If it didn't reflect blue, then there wouldn't be any blue light from it to enter your eye,
and you wouldn't see any blue.
If the object looks blue, then you know two things:
1). There was some blue light hitting the object.
2). The blue light hitting the object wasn't all absorbed. At least
some of it was reflected from the object, toward your eye.
The color of an opaque object is determined by the wavelengths of light it reflects. The object absorbs certain wavelengths of light and reflects others, which our eyes perceive as color. For example, an object that appears red absorbs most colors of light except for red, which it reflects.
Reflects, other wavelengths (colours) are absorbed.
The color of an object depends on the wavelengths of light that it reflects. When an object appears yellow in daylight, it reflects mostly yellow light. When illuminated with red light, which contains only red wavelengths, the object reflects primarily red light, making it appear red. When illuminated with magenta light, which contains red and blue wavelengths, the object absorbs the blue light and reflects only the red, appearing red.
No, under green light a red object will still appear red. This is because the color of an object is determined by the wavelengths of light it reflects, and green light does not change the wavelengths that a red object reflects.
The object appears to be a certain color because it absorbs certain wavelengths of light and reflects others. The reflected light enters our eyes and stimulates the cone cells in our retinas, which then send signals to our brain to interpret the color of the object based on the wavelengths of light it reflects.
The color of an opaque object is determined by the wavelengths of light it reflects. The object absorbs certain wavelengths of light and reflects others, which our eyes perceive as color. For example, an object that appears red absorbs most colors of light except for red, which it reflects.
An object appears a certain color because it reflects specific wavelengths in the visible spectrum while absorbing others. For example, a blue object reflects blue wavelengths and absorbs other colors.
Reflects, other wavelengths (colours) are absorbed.
The color of an object depends on the wavelengths of light that it reflects. When an object appears yellow in daylight, it reflects mostly yellow light. When illuminated with red light, which contains only red wavelengths, the object reflects primarily red light, making it appear red. When illuminated with magenta light, which contains red and blue wavelengths, the object absorbs the blue light and reflects only the red, appearing red.
No, under green light a red object will still appear red. This is because the color of an object is determined by the wavelengths of light it reflects, and green light does not change the wavelengths that a red object reflects.
The object appears to be a certain color because it absorbs certain wavelengths of light and reflects others. The reflected light enters our eyes and stimulates the cone cells in our retinas, which then send signals to our brain to interpret the color of the object based on the wavelengths of light it reflects.
An object appears yellow because it reflects wavelengths of light in the yellow part of the visible spectrum and absorbs other wavelengths. Our eyes perceive this reflected light as the color yellow.
If an object appears blue, it means that it reflects and scatters blue light while absorbing other colors. The object appears blue because our eyes detect the reflected blue light. This phenomenon is based on the object's molecular structure and the wavelengths of light it interacts with.
The color produced when objects reflect light depends on the wavelengths of light that are reflected. For example, an object that reflects all visible wavelengths of light appears white, while an object that absorbs all wavelengths appears black. Other colors are produced based on the specific wavelengths that are reflected.
An object's color is comprised of the wavelengths of light that it reflects - so an orange object reflects reds and yellows while absorbing blues and greens, while a green object is the opposite.
An object that reflects red light and absorbs other colors appears red because it is reflecting red wavelengths and absorbing all other colors. This selective reflection of light is due to the object's specific molecular structure or pigmentation which determines how it interacts with different wavelengths of light.
When light shines on different colored objects, each object absorbs certain wavelengths of light and reflects others. The reflected light is what we see as the color of the object. For example, a red object absorbs most light wavelengths except for red, which it reflects. Therefore, we perceive the object as red.