11 Other formulas that you can solve using the same Inputs

Total Surface Area of a Cone
Total Surface Area=pi*Radius*(Radius+sqrt(Radius^2+Height^2)) GO
Lateral Surface Area of a Cone
Lateral Surface Area=pi*Radius*sqrt(Radius^2+Height^2) GO
Surface Area of a Capsule
Surface Area=2*pi*Radius*(2*Radius+Side) GO
Volume of a Capsule
Volume=pi*(Radius)^2*((4/3)*Radius+Side) GO
Volume of a Circular Cone
Volume=(1/3)*pi*(Radius)^2*Height GO
Base Surface Area of a Cone
Base Surface Area=pi*Radius^2 GO
Top Surface Area of a Cylinder
Top Surface Area=pi*Radius^2 GO
Volume of a Circular Cylinder
Volume=pi*(Radius)^2*Height GO
Area of a Circle when radius is given
Area of Circle=pi*Radius^2 GO
Volume of a Hemisphere
Volume=(2/3)*pi*(Radius)^3 GO
Volume of a Sphere
Volume=(4/3)*pi*(Radius)^3 GO

4 Other formulas that calculate the same Output

Orbital Angular Momentum
Angular Momentum=sqrt(Azimuthal Quantum Number*(Azimuthal Quantum Number+1))*Plancks Constant/(2*pi) GO
Spin Angular Momentum
Angular Momentum=sqrt(Spin Quantum Number*(Spin Quantum Number+1))*Plancks Constant/(2*pi) GO
Angular Momentum Using Quantum Number
Angular Momentum=(Quantum Number*Plancks Constant)/(2*pi) GO
Angular Momentum
Angular Momentum=Moment of Inertia*Angular Velocity GO

Angular Momentum Formula

Angular Momentum=Mass*Velocity*Radius
More formulas
Specific charge GO
Mass of moving electron GO
Electric charge GO
Mass number GO
Number of neutrons GO
Wave number of electromagnetic wave GO
Velocity of alpha particle using distance of closest approach GO
Distance of closest approach GO
Energy Of A Moving Particle Using Frequency GO
Wave length Of A Moving Particle GO
Frequency Of A Moving Particle GO
Wave Number Of A Moving Particle GO
Bohr's Radius GO
Kinetic Energy Of A Electron GO
Potential Energy Of Electron GO
Total Energy Of Electron GO
Number Of Spectral Lines GO
Change In Wavelength Of A Moving Particle GO
Change In Wave Number Of A Moving Particle GO
Wavelength Of A Moving Particle GO
Energy Of A Moving Particle Using Wavelength GO
Energy Of A Moving Particle Using Wave Number GO
De-Brogile Wavelength GO
Angular Momentum Using Quantum Number GO
Magnetic Moment GO
Radius Of The Orbit GO
Velocity Of The Particle GO
Kinetic Energy In Electron Volts. GO
Potential Energy In Electron Volts. GO
Total Energy In Electron Volts GO
Wavelength Using Energy GO
Frequency Using Energy GO
Number Of Spherical Nodes GO
Number Of Angular Nodes GO
Number Of Nodal Planes GO
Total Number Of Nodes GO
Energy of a photon using Einstein's approach GO
Energy of 1 mole of photons GO
Threshold energy GO
Intensity of light in photo-electric effect GO
Kinetic energy of photoelectrons GO
Energy of photon in photo-electric effect GO
Electrostatic force between nucleus and electron GO
Radius of Bohr's orbit when atomic number is given GO
Velocity of electron in Bohr's orbit GO
Orbital frequency of an electron GO
Kinetic energy of electron when atomic number is given GO
Total energy of electron when atomic number is given GO
Rydberg's Equation GO
Rydberg's Equation for hydrogen GO
Rydberg's Equation for Lyman series GO
Rydberg's Equation for Balmer Series GO
Rydberg's Equation for Paschen Series GO
Rydberg's Equation for Brackett Series GO
Rydberg's Equation for Pfund Series GO
Orbital Angular Momentum GO
Spin Angular Momentum GO
Time period of revolution of electron GO

What is Bohr's theory?

Bohr's Theory is a theory of atomic structure in which the hydrogen atom (Bohr atom ) is assumed to consist of a proton as nucleus, with a single electron moving in distinct circular orbits around it, each orbit corresponding to a specific quantized energy state.

How to Calculate Angular Momentum?

Angular Momentum calculator uses Angular Momentum=Mass*Velocity*Radius to calculate the Angular Momentum, The Angular Momentum formula is defined as the rotational equivalent of linear momentum. It is an important quantity in physics because it is a conserved quantity. . Angular Momentum and is denoted by L symbol.

How to calculate Angular Momentum using this online calculator? To use this online calculator for Angular Momentum, enter Radius (r), Mass (m) and Velocity (v) and hit the calculate button. Here is how the Angular Momentum calculation can be explained with given input values -> 382.86 = 35.45*60*0.18.

FAQ

What is Angular Momentum?
The Angular Momentum formula is defined as the rotational equivalent of linear momentum. It is an important quantity in physics because it is a conserved quantity. and is represented as L=m*v*r or Angular Momentum=Mass*Velocity*Radius. Radius is a radial line from the focus to any point of a curve, Mass is the quantity of matter in a body regardless of its volume or of any forces acting on it and Velocity, in physics, is a vector quantity (it has both magnitude and direction), and is the time rate of change of position (of an object). .
How to calculate Angular Momentum?
The Angular Momentum formula is defined as the rotational equivalent of linear momentum. It is an important quantity in physics because it is a conserved quantity. is calculated using Angular Momentum=Mass*Velocity*Radius. To calculate Angular Momentum, you need Radius (r), Mass (m) and Velocity (v). With our tool, you need to enter the respective value for Radius, Mass and Velocity and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Angular Momentum?
In this formula, Angular Momentum uses Radius, Mass and Velocity. We can use 4 other way(s) to calculate the same, which is/are as follows -
  • Angular Momentum=Moment of Inertia*Angular Velocity
  • Angular Momentum=(Quantum Number*Plancks Constant)/(2*pi)
  • Angular Momentum=sqrt(Azimuthal Quantum Number*(Azimuthal Quantum Number+1))*Plancks Constant/(2*pi)
  • Angular Momentum=sqrt(Spin Quantum Number*(Spin Quantum Number+1))*Plancks Constant/(2*pi)
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