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How do the hair cells in your ears respond to different wavelengths of vibrations?
Wiki User
∙ 14y ago
The hairs in the inner ear have a small amount of fluid surrounding them and as sound passes through the ear canal to the tympanic membrane the stapes also vibrates and sends those vibrations to the cochlea where the hair cells are in that fluid. The vibrations are translated to sound through the optic nerve and sent to the brain as high and low sounds. Another thing to note about the hairs is that when we experience a back and forth motion such as in a boat the fluid makes the hairs swish back and forth causing equilibrium problems and nausea and vomiting (sea sickness or motion sickness).
Wiki User
∙ 14y ago
Hair cells in the inner ear respond to different wavelengths of vibrations by bending in response to the specific frequency of the sound wave. Different hair cells are specialized to respond to different frequencies, allowing the brain to interpret the pitch of the sound being heard.
Wiki User
∙ 15y agoNever heard that hair cells can hear.
Wiki User
∙ 10y agoamplitude
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Which receptor cells help distinguish different wavelengths of light?
Cones are the receptor cells in the retina that help distinguish different wavelengths of light. There are three types of cones that are sensitive to different wavelengths (red, green, and blue), allowing us to perceive a wide spectrum of colors.
What does the cone cell look like?
Cone cells are photoreceptor cells in the retina that are responsible for color vision and high visual acuity. These cells are shaped like a cone and contain pigments that allow them to respond to different wavelengths of light. In humans, cone cells are primarily concentrated in the fovea, the center of the retina.
Which receptor Cells most directly enable us to distinguish different wavelengths of light?
Cones in the retina are the receptor cells that enable us to distinguish different wavelengths of light. There are three types of cones that are sensitive to different wavelengths, allowing us to perceive colors.
Is the eye cell a cone cell?
Cone cells are a type of photoreceptor cell in the retina of the eye that are responsible for color vision and high visual acuity. Each cone cell contains different pigments that respond to different wavelengths of light. Therefore, not all eye cells are cone cells, as the retina also contains rod cells, another type of photoreceptor cell that is more sensitive to low light levels and is responsible for night vision.
What is the name of the cells in the nephron that respond to ADH and aldosterone?
The cells in the nephron that respond to ADH are called principal cells, while the cells that respond to aldosterone are called intercalated cells. These cells play a crucial role in regulating the reabsorption of water and electrolytes in the kidneys.
How does the ear interpret frequency of sound?
The cochlea in the inner ear contains hair cells that respond to specific frequencies of sound vibrations. Different frequencies cause different hair cells to vibrate, which stimulates the auditory nerve to send signals to the brain. The brain then processes these signals as different pitches or frequencies of sound.
Which receptor cells help distinguish different wavelengths of light?
Cones are the receptor cells in the retina that help distinguish different wavelengths of light. There are three types of cones that are sensitive to different wavelengths (red, green, and blue), allowing us to perceive a wide spectrum of colors.
Cone cells are color photoreceptors that use different retinal molecules to absorb different wavelengths of light?
While cone cells are the color photoreceptors in the eye, they use different opsin molecules for the absorption of different wavelengths of light. So the answer would be false.
What does the cone cell look like?
Cone cells are photoreceptor cells in the retina that are responsible for color vision and high visual acuity. These cells are shaped like a cone and contain pigments that allow them to respond to different wavelengths of light. In humans, cone cells are primarily concentrated in the fovea, the center of the retina.
Which receptor Cells most directly enable us to distinguish different wavelengths of light?
Cones in the retina are the receptor cells that enable us to distinguish different wavelengths of light. There are three types of cones that are sensitive to different wavelengths, allowing us to perceive colors.
Photosensitive receptor cells of the retina make the perception of color possible?
Photosensitive receptor cells in the retina, called cones, are responsible for color vision. These cones contain different pigments that respond to different wavelengths of light, allowing us to perceive a range of colors. The brain processes the signals from these cones to create a perception of color.
How do humans see different wavelengths of light?
Humans see different wavelengths of light due to the presence of specialized cells in the retina of the eye called cones. There are three types of cones, each sensitive to a specific range of wavelengths (short, medium, and long wavelengths). When light enters the eye, these cones convert the different wavelengths into electrical signals that are then processed by the brain to create the perception of color.
Cells of different tissues and organs respond to the same hormone if they have the same kind of molecules?
Yes, cells can respond to the same hormone if they have the specific receptors that can bind to that hormone. The presence of these receptors allows cells to detect and respond to hormonal signals, regardless of whether they are from the same tissue or organ.
Are all wavelengths of light equal in phototropism?
No, not all wavelengths of light are equal in phototropism. Plants are most sensitive to blue and red light for their growth and development, as these wavelengths are absorbed by specific photoreceptors in the plant cells. Green light, on the other hand, is less effective in stimulating phototropic responses.
What is the source of different colors that you see?
Different colors are produced when objects absorb and reflect different wavelengths of light. The human eye contains specialized cells called cones that are sensitive to these different wavelengths, allowing us to perceive colors. The brain then processes this information to create the perception of color.
What causes our perception of different colors of light?
Our perception of different colors of light is caused by the wavelength of light. Shorter wavelengths appear as blue or violet, while longer wavelengths appear as red or orange. Our eyes have specialized cells called cones that detect different wavelengths of light and send signals to our brains, allowing us to perceive color.
Is the eye cell a cone cell?
Cone cells are a type of photoreceptor cell in the retina of the eye that are responsible for color vision and high visual acuity. Each cone cell contains different pigments that respond to different wavelengths of light. Therefore, not all eye cells are cone cells, as the retina also contains rod cells, another type of photoreceptor cell that is more sensitive to low light levels and is responsible for night vision.
