De-Broglie wavelength of particle in circular orbit Calculator

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Atomic-Structure	de-Broglie hypothesis ↺

✖Radius of orbit is the distance from the center of orbit of an electron to a point on its surface.ⓘ Radius of orbit [r]			+10% -10%
✖Quantum Number describe values of conserved quantities in the dynamics of a quantum system.ⓘ Quantum Number [n]			+10% -10%

✖Wavelength is the distance between identical points (adjacent crests) in the adjacent cycles of a waveform signal propagated in space or along a wireⓘ De-Broglie wavelength of particle in circular orbit [λ]

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De-Broglie wavelength of particle in circular orbit

Akshada Kulkarni

National Institute of Information Technology (NIIT), Neemrana

Akshada Kulkarni has created this Calculator and 400+ more calculators!

Suman Ray Pramanik

Indian Institute of Technology (IIT), Kanpur

Suman Ray Pramanik has verified this Calculator and 100+ more calculators!

< 11 Other formulas that you can solve using the same Inputs

Kinetic Energy In Electron Volts.

Energy In Electron Volts=-13.6*(Atomic number)^2/(Quantum Number)^2 GO

Potential Energy In Electron Volts.

Energy In Electron Volts=6.8*(Atomic number)^2/(Quantum Number)^2 GO

Number Of Spectral Lines

Number Of Spectral Lines=(Quantum Number*(Quantum Number-1))/2 GO

Velocity Of The Particle

Velocity=(Quantum Number*Plancks Constant)/(Mass*Radius*2*pi) GO

Radius Of The Orbit

Radius=(Quantum Number*Plancks Constant)/(2*pi*Mass*Velocity) GO

Magnetic Moment

Magnetic Moment=sqrt(Quantum Number*(Quantum Number+2))*1.7 GO

Angular Momentum Using Quantum Number

Angular Momentum=(Quantum Number*Plancks Constant)/(2*pi) GO

Kinetic Energy Of A Electron

Energy=-2.178*10^-18*(Atomic number)^2/(Quantum Number)^2 GO

Potential Energy Of Electron

Energy=1.085*10^-18*(Atomic number)^2/(Quantum Number)^2 GO

Total Energy Of Electron

Energy=-1.085*(Atomic number)^2/(Quantum Number)^2 GO

Bohr's Radius

Radius=(Quantum Number/Atomic number)*0.529*10^-10 GO

< 11 Other formulas that calculate the same Output

de-Broglie wavelength of charged particle when potential is given

Wavelength=[hP]/(2*[Charge-e]*Electric Potential Difference*Mass of moving electron) GO

Wavelength Using Energy

Wavelength=Plancks Constant/sqrt(2*Mass*Energy In Electron Volts) GO

Wavelength Of A Moving Particle

Wavelength=(Plancks Constant*Velocity Of Light in Vacuum)/Energy GO

Relation between de-Broglie wavelength and kinetic energy of particle

Wavelength=[hP]/sqrt(2*Kinetic Energy*Mass of moving electron) GO

Change In Wavelength Due To The Movement Of Source

Wavelength=Velocity Source*Time Period Of Progressive Wave GO

Change In Wavelength When Angular Frequency is Given

Wavelength=Velocity Source*2*pi*Angular Frequency GO

De-Brogile Wavelength

Wavelength=Plancks Constant/(Mass*Velocity) GO

Change In Wavelength When Frequency is Given

Wavelength=Velocity Source/frequency GO

De Broglie Wavelength

Wavelength=[hP]/Photon's Momentum GO

De-Broglie's wavelength when velocity of particle is given

Wavelength=[hP]/(Mass*Velocity) GO

Wavelength Of The Wave(Using Frequency)

Wavelength=Velocity/frequency GO

De-Broglie wavelength of particle in circular orbit Formula

Wavelength=(2*pi*Radius of orbit)/Quantum Number
λ=(2*pi*r)/n

More formulas

De-Brogile Wavelength GO

Energy of a particle GO

Energy of particle when de-Broglie wavelength is given GO

De-Broglie's wavelength when velocity of particle is given GO

Einstein's mass-energy relation GO

Number of revolutions of an electron GO

Relation between de-Broglie wavelength and kinetic energy of particle GO

de-Broglie wavelength of charged particle when potential is given GO

de-Broglie wavelength for an electron when potential is given GO

Kinetic energy when de-Broglie wavelength is given GO

Potential when de-Broglie wavelength is given GO

Potential when de-Broglie wavelength of electron is given GO

What is de Broglie's hypothesis of matter waves?

Louis de Broglie proposed a new speculative hypothesis that electrons and other particles of matter can behave like waves. According to de Broglie’s hypothesis, massless photons, as well as massive particles, must satisfy one common set of relations that connect the energy E with the frequency f, and the linear momentum p with the de- Broglie wavelength.

How to Calculate De-Broglie wavelength of particle in circular orbit?

De-Broglie wavelength of particle in circular orbit calculator uses Wavelength=(2*pi*Radius of orbit)/Quantum Number to calculate the Wavelength, The De-Broglie wavelength of particle in circular orbit is associated with a particle/electron revolving around the nucleus in the circular path and is related to its radius, r. Wavelength and is denoted by λ symbol.

How to calculate De-Broglie wavelength of particle in circular orbit using this online calculator? To use this online calculator for De-Broglie wavelength of particle in circular orbit, enter Radius of orbit (r) and Quantum Number (n) and hit the calculate button. Here is how the De-Broglie wavelength of particle in circular orbit calculation can be explained with given input values -> 6.283E-8 = (2*pi*1E-08)/1.

FAQ

What is De-Broglie wavelength of particle in circular orbit?

The De-Broglie wavelength of particle in circular orbit is associated with a particle/electron revolving around the nucleus in the circular path and is related to its radius, r and is represented as λ=(2*pi*r)/n or Wavelength=(2*pi*Radius of orbit)/Quantum Number. Radius of orbit is the distance from the center of orbit of an electron to a point on its surface and Quantum Number describe values of conserved quantities in the dynamics of a quantum system.

How to calculate De-Broglie wavelength of particle in circular orbit?

The De-Broglie wavelength of particle in circular orbit is associated with a particle/electron revolving around the nucleus in the circular path and is related to its radius, r is calculated using Wavelength=(2*pi*Radius of orbit)/Quantum Number. To calculate De-Broglie wavelength of particle in circular orbit, you need Radius of orbit (r) and Quantum Number (n). With our tool, you need to enter the respective value for Radius of orbit and Quantum Number 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 Wavelength?

In this formula, Wavelength uses Radius of orbit and Quantum Number. We can use 11 other way(s) to calculate the same, which is/are as follows -

Wavelength=Velocity/frequency
Wavelength=Velocity Source*Time Period Of Progressive Wave
Wavelength=Velocity Source/frequency
Wavelength=Velocity Source*2*pi*Angular Frequency
Wavelength=[hP]/Photon's Momentum
Wavelength=(Plancks Constant*Velocity Of Light in Vacuum)/Energy
Wavelength=Plancks Constant/(Mass*Velocity)
Wavelength=Plancks Constant/sqrt(2*Mass*Energy In Electron Volts)
Wavelength=[hP]/(Mass*Velocity)
Wavelength=[hP]/sqrt(2*Kinetic Energy*Mass of moving electron)
Wavelength=[hP]/(2*[Charge-e]*Electric Potential Difference*Mass of moving electron)

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