Frequency or wave length.
The relation between frequency f and wave length lof a light wave
is given by; f = c/l, where c is light's speed.
Just ONE property, the wavelength of the light. The colour of visible light depends on its wavelength. These wavelengths range from 700 nm at the red end of the spectrum to 400 nm at the violet end.
The frequency of the light wave determines its color. Higher frequencies correspond to shorter wavelengths and bluer colors, while lower frequencies correspond to longer wavelengths and redder colors.
Frequency and wavelength in a light wave are important because they determine the energy and properties of the light. The frequency determines the color of the light, with higher frequencies corresponding to bluer colors and lower frequencies to redder colors. The wavelength affects how the light interacts with different materials and influences properties like diffraction and interference.
Not exactly - light has wave properties. That means that it behaves like a wave.
The frequency of the wave determines the color of light. Higher frequency waves correspond to colors towards the blue end of the spectrum, while lower frequency waves correspond to colors towards the red end of the spectrum.
Just ONE property, the wavelength of the light. The colour of visible light depends on its wavelength. These wavelengths range from 700 nm at the red end of the spectrum to 400 nm at the violet end.
The frequency of a light wave tells you how many wave cycles pass a given point in one second. It determines the color of the light: higher frequencies correspond to colors like blue and violet, while lower frequencies correspond to colors like red and orange.
Frequency or wave length.The relation between frequency f and wave length lof a light waveis given by; f = c/l, where c is light's speed.
Yes, light is a wave. It exhibits properties such as interference, diffraction, and polarization, which are characteristics of wave behavior. These properties help define light as a wave phenomenon.
The wavelength of the light wave determines its color, with longer wavelengths appearing red and shorter wavelengths appearing violet. Additionally, the frequency of the light wave also plays a role, where higher frequencies correspond to bluer hues and lower frequencies to redder hues.
Vibration of a wave refers to the oscillating movement of particles or fields as the wave propagates through a medium. This vibration creates a pattern of alternating high and low pressure or displacement in the medium, resulting in the transmission of energy. The frequency of the vibration determines properties of the wave, such as pitch in sound waves or color in light waves.
The simplest answer is that light consists of particles with wave properties. Elementary particles also have wave properties. This is how light travels.