The wavelength of electron when it is accelerated through potential variance of 4.00 × 10 3 volts has to be calculated. Concept introduction: Louis de Broglie in 1923 rationalized that when light shows particle aspects, then particles of matter display properties of waves under definite circumstances. λ = h mυ h is Planck’s constant( 6 .63 × 10 -34 J .s ) which relates energy and frequency. υ is the speed of particle. m is the mass of particle. λ is the wavelength. The above equation is called de Broglie relation. Relation between frequency and wavelength is, C = λν C is the speed of light. ν is the frequency. λ is wavelength. E = hν h is Planck’s constant ( 6 .63 × 10 -34 J .s ) which relates energy and frequency. ν is the frequency. E is energy of light particle. The distance between any two similar points of a wave is called wavelength Figure 1 λ is wavelength. Frequency is defined as number of wavelengths of a wave that can pass through a point in one second.
The wavelength of electron when it is accelerated through potential variance of 4.00 × 10 3 volts has to be calculated. Concept introduction: Louis de Broglie in 1923 rationalized that when light shows particle aspects, then particles of matter display properties of waves under definite circumstances. λ = h mυ h is Planck’s constant( 6 .63 × 10 -34 J .s ) which relates energy and frequency. υ is the speed of particle. m is the mass of particle. λ is the wavelength. The above equation is called de Broglie relation. Relation between frequency and wavelength is, C = λν C is the speed of light. ν is the frequency. λ is wavelength. E = hν h is Planck’s constant ( 6 .63 × 10 -34 J .s ) which relates energy and frequency. ν is the frequency. E is energy of light particle. The distance between any two similar points of a wave is called wavelength Figure 1 λ is wavelength. Frequency is defined as number of wavelengths of a wave that can pass through a point in one second.
Solution Summary: The author explains that the wavelength of electron when it is accelerated through potential variance of 4.00times 103
The wavelength of electron when it is accelerated through potential variance of 4.00×103volts has to be calculated.
Concept introduction:
Louis de Broglie in 1923 rationalized that when light shows particle aspects, then particles of matter display properties of waves under definite circumstances.
λ=hmυ
h is Planck’s constant(
6.63×10-34J.s) which relates energy and frequency.
υ is the speed of particle.
m is the mass of particle.
λ is the wavelength.
The above equation is called de Broglie relation.
Relation between frequency and wavelength is,
C=λν
C is the speed of light.
ν is the frequency.
λ is wavelength.
E=hν
h is Planck’s constant (
6.63×10-34J.s ) which relates energy and frequency.
ν is the frequency.
E is energy of light particle.
The distance between any two similar points of a wave is called wavelength
Figure 1
λ is wavelength.
Frequency is defined as number of wavelengths of a wave that can pass through a point in one second.
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