Children: Symmetry
Conformal symmetry is a type of symmetry that is invariant under transformations that preserve angles but not necessarily distances. In mathematical terms, a transformation is conformal if it preserves the form of angles between curves at their intersection points. Conformal transformations can include translations, rotations, dilations (scalings), and special transformations such as inversions or more general conformal mappings.
The term "confronted animals" doesn't refer to a widely recognized concept in biology or animal behavior as of my last update. However, it could imply situations where animals encounter each other in a way that leads to direct interactions, which may include aggression, territorial disputes, mating behaviors, or other social interactions. In a broader context, it might refer to scenarios where animals are faced with challenges or threats, whether from other animals, humans, or environmental factors.
Conservation laws are fundamental principles in physics that state certain physical quantities remain constant within a closed system over time. These laws are derived from symmetries in nature and provide crucial insights into the behavior of physical systems. The most well-known conservation laws include: 1. **Conservation of Energy**: The total energy in a closed system remains constant over time. Energy can neither be created nor destroyed but can change forms (e.g., from kinetic to potential energy).
In physics, particularly in the context of field theory and particle physics, a "conserved current" refers to a current that is associated with a conserved quantity in a dynamical system. This concept is heavily rooted in the principles of symmetry, notably through Noether's theorem, which connects symmetries of the action of a physical system to conserved quantities.
Continuous symmetry refers to a type of symmetry that can change smoothly over a range of values, rather than being limited to discrete, specific configurations. In mathematical terms, a system exhibits continuous symmetry if there is a continuous group of transformations (often associated with a Lie group) that leave the system invariant. For example, consider the rotation of a circle.
Coxeter notation is a way of representing regular polytopes and their higher-dimensional analogs (such as regular polygons, polyhedra, and polychora) using a system based on pairs of numbers. It employs a compact notation that often consists of a string of integers, occasionally including letters or specific symbols to indicate certain geometric properties, relations, or symmetries.
The crystal system is a classification of crystals based on their internal symmetry and geometric arrangement. In crystallography, scientists categorize crystals into seven distinct systems according to their unit cells—the smallest repeating unit that reflects the symmetry and structure of the entire crystal. The seven crystal systems are: 1. **Cubical (or Isometric)**: Characterized by three equal axes at right angles to each other. Example: salt (sodium chloride).
A crystallographic point group is a mathematical classification of the symmetry of a crystal structure. These groups describe the symmetry operations that leave at least one point (typically the origin) invariant, meaning those operations do not alter the position of that point. The main symmetry operations included in crystallographic point groups are: 1. **Rotation**: Turning the crystal around an axis. 2. **Reflection**: Flipping the crystal across a plane.
Curie's principle, formulated by the French physicist Pierre Curie, states that "when a physical phenomenon exhibits symmetry, the causes of that phenomenon must also exhibit the same symmetry." In other words, if a system has a certain symmetry, any effects or changes resulting from that system should also respect that symmetry. This principle is particularly relevant in fields such as crystallography, material science, and physics in general, helping to predict how materials will behave under various conditions.
Cymatics is the study of visible sound and vibration. The term is derived from the Greek word "kyma," meaning "wave." It refers to the phenomenon where sound waves create visible patterns in a medium, usually a viscous substance like water or a powder. In cymatics, sound frequencies are applied to a surface, causing it to resonate.
Dichromatic symmetry is a concept that arises in the context of color theory and visual perception, particularly related to how we perceive and represent colors in a symmetrical manner. It often relates to the ways certain color combinations can be perceived as symmetrical or harmonious even when they are not identical. In art and design, dichromatic symmetry may refer to the use of two distinct colors that create a balanced and visually appealing composition.
Dihedral symmetry in three dimensions refers to the symmetry of three-dimensional objects that can be described by dihedral groups, which are related to the symmetries of polygons. Specifically, dihedral symmetry arises in the context of a polygon that has a certain number of sides, with a focus on its rotational and reflectional symmetries.
Discrete symmetry refers to a type of symmetry that involves distinct, separate transformations rather than continuous transformations. In physics and other scientific disciplines, symmetry is often related to invariance under specific transformations, and discrete symmetry encompasses situations where certain operations map a system onto itself in a non-continuous way. There are several types of discrete symmetries, including: 1. **Parity (P)**: This is the symmetry of spatial inversion, where the coordinates of a system are inverted (e.g.
The term "Einstein Group" doesn't refer to a widely recognized concept in academia or other fields as of my last update in October 2023. However, it could relate to several different contexts depending on what you're referencing: 1. **Scientific Community**: It might refer to a group of physicists or researchers who focus on topics related to Einstein's theories, especially in the realms of relativity or quantum mechanics.
Elitzur's theorem is a result in quantum mechanics that deals with the relationship between measurement and quantum states. Specifically, it addresses the concept of "quantum erasure," which refers to the idea that certain measurements can potentially make it possible to restore information about a quantum system that was previously lost or obscured by other measurements. The most famous context in which Elitzur's theorem is discussed involves the double-slit experiment, a fundamental demonstration of quantum behavior.
An equivariant map is a concept that arises in various areas of mathematics, particularly in the study of group actions on sets, geometric objects, and structures in algebra and topology. Formally, let \( G \) be a group acting on two spaces \( X \) and \( Y \). A map \( f: X \to Y \) is said to be equivariant with respect to the group action if it respects the action of the group.
The Erlangen Program is a framework for classifying geometric structures and understanding their properties based on group theory. It was proposed by the German mathematician Felix Klein in 1872 during a lecture in Erlangen, Germany. The central idea of the program is to study geometries by looking at the transformations that preserve certain properties or structures. Klein's approach emphasizes the relationship between geometry and symmetry. He classified geometries based on the groups of transformations that leave certain properties invariant.
Explicit symmetry breaking refers to a situation in physics where a system that has a certain symmetry is made to lose that symmetry due to the introduction of some external influence or perturbation. This is different from spontaneous symmetry breaking, where the symmetry is broken by the dynamics of the system itself, without any external influence. In explicit symmetry breaking, the parameters of the system (like masses, coupling constants, or external fields) are adjusted in such a way that they actively favor one state over another.
Facial symmetry refers to the degree to which one side of a person's face is a mirror image of the other side. In a perfectly symmetrical face, corresponding features (such as eyes, eyebrows, lips, and jawline) match in size, shape, and position on both sides. However, most human faces are not perfectly symmetrical; slight asymmetries are common and can even contribute to an individual's uniqueness and attractiveness.