Which Light Has More Energy: 580 nm or 660 nm?
Which type of light—light with a wavelength of 660 nm or one of 580 nm—has more energy?
Light with a 660 nm wavelength has more energy than light with a 580 nm wavelength. This is due to the fact that the relationship between light energy and wavelength is inverse.
Why does light with a 660 nm wavelength have more energy than light with a 580 nm wavelength?
The energy of the light diminishes with an increase in wavelength. As a result, light with a 660 nm wavelength has a shorter wavelength and more energy than light with a 580 nm wavelength.
How does the ability to permeate into substance affect the energy of light with 660 nm vs. 580 nm?
The shorter wavelength of the 660 nm light's greater ability than the longer wavelength of the 580 nm light to permeate into the substance leads to it having more energy.
Why can light with a 660 nm wavelength transfer more energy to a substance compared to light with a 580 nm wavelength?
Because the 660 nm light has a greater frequency and more energy than the 580 nm light, it is able to transfer more energy to the substance.
Final Answer:
The energy of light is inversely related to its wavelength. Therefore, light with a wavelength of 580 nm has more energy than light with a wavelength of 660 nm.
Explanation:
The energy of light is inversely proportional to its wavelength, which means that shorter wavelengths of light have more energy than longer ones. In our comparison, 580 nm has less wavelength than 660 nm, implying that light of wavelength 580 nm has more energy. Hence, the answer to your question, 'Which has more energy, light with a wavelength of 580 nm or light with a wavelength of 660 nm?' is a. 580 nm.
Light energy is an essential aspect of understanding the behavior of light waves. The relationship between wavelength and energy is crucial in determining the characteristics of different types of light. In the case of light with wavelengths of 580 nm and 660 nm, the shorter wavelength of 580 nm results in it having more energy compared to the light with a longer wavelength of 660 nm.
The ability of light to permeate into substances is influenced by its wavelength, with shorter wavelengths having a greater ability to penetrate and transfer energy. This is why light with a 660 nm wavelength is capable of transferring more energy to substances than light with a 580 nm wavelength.
Understanding the inverse relationship between the energy of light and its wavelength can provide valuable insights into various applications of light in science and technology. By recognizing that shorter wavelengths correspond to higher energy levels, we can make informed decisions about the use and manipulation of light in different contexts.