None, such a pigment would be utterly useless, biologically. Even rhodopsin in your rods, which process black and white and are primarily used for change detection, absorbs multiple frequencies of light. Would it make sense for you to use a ton of different pigments that each absorb one wavelength, instead of having a few that absorb a wide range of wavelengths? I would attach a diagram of the absorption spectra for rhodopsin, but I think my Professor would get mad about copyrights.
The accessory pigment phycoerythrin allows porphyra to absorb light more efficiently in deeper waters where blue and green light is less available. This gives porphyra an advantage in photosynthesis and allows it to thrive in environments where other organisms may struggle to obtain enough light for energy production.
The green pigment in chloroplasts is called chlorophyll. It absorbs light energy from the sun during photosynthesis, which is the process by which plants use sunlight to convert carbon dioxide and water into glucose and oxygen.
When light has a higher frequency, it means the wavelength is shorter and the energy of the light is higher. Higher frequency light can have more pronounced effects, such as greater potential for damaging biological tissues and the ability to excite electrons to higher energy levels. Examples of high frequency light include ultraviolet and X-rays.
The most energetic kind of visible light is violet light, while the least energetic kind is red light. This is because violet light has the shortest wavelength and highest frequency, while red light has the longest wavelength and lowest frequency among visible light colors.
It depends on what kind of pigment the plant has. The color of the plant is reflected. That means every other color is obsorbed.
The accessory pigment phycoerythrin allows porphyra to absorb light more efficiently in deeper waters where blue and green light is less available. This gives porphyra an advantage in photosynthesis and allows it to thrive in environments where other organisms may struggle to obtain enough light for energy production.
The green pigment in chloroplasts is called chlorophyll. It absorbs light energy from the sun during photosynthesis, which is the process by which plants use sunlight to convert carbon dioxide and water into glucose and oxygen.
When light has a higher frequency, it means the wavelength is shorter and the energy of the light is higher. Higher frequency light can have more pronounced effects, such as greater potential for damaging biological tissues and the ability to excite electrons to higher energy levels. Examples of high frequency light include ultraviolet and X-rays.
All objects do. There is none that does not absorb any.
The most energetic kind of visible light is violet light, while the least energetic kind is red light. This is because violet light has the shortest wavelength and highest frequency, while red light has the longest wavelength and lowest frequency among visible light colors.
Objects like opaque walls, curtains, and furniture block light from passing through them. Materials like black fabric, black paint, and activated charcoal absorb light by trapping and converting it into heat energy.
Yes, sunglasses absorb and block certain wavelengths of light, particularly harmful UV rays. This helps to reduce glare, protect the eyes from sun damage, and improve overall visual comfort and clarity.
It contain a pigment called Flavones.
spectroscope.....find out what kind of atoms are giving off light energy
Yes. The energy is given by plank's constant times the frequencie of the photon (remember that light is both particle and wave). So since blue light has higher frequency than green light, it is more energetic.
It depends on what kind of pigment the plant has. The color of the plant is reflected. That means every other color is obsorbed.
You didn't specify what kind of wave. Use the relationship: speed = frequency x wavelength.You didn't specify what kind of wave. Use the relationship: speed = frequency x wavelength.You didn't specify what kind of wave. Use the relationship: speed = frequency x wavelength.You didn't specify what kind of wave. Use the relationship: speed = frequency x wavelength.