Question

Describe how the frequency of electromagnetic radiation is related to its wavelength.

Short answer

Frequency and wavelength have an inverse relationship: as one increases, the other decreases.

Step-by-step solution

Understanding the Relationship

The frequency of electromagnetic radiation is inversely related to its wavelength. If you know the frequency (\(f\)), you can find the wavelength (\(\lambda\)) using the formula: \(c = \lambda \cdot f\), where \(c\) is the speed of light in a vacuum, approximately \(3 \times 10^8\) meters per second.

Solving for Wavelength

Rearrange the relationship formula to solve for wavelength: \(\lambda = \frac{c}{f}\). This shows that as the frequency increases, the wavelength decreases, provided that the speed of light remains constant.

Solving for Frequency

Similarly, to solve for frequency given the wavelength, rearrange the formula to: \(f = \frac{c}{\lambda}\). This shows that as the wavelength increases, the frequency decreases, illustrating their inverse relationship.

Key concepts

Frequency

Frequency is a key concept when discussing electromagnetic radiation. It refers to how many cycles of a wave pass a point in one second. This is measured in units called Hertz (Hz). Each type of electromagnetic wave, such as light or radio waves, has a specific frequency.

Understanding frequency helps us categorize different types of electromagnetic waves. For example, radio waves have a low frequency compared to X-rays, which have a high frequency. This means:

• Low-frequency waves are typically less energetic.
• High-frequency waves carry more energy.

The frequency (\(f\)) of a wave is directly related to its energy, which means that the higher the frequency, the more energy the wave carries. In the realm of electromagnetic radiation, knowing the frequency allows scientists to infer a lot about a wave's characteristics and potential effects.

Wavelength

Wavelength is another crucial concept in the study of electromagnetic radiation. It represents the distance between two consecutive peaks or troughs of a wave. The unit of measurement for wavelength is usually meters, nanometers, or micrometers, depending on the scale.

Wavelength is inversely related to frequency. This means that as one increases, the other decreases. To understand wavelength more clearly, consider:

• Longer wavelengths, like those of radio waves, are associated with lower frequency.
• Shorter wavelengths, like those of gamma rays, correspond to higher frequency.

Knowing the wavelength of electromagnetic radiation allows scientists to predict how it will interact with different materials. For instance, shorter wavelengths like X-rays can penetrate materials, which is why they are used in medical imaging. By studying wavelength, we can understand the behavior and properties of electromagnetic waves more thoroughly.

Speed of Light

The speed of light is a fundamental constant in the universe. Denoted by the letter \(c\), it is approximately \(3 \times 10^8\) meters per second. This speed is what all electromagnetic waves travel at in a vacuum, regardless of their frequency or wavelength.

This constant is an essential part of the relationship between frequency and wavelength, as described by the equation \(c = \lambda \cdot f\). This shows that the speed of light is the product of a wave’s wavelength (\(\lambda\)) and frequency (\(f\)). Because the speed of light is constant, a change in frequency must result in an inverse change in wavelength, and vice versa, to satisfy the equation.

The speed of light not only helps define the relationship between wavelength and frequency but is also a critical factor in technologies like fiber optics and communication systems. Understanding the speed of light allows scientists and engineers to design better systems for transmitting information across the globe.