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Photon energy can be increased by following two methods.
1). by increase in frequency of one photon as (E = hf); where f denotes the frequency of corresponding region. In this case, the electromagnetic region will change to higher frequency region or shorter wavelength region. The photon energy may increase, but not the intensity.
2). secondly increase in the number of photons (n) as E= nhf. If the number of photons of a particular frequency increase, photon energy also increases. In this case, intensity of light of definite frequency (either blue, red etc.) increase simultaneously.
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Which best describes the relationship between photon energy and the color of light?
The color of light is directly related to the energy of its photons. Light with higher photon energy appears bluer, while light with lower photon energy appears redder. This relationship is governed by the electromagnetic spectrum and the frequency of light.
What is the distance between the crest of one photon wave and the next is called?
The distance between the crest of one photon wave and the next is called the wavelength. It is a measure of the spatial extent of the wave and determines the color and energy of the photon.
What determines the color of a photon and how is it related to its properties and behavior?
The color of a photon is determined by its wavelength, which corresponds to its energy. Different colors of light have different wavelengths and energies. The properties and behavior of a photon, such as its speed and interactions with matter, are influenced by its color and energy level.
What is the relationship between the wavelength of a photon and its perceived color?
The relationship between the wavelength of a photon and its perceived color is that shorter wavelengths correspond to colors towards the blue end of the spectrum, while longer wavelengths correspond to colors towards the red end of the spectrum. This is known as the visible light spectrum, where different wavelengths of light are perceived as different colors by the human eye.
When an electron falls from a higher energy level to a lower energy energy level how is the energy released?
When an electron falls from a higher energy level to a lower energy level, the energy it was carrying is released in the form of a photon. The energy of the photon is equal to the difference in energy between the two levels. This released energy can be observed as light emission in the visible or invisible spectra, depending on the specific energy levels involved.
Which best describes the relationship between photon energy and the color of light?
The color of light is directly related to the energy of its photons. Light with higher photon energy appears bluer, while light with lower photon energy appears redder. This relationship is governed by the electromagnetic spectrum and the frequency of light.
When a photon is emmit out from the atom its color is same as the atom color?
No. The color of the electron depends on the energy difference between the levels from/to which it is changing.
What is the distance between the crest of one photon wave and the next is called?
The distance between the crest of one photon wave and the next is called the wavelength. It is a measure of the spatial extent of the wave and determines the color and energy of the photon.
What determines the color of a photon and how is it related to its properties and behavior?
The color of a photon is determined by its wavelength, which corresponds to its energy. Different colors of light have different wavelengths and energies. The properties and behavior of a photon, such as its speed and interactions with matter, are influenced by its color and energy level.
Which color wavelengths would contain the most photon energy?
Red color
Which color of the visible spectrum contain the most energy?
Each photon of blue light has more energy than a photon of any other color, because the blue ones have the highest frequency.
What is the relationship between the wavelength of a photon and its perceived color?
The relationship between the wavelength of a photon and its perceived color is that shorter wavelengths correspond to colors towards the blue end of the spectrum, while longer wavelengths correspond to colors towards the red end of the spectrum. This is known as the visible light spectrum, where different wavelengths of light are perceived as different colors by the human eye.
What happens to excess energy when the electron jumps from a higher energy orbit to a lower energy orbit in the hydrogen atom?
The electron emits a photon of light which we can see in a spectrograph as color. Four colors are normally seen in a hydrogen atom subjected to energy.
When an electron falls from a higher energy level to a lower energy energy level how is the energy released?
When an electron falls from a higher energy level to a lower energy level, the energy it was carrying is released in the form of a photon. The energy of the photon is equal to the difference in energy between the two levels. This released energy can be observed as light emission in the visible or invisible spectra, depending on the specific energy levels involved.
What is the relationship between color and frequency and energy of an electromagnetic wave?
Color is determined by the frequency of an electromagnetic wave, with higher frequencies corresponding to colors at the blue end of the spectrum and lower frequencies corresponding to colors at the red end. Energy is directly proportional to frequency, so higher frequency waves (e.g., blue light) have more energy than lower frequency waves (e.g., red light).
How Does Electrons Give Off Light?
When an electron transitions from a higher energy level to a lower one, it releases energy in the form of a photon of light. This photon has a specific wavelength and color determined by the energy difference between the two levels. This process is known as emission of light by electrons.
Quanta of light emitted from 1 electron drops from the 7th to 2nd energy level?
When an electron drops from the 7th to the 2nd energy level in an atom, it emits a photon of light. The energy of this photon corresponds to the difference in energy between these two levels. The amount of energy difference is specific to the atom involved, and the photon emitted will have a specific wavelength and color based on this energy difference.
