What does red green and blue make 2024?

Hello there! My name is Dr. Hue, and I've dedicated my life to the study of color. Color theory, color mixing, the psychology of color – it all fascinates me! You've come to the right place with your question about red, green, and blue. Let's dive into the fascinating world of these primary colors and what happens when you blend them together.

When we talk about red, green, and blue making something, it's crucial to distinguish between two fundamentally different ways of mixing colors:

1. Subtractive Color Mixing:

This method involves mixing physical substances like pigments found in paints, inks, and dyes. Think about what happens when you blend watercolors. Each pigment absorbs certain wavelengths of light and reflects others. The reflected wavelengths reach our eyes, and our brain interprets those signals as specific colors.

* The Key Idea: In subtractive mixing, each added pigment *subtracts* more wavelengths from the light that's ultimately reflected.

* **Red, Green, and Blue in Subtractive Mixing:** Interestingly, in this system, red, green, and blue aren't the primary colors. Instead, we have:
* Cyan (a bluish-green)
* Magenta (a purplish-red)
* Yellow

These three are the primary colors of subtractive mixing because you can't create them by mixing other pigments. However, you can combine them to create a wide range of colors, including approximations of red, green, and blue.

* Mixing Cyan, Magenta, and Yellow: Now, if you were to mix cyan, magenta, and yellow (the subtractive primaries) in theory, you'd get a muddy brown or black. Why? Because you're essentially absorbing most of the wavelengths of light, leaving little to be reflected back to your eye.

2. Additive Color Mixing:

This is where red, green, and blue truly shine! Additive mixing involves mixing light sources. Instead of pigments absorbing light, we have light sources directly emitting specific wavelengths.

* How it Works: Our eyes have specialized photoreceptor cells called cones that are sensitive to different wavelengths of light. We have cones primarily sensitive to red, green, and blue wavelengths. When these cones are stimulated in various combinations, our brain perceives a wide spectrum of colors.

* Red, Green, and Blue as Primary Colors: In additive color mixing, red, green, and blue are considered primary colors because you cannot create them by mixing other light sources.

* The Magic of Mixing: When you combine these primary lights:
* Red + Green = Yellow
* Red + Blue = Magenta
* Green + Blue = Cyan
* Red + Green + Blue = White

Yes, you read that right! Mixing red, green, and blue light produces white light. This is the fundamental principle behind how your computer screen, television, and smartphone display millions of colors. By varying the intensity of these three primary lights, these devices create the illusion of a vast color spectrum.

In Conclusion

So, the answer to your question depends on how you're mixing red, green, and blue. In subtractive mixing (like with paints), you wouldn't get a satisfying result. But in additive mixing (the realm of light), red, green, and blue combine to create the purest white light!

The secondary colors of RGB, cyan, magenta, and yellow, are formed by the mixture of two of the primaries and the exclusion of the third. Red and green combine to make yellow, green and blue make cyan, blue and red make magenta. ... White light is created when all colors of the EM spectrum converge in full intensity.