Energy = Planck's constant * Frequency
so, basically
5.5 X 10^-18 J = 6.626 X 10^-34 J*s/Frequency
= 8.3 X 10^15 Hertz ( or s^-1 )
One calculates energy as the product of frequency and Planck's constant. Planck's constant is approximately 6x10^(-34)Js. So you answer is:
8x10^9 s^(-1)
8x10^9 Hz
80
E = h x nu = 6.626176 x 10-34 joule-seconds x 4x10^7 sec = 2.65x10^-26 Joules
Longitudinal and Transverse energy waves are the two types.
In the visible region of electromagnetic spectrum VIBGYOR, violet having highest frequency is at one extreme and red having the lowest frequency goes to other extreme. So violet with shortest wavelength and red with the longest.
E = hv where that "v" is actually supposed to be the Greek letter nu, standing for frequency. So just convert the wavelength to frequency and multiply by Planck's constant and you'll have your answer.
Electromagnetic radiation, or light, is a form of energy. Light travels in waves at a constant speed, and so it always has a wavelenghth and a corresponding frequency. As the wavelength gets shorter, the frequency increases. As the frequency increases, the amount of energy carried per photon increases. Another word for frequency, when talking about light, is color. The visible frequencies of light range from red to violet, with red having the lowest frequency/largest wavelength and violet having the highest frequency/shortest wavelength. There are many times more frequencies of light that cannot be seen than can. Going more energetic from violet, you have ultraviolet (UV), X-rays, and gamma rays. Gamma rays are every color of light higher than a certain frequency, and so you could theoretically have a color of light with infinite energy in one photon, and it would still be a gamma ray.
E = h x nu = 6.626176 x 10-34 joule-seconds x 4x10^7 sec = 2.65x10^-26 Joules
The energy is 3,8431.10e-14 joule.
The frequecy is o,74958 Hz.
Longitudinal and Transverse energy waves are the two types.
If the photon is having very less frequency (say v=1Hz) ,then the Energy of such photon will be the smallest one. It can be inferred that the smallest unit of light energy will correspond to the smallest frequency of such quanta. But from the uncertainty principle it limits the energy of a quanta.
E=h*fh is Planck's constant, which is equal to 6.62 x 10-34 J . s.f is the frequency in Hz.Multiplication of two numbers together is left as an exercise to the student.3.2 x 10-18 Jacutual answer on The Question is 4.3 x 10-19J
In this case, the frequency of a wave emitted by one person would increase (be perceived as having a higher frequency) by the other.In this case, the frequency of a wave emitted by one person would increase (be perceived as having a higher frequency) by the other.In this case, the frequency of a wave emitted by one person would increase (be perceived as having a higher frequency) by the other.In this case, the frequency of a wave emitted by one person would increase (be perceived as having a higher frequency) by the other.
E = hv where that "v" is actually supposed to be the Greek letter nu, standing for frequency. So just convert the wavelength to frequency and multiply by Planck's constant and you'll have your answer.
In the visible region of electromagnetic spectrum VIBGYOR, violet having highest frequency is at one extreme and red having the lowest frequency goes to other extreme. So violet with shortest wavelength and red with the longest.
16 nigg3rs
Electromagnetic radiation, or light, is a form of energy. Light travels in waves at a constant speed, and so it always has a wavelenghth and a corresponding frequency. As the wavelength gets shorter, the frequency increases. As the frequency increases, the amount of energy carried per photon increases. Another word for frequency, when talking about light, is color. The visible frequencies of light range from red to violet, with red having the lowest frequency/largest wavelength and violet having the highest frequency/shortest wavelength. There are many times more frequencies of light that cannot be seen than can. Going more energetic from violet, you have ultraviolet (UV), X-rays, and gamma rays. Gamma rays are every color of light higher than a certain frequency, and so you could theoretically have a color of light with infinite energy in one photon, and it would still be a gamma ray.
Energy of photon in joules = Planck's Constant (in Joule seconds) * greek letter Nu for frequency (units of 1/seconds)Planck's Constant = 6.626 * 10^-34 Joule secondsYou can type "Planck's constant" into google to calculate this (this is what I did).(Planck's constant * 4 * (10^7)) / s = 2.6504272 × 10-26 joules