducible representations | + | |
| - | of the Poincare group is probably the most successful part of special | + | A symmetry is a transformation that we can perform without changing something. Therefore, the invariance of the speed of light under arbitrary changes of the frame of reference is a symmetry and we call this symmetry the Poincare group. The Poincare group contains all transformations that we can perform without changing the speed of light. |
| - | relativity** (in particle physics, not in gravitation theory, for which it is a | + | |
| - | disaster). **It permits us to classify all kinds of particles and implies the main | + | |
| - | conservation laws (energy-momentum and angular momentum)**. [...] The translation generators are | + | |
| - | responsible for the energy-momentum conservation laws, the rotation generators | + | |
| - | of the conservation of angular momentum, and the boost generators | + | |
| - | of the conservation of initial position. //" from Reflections on the Evolution of Physical Theories by Henri Bacry</blockquote> | + | |
| - | <blockquote>"//The enlargement of the Lorentz group to the Poincare group was proposed [ 13] as a way of describing the quantum states of relativistic particles without using the wave equations. The states of a free particle are then given by the unitary irreducible representations of the Poincare group.//" from [[http://www.sciencedirect.com/science/article/pii/0370269394001103|Deformed Poincare containing the exact Lorentz algebra]] by Alexandros A. Kehagias et. al.</blockquote> | ||
| - | <tabbox Layman> | ||
| - | <note tip> | ||
| - | Explanations in this section should contain no formulas, but instead colloquial things like you would hear them during a coffee break or at a cocktail party. | ||
| - | </note> | ||
| | | ||
| - | <tabbox Student> | + | <tabbox Concrete> |
| The $\color{red}{\text{Poincare group}}$ consists of $\color{blue}{\text{translations}}$ $\color{magenta}{\text{plus}}$ $\color{green}{\text{rotations and boosts}}$. | The $\color{red}{\text{Poincare group}}$ consists of $\color{blue}{\text{translations}}$ $\color{magenta}{\text{plus}}$ $\color{green}{\text{rotations and boosts}}$. | ||
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| - | <tabbox Researcher> | + | <tabbox Abstract> |
| * For a modern discussion of the Poincare group, see D. Giulini, The Poincare group: Algebraic, representation-theoretic, and geometric | * For a modern discussion of the Poincare group, see D. Giulini, The Poincare group: Algebraic, representation-theoretic, and geometric | ||
| aspects. | aspects. | ||
| + | <tabbox Why is it interesting?> | ||
| + | The double cover of the Poincare group is the fundamental spacetime symmetry of modern physics and is a crucial component of the [[models:standard_model|standard model of particle physics]]. | ||
| + | The Poincare group is the set of all transformations that leave the speed of light invariant. Thus, the Poincare group yields all possible transformations between allowed frames of reference. This is incredibly useful, when we want to write down fundamental laws of nature. The fundamental laws should be valid in all allowed frames of reference, otherwise they would be quite useless. | ||
| + | |||
| + | In practice, we can use our knowledge of all transformations inside the Poincare group to write down equations that are invariant under all these transformations. These equations then hold in all allowed frames of reference. This is such a strong restriction on the possible equations that is almost enough to derive the most important equations of fundamental physics: the Dirac equation, the Klein-Gordon equation and the Maxwell-Equations. | ||
| + | |||
| + | <blockquote>"//The Hilbert space of one-particle states is always an irreducible | ||
| + | representation space of the Poincare group. [...] **The construction of the unitary irreducible representations | ||
| + | of the Poincare group is probably the most successful part of special | ||
| + | relativity** (in particle physics, not in gravitation theory, for which it is a | ||
| + | disaster). **It permits us to classify all kinds of particles and implies the main | ||
| + | conservation laws (energy-momentum and angular momentum)**. [...] The translation generators are | ||
| + | responsible for the energy-momentum conservation laws, the rotation generators | ||
| + | of the conservation of angular momentum, and the boost generators | ||
| + | of the conservation of initial position. //" from Reflections on the Evolution of Physical Theories by Henri Bacry</blockquote> | ||
| + | |||
| + | <blockquote>"//The enlargement of the Lorentz group to the Poincare group was proposed [ 13] as a way of describing the quantum states of relativistic particles without using the wave equations. The states of a free particle are then given by the unitary irreducible representations of the Poincare group.//" from [[http://www.sciencedirect.com/science/article/pii/0370269394001103|Deformed Poincare containing the exact Lorentz algebra]] by Alexandros A. Kehagias et. al.</blockquote> | ||
| | | ||
| - | <tabbox History> | + | <tabbox FAQ> |
| + | |||
| + | -->Why do we say that irreducible representation of Poincare group represents the one-particle state?# | ||
| + | |||
| + | see https://physics.stackexchange.com/questions/73593/why-do-we-say-that-irreducible-representation-of-poincare-group-represents-the-o | ||
| + | |||
| + | and also https://physics.stackexchange.com/questions/21801/identification-of-the-state-of-particle-types-with-representations-of-poincare-g | ||
| + | <-- | ||
| </tabbox> | </tabbox> | ||
advanced_tools/group_theory/poincare_group.1521627914.txt.gz · Last modified: 2018/03/21 10:25 (external edit)
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