Nishant Sihag
Indian Institute of Technology (IIT), Delhi
Nishant Sihag has created this Calculator and 50+ more calculators!
Akshada Kulkarni
National Institute of Information Technology (NIIT), Neemrana
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11 Other formulas that you can solve using the same Inputs

Impulsive Torque
Impulsive Torque=(Moment of Inertia*(Final Angular Velocity-Angular velocity))/Time Taken to Travel GO
Strain Energy if moment value is given
Strain Energy=(Bending moment*Bending moment*Length)/(2*Elastic Modulus*Moment of Inertia) GO
Center of Gravity
Centre of gravity=Moment of Inertia/(Volume*(Centre of Buoyancy+Metacenter)) GO
Center of Buoyancy
Centre of Buoyancy=Moment of Inertia/(Volume*Centre of gravity)-Metacenter GO
Metacenter
Metacenter=Moment of Inertia/(Volume*Centre of gravity)-Centre of Buoyancy GO
Deflection of fixed beam with load at center
Deflection=-Width*(Length^3)/(192*Elastic Modulus*Moment of Inertia) GO
Nozzle Efficiency
Nozzle efficiency=Change in Kinetic Energy/Kinetic Energy GO
Angular Momentum
Angular Momentum=Moment of Inertia*Angular Velocity GO
Cooled Compressor Efficiency
Cooled Compressor Efficiency=Kinetic Energy/Work GO
Compressor Efficiency
Compressor efficiency=Kinetic Energy/Work GO
Turbine Efficiency
turbine efficiency=Work /Kinetic Energy GO

10 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 of electron when radial momentum is given
Angular Momentum=sqrt((Total momentum^2)-(Radial momentum^2)) GO
Angular momentum of electron
Angular Momentum=(Minor axis of elliptical orbit*[hP])/(2*pi) GO
Angular Momentum Using Quantum Number
Angular Momentum=(Quantum Number*Plancks Constant)/(2*pi) GO
Angular moment of momentum at inlet
Angular Momentum=Tangential velocity at inlet*Radius 1 GO
Angular moment of momentum at exit
Angular Momentum=Tangential velocity at exit*Radius 1 GO
Angular momentum using moment of inertia
Angular Momentum=Moment of Inertia*Angular Velocity GO
Angular Momentum
Angular Momentum=Moment of Inertia*Angular Velocity GO
Angular Momentum
Angular Momentum=Mass*Velocity*Radius GO

Angular momentum in terms of kinetic energy Formula

Angular Momentum=sqrt(2*Moment of Inertia*Kinetic Energy)
L=sqrt(2*I*KE)
More formulas
Mass 1 of diatomic molecule GO
Mass 2 of diatomic molecule GO
Radius 1 of rotation GO
Radius 2 of rotation GO
Bond length GO
Radius 1 of rotation when bond length is given GO
Radius 2 of rotation when bond length is given GO
Radius 1 of rotation in terms of masses and bond length GO
Radius 2 of rotation in terms of masses and bond length GO
Bond length in terms of masses and radius 1 GO
Bond length in terms of masses and radius 2 GO
Kinetic energy of system GO
Velocity of particle 1 in terms of K.E GO
Velocity of particle 2 in terms of K.E GO
Velocity of particle 1 GO
Rotational frequency in terms of velocity 1 GO
Radius 1 when rotational frequency is given GO
Velocity of particle 2 GO
Rotational frequency in terms of velocity 2 GO
Radius 2 when rotational frequency is given GO
Angular velocity of diatomic molecule GO
Rotational frequency when angular frequency is given GO
Kinetic energy when angular velocity is given GO
Angular velocity when kinetic energy is given GO
Moment of inertia of diatomic molecule GO
Mass 1 when moment of inertia is given GO
Mass 2 when moment of inertia is given GO
Radius 1 when moment of inertia is given GO
Radius 2 when moment of inertia is given GO
Kinetic energy in terms of inertia and angular velocity GO
Moment of Inertia in terms of K.E and angular velocity GO
Angular velocity in terms of inertia and kinetic energy GO
Moment of inertia using masses of diatomic molecule and bond length GO
Bond length using moment of inertia GO
Reduced mass GO
Moment of inertia using reduced mass GO
Reduced mass using moment of inertia GO
Bond length using reduced mass GO
Angular momentum using moment of inertia GO
Moment of inertia using angular momentum GO
Angular velocity using angular momentum and inertia GO
Kinetic energy in terms of angular momentum GO
Moment of inertia using kinetic energy and angular momentum GO
Rotational constant GO
Beta using rotational energy GO
Beta in terms of rotational level GO
Moment of inertia using rotational constant GO
Moment of inertia using rotational energy GO
Rotational constant in terms of energy GO
Energy of rotational transitions from J to J +1 GO
Rotational constant using energy of transitions GO
Rotational constant in terms of wave number GO
Bond length of diatomic molecule in rotational spectrum GO
Centrifugal Distortion constant using rotational energy GO

How to get Angular momentum in terms of kinetic energy?

We know that rotational kinetic energy is half moment of inertia times square of angular velocity. And further angular momentum is defined by: L=Iω. Through simple algebra we get a relation of angular momentum in terms of Kinetic energy{(L^2)=2*I*KE} .

How to Calculate Angular momentum in terms of kinetic energy?

Angular momentum in terms of kinetic energy calculator uses Angular Momentum=sqrt(2*Moment of Inertia*Kinetic Energy) to calculate the Angular Momentum, The Angular momentum in terms of kinetic energy formula is derived from rotational kinetic energy. Angular momentum is the rotational equivalent of linear momentum. Relation of angular momentum in terms of Kinetic energy{(L^2)=2*I*KE}. . Angular Momentum and is denoted by L symbol.

How to calculate Angular momentum in terms of kinetic energy using this online calculator? To use this online calculator for Angular momentum in terms of kinetic energy, enter Moment of Inertia (I) and Kinetic Energy (KE) and hit the calculate button. Here is how the Angular momentum in terms of kinetic energy calculation can be explained with given input values -> 12.99038 = sqrt(2*1.125*75).

FAQ

What is Angular momentum in terms of kinetic energy?
The Angular momentum in terms of kinetic energy formula is derived from rotational kinetic energy. Angular momentum is the rotational equivalent of linear momentum. Relation of angular momentum in terms of Kinetic energy{(L^2)=2*I*KE}. and is represented as L=sqrt(2*I*KE) or Angular Momentum=sqrt(2*Moment of Inertia*Kinetic Energy). Moment of Inertia is the measure of the resistance of a body to angular acceleration about a given axis and Kinetic Energy is defined as the work needed to accelerate a body of a given mass from rest to its stated velocity. Having gained this energy during its acceleration, the body maintains this kinetic energy unless its speed changes.
How to calculate Angular momentum in terms of kinetic energy?
The Angular momentum in terms of kinetic energy formula is derived from rotational kinetic energy. Angular momentum is the rotational equivalent of linear momentum. Relation of angular momentum in terms of Kinetic energy{(L^2)=2*I*KE}. is calculated using Angular Momentum=sqrt(2*Moment of Inertia*Kinetic Energy). To calculate Angular momentum in terms of kinetic energy, you need Moment of Inertia (I) and Kinetic Energy (KE). With our tool, you need to enter the respective value for Moment of Inertia and Kinetic Energy 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 Moment of Inertia and Kinetic Energy. We can use 10 other way(s) to calculate the same, which is/are as follows -
  • Angular Momentum=Moment of Inertia*Angular Velocity
  • Angular Momentum=Mass*Velocity*Radius
  • 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)
  • Angular Momentum=(Minor axis of elliptical orbit*[hP])/(2*pi)
  • Angular Momentum=sqrt((Total momentum^2)-(Radial momentum^2))
  • Angular Momentum=Moment of Inertia*Angular Velocity
  • Angular Momentum=Tangential velocity at inlet*Radius 1
  • Angular Momentum=Tangential velocity at exit*Radius 1
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