angular coordinate

Examples of angular coordinate in the following topics:

• Introduction to the Polar Coordinate System

  • The distance from the pole is called the radial coordinate or radius, and the angle is called the angular coordinate, polar angle, or azimuth.
  • The radial coordinate is often denoted by $r$ or $ρ$ , and the angular coordinate by $ϕ$, $θ$, or $t$.
  • In many contexts, a positive angular coordinate means that the angle $ϕ$ is measured counterclockwise from the axis.  
  • Adding any number of full turns ($360^{\circ} $ or $2\pi$ radians) to the angular coordinate does not change the corresponding direction.
  • In green, the point with radial coordinate $3$ and angular coordinate $60$ degrees or $(3,60^{\circ})$.

• Cylindrical and Spherical Coordinates

  • Cylindrical and spherical coordinates are useful when describing objects or phenomena with specific symmetries.
  • While Cartesian coordinates have many applications, cylindrical and spherical coordinates are useful when describing objects or phenomena with specific symmetries.
  • The spherical coordinates (radius $r$, inclination $\theta$, azimuth $\varphi$) of a point can be obtained from its Cartesian coordinates ($x$, $y$, $z$) by the formulae:
  • A cylindrical coordinate system with origin $O$, polar axis $A$, and longitudinal axis $L$.
  • The dot is the point with radial distance $\rho = 4$, angular coordinate $\varphi = 130$ degrees, and height $z = 4$.

• Wave Equation for the Hydrogen Atom

  • Although the resulting energy eigenfunctions (the orbitals) are not necessarily isotropic themselves, their dependence on the angular coordinates follows generally from this isotropy of the underlying potential.
  • The angular momentum quantum number ℓ = 0, 1, 2, ... determines the magnitude of the angular momentum.
  • In addition to mathematical expressions for total angular momentum and angular momentum projection of wavefunctions, an expression for the radial dependence of the wavefunctions must be found.
  • Due to angular momentum conservation, states of the same ℓ but different mℓ have the same energy.
  • The wavefunction itself is expressed in spherical polar coordinates:

• Description of the Hydrogen Atom

  • Although the resulting energy eigenfunctions (the orbitals) are not necessarily isotropic themselves, their dependence on the angular coordinates follows completely, generally from this isotropy of the underlying potential.
  • This corresponds to the fact that angular momentum is conserved in the orbital motion of the electron around the nucleus.
  • Therefore, the energy eigenstates may be classified by two angular momentum quantum numbers, ℓ and m (both are integers).
  • The angular momentum quantum number ℓ = 0, 1, 2, ... determines the magnitude of the angular momentum.
  • In addition to mathematical expressions for total angular momentum and angular momentum projection of wavefunctions, an expression for the radial dependence of the wave functions must be found.

• Angular Acceleration, Alpha

  • Angular acceleration is the rate of change of angular velocity, expressed mathematically as $\alpha = \Delta \omega/\Delta t$ .
  • Angular acceleration is the rate of change of angular velocity.
  • Angular acceleration is defined as the rate of change of angular velocity.
  • In equation form, angular acceleration is expressed as follows:
  • The units of angular acceleration are (rad/s)/s, or rad/s2.

• Constant Angular Acceleration

  • Constant angular acceleration describes the relationships among angular velocity, angle of rotation, and time.
  • Simply by using our intuition, we can begin to see the interrelatedness of rotational quantities like θ (angle of rotation), ω (angular velocity) and α (angular acceleration).
  • Similarly, the kinematics of rotational motion describes the relationships among rotation angle, angular velocity, angular acceleration, and time.
  • As in linear kinematics where we assumed a is constant, here we assume that angular acceleration α is a constant, and can use the relation: $a=r\alpha $ Where r - radius of curve.Similarly, we have the following relationships between linear and angular values: $v=r\omega \\x=r\theta $
  • Relate angle of rotation, angular velocity, and angular acceleration to their equivalents in linear kinematics

• Hydrostatics

  • or that isentropic stars must have constant angular velocity on cylindrical surfaces.

• Rotational Collisions

  • In a closed system, angular momentum is conserved in a similar fashion as linear momentum.
  • For objects with a rotational component, there exists angular momentum.
  • Angular momentum is defined, mathematically, as L=Iω, or L=rxp.
  • An object that has a large angular velocity ω, such as a centrifuge, also has a rather large angular momentum.
  • After the collision, the arrow sticks to the rolling cylinder and the system has a net angular momentum equal to the original angular momentum of the arrow before the collision.

• Conservation of Angular Momentum

  • The law of conservation of angular momentum states that when no external torque acts on an object, no change of angular momentum will occur.
  • The conserved quantity we are investigating is called angular momentum.
  • The symbol for angular momentum is the letter L.
  • If the change in angular momentum ΔL is zero, then the angular momentum is constant; therefore,
  • (I: rotational inertia, $\omega$: angular velocity)

• Quantum Numbers

  • This model describes electrons using four quantum numbers: energy (n), angular momentum (ℓ), magnetic moment (mℓ), and spin (ms).
  • This number therefore has a dependence only on the distance between the electron and the nucleus (i.e. the radial coordinate r).
  • The second quantum number, known as the angular or orbital quantum number, describes the subshell and gives the magnitude of the orbital angular momentum through the relation.
  • The magnetic quantum number describes the energy levels available within a subshell and yields the projection of the orbital angular momentum along a specified axis.
  • The fourth quantum number describes the spin (intrinsic angular momentum) of the electron within that orbital and gives the projection of the spin angular momentum (s) along the specified axis.