0
Want this question answered?
Be notified when an answer is posted
Add your answer:
Earn +20 pts
Measures the amount of particle vibration?
Amplitude measures the amount of particle vibration.
According to who the energy of a particle is proportional to its frequency of oscillation?
max planck
Is the time it takes for one full vibration of a particle in a medium?
The inverse of the frequency.
If two sine waves of equal frequency and amplitude are superimposed what is the frequency of the resulting wave What will happen to a particle?
The resulting waveform will have the same frequency as both components although the amplitude will be doubled.
What refers to the number of cycles a particle riding the waves passes through in a given amount of time?
frequency ..... A+
Measures the amount of particle vibration?
Amplitude measures the amount of particle vibration.
Decreasing particle size collision frequency of reactants?
increases
What refers to the number of cycles a particle riding the wave passes through in a given amount of time?
frequency ..... A+
According to who the energy of a particle is proportional to its frequency of oscillation?
max planck
Is the time it takes for one full vibration of a particle in a medium?
The inverse of the frequency.
What is frequency of waves?
The number of circular revolutions made by the charged particle in one second. f=1/T unit of frequency is Hertz
Is the full time it takes for one full vibration of a particle in a medium?
The inverse of the frequency.
If two sine waves of equal frequency and amplitude are superimposed what is the frequency of the resulting wave What will happen to a particle?
The resulting waveform will have the same frequency as both components although the amplitude will be doubled.
What refers to the number of cycles a particle riding the waves passes through in a given amount of time?
frequency ..... A+
Does a low pitch sound have a low frequency?
A sound wave, like any other wave, is introduced into a medium by a vibrating object. The vibrating object is the source of the disturbance that moves through the medium. The vibrating object that creates the disturbance could be the vocal cords of a person, the vibrating string and sound board of a guitar or violin, the vibrating tines of a tuning fork, or the vibrating diaphragm of a radio speaker. Regardless of what vibrating object is creating the sound wave, the particles of the medium through which the sound moves is vibrating in a back and forth motion at a given frequency. The frequency of a wave refers to how often the particles of the medium vibrate when a wave passes through the medium. The frequency of a wave is measured as the number of complete back-and-forth vibrations of a particle of the medium per unit of time. If a particle of air undergoes 1000 longitudinal vibrations in 2 seconds, then the frequency of the wave would be 500 vibrations per second. A commonly used unit for frequency is the Hertz (abbreviated Hz), where 1 Hertz = 1 vibration/second As a sound wave moves through a medium, each particle of the medium vibrates at the same frequency. This is sensible since each particle vibrates due to the motion of its nearest neighbor. The first particle of the medium begins vibrating, at say 500 Hz, and begins to set the second particle into vibrational motion at the same frequency of 500 Hz. The second particle begins vibrating at 500 Hz and thus sets the third particle of the medium into vibrational motion at 500 Hz. The process continues throughout the medium; each particle vibrates at the same frequency. And of course the frequency at which each particle vibrates is the same as the frequency of the original source of the sound wave. Subsequently, a guitar string vibrating at 500 Hz will set the air particles in the room vibrating at the same frequency of 500 Hz, which carries a sound signal to the ear of a listener, which is detected as a 500 Hz sound wave.
Light is a particle called photon Why the velocities are different?
Photon is not a particle at all. It is having zero rest mass. The colour of light is mainly due to variation in the frequency nu. The energy of a photon is given by the formula E= h nu. Here nu is the frequency of the radiation. As frequency changes colour changes. For violet it will be the highest and for red its frequecy will be the lowest.
How do you calculate the frequency of light emitted in chemicals?
There are several ways to calculate the frequency of light emitted or absorbed by different chemicals, and they depend on what you already know. For example, if you know the energy of the particle, then you can calculate frequency from E = planck's constant x frequency and solve for frequency. If you happen to know the wavelength, then you can use C = wavelength x frequency and solve for frequency (where C = speed of light).
