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Chapter 6: Problem 17

Arrange the following kinds of electromagnetic radiation in order of increasing wavelength: infrared, green light, red light, radio waves, X rays, ultraviolet light.

Short Answer

Expert verified
X rays, Ultraviolet light, Green light, Red light, Infrared, Radio waves.

Step by step solution

01

Remember the electromagnetic spectrum

The electromagnetic spectrum is the range of wavelengths, frequencies, and energies of all possible electromagnetic waves. From low frequency/long wavelength to high frequency/short wavelength, the types of waves are: Radio waves, Microwaves, Infrared, Visible light (red, orange, yellow, green, blue, indigo, and violet), Ultraviolet light, X rays, and Gamma rays.
02

Identify the positions of the given radiation types

According to the electromagnetic spectrum, the given types of radiation have the following positions: 1. Radio waves 2. Infrared 3. Visible light (including red and green light) 4. Ultraviolet light 5. X rays
03

Arrange in order of increasing wavelength

As we move from low frequency/long wavelength to high frequency/short wavelength in the electromagnetic spectrum: 1. Radio waves have the longest wavelength among the given radiation types. 2. Infrared has the next longest wavelength. 3. Visible light, including red and green light, has wavelengths shorter than infrared. Red light has a longer wavelength than green light. 4. Ultraviolet light has a shorter wavelength than visible light. 5. X rays have the shortest wavelength among the given radiation types.
04

Write the final order

Based on our knowledge of the electromagnetic spectrum, the given radiation types can be arranged in order of increasing wavelength as follows: X rays, Ultraviolet light, Green light, Red light, Infrared, Radio waves.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Wavelength
Wavelength is a fundamental concept when it comes to understanding the electromagnetic spectrum. Essentially, a wavelength is the distance between two consecutive peaks (or troughs) of a wave. It is usually measured in meters, centimeters, or nanometers.
  • Longer wavelengths correspond to lower energy and frequency.
  • Shorter wavelengths have higher energy and frequency.
This concept is key to arranging different types of electromagnetic radiation in order of increasing wavelength. When comparing two types of radiation, the one with longer wavelength will have lower energy.
Understanding how wavelength relates to energy and frequency helps explain why radio waves and X-rays appear on opposite ends of the electromagnetic spectrum. Radio waves have long wavelengths, while X-rays have short wavelengths, indicating higher energy levels.
Electromagnetic Radiation
Electromagnetic radiation encompasses all types of electromagnetic waves, regardless of whether we can see them. These waves travel through space at the speed of light and vary widely in wavelength and frequency.
  • Radio waves are on one extreme, with long wavelengths and low frequencies.
  • Gamma rays are on the opposite extreme, featuring very short wavelengths and high frequencies.
Each type of electromagnetic radiation has unique properties and applications.
For example:
  • Radio waves are used for broadcasting signals, like music and news.
  • Infrared radiation is often used in remote controls and thermal imaging.
  • Ultraviolet light can cause sunburn, but also helps in the production of Vitamin D.
Understanding electromagnetic radiation helps in harnessing its properties for various technological advances and daily applications.
Visible Light
Visible light is the portion of the electromagnetic spectrum that is detectable by the human eye. It ranges from approximately 400 nanometers (violet) to 700 nanometers (red) in wavelength.
  • Red light has the longest wavelength within visible light, at around 700 nanometers.
  • Violet light has the shortest, at about 400 nanometers.
In between these extremes, we have the familiar colors of the rainbow: orange, yellow, green, blue, and indigo. This range of colors is what we refer to when we talk about 'visible light.'
Our understanding of visible light is not just limited to its beauty—it is crucial in areas like photography, art, and optical technology. Using this knowledge, it's easier to determine the sequence of light waves in the electromagnetic spectrum, from red light's longer wavelengths to violet light's shorter wavelengths.

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Most popular questions from this chapter

The first 25 years of the twentieth century were momentous for the rapid pace of change in scientists' understanding of the nature of matter. (a) How did Rutherford's experiments on the scattering of \(\alpha\) particles by a gold foil set the stage for Bohr's theory of the hydrogen atom? (b) In what ways is de Broglie's hypothesis, as it applies to electrons, consistent with J. J. Thomson's conclusion that the electron has mass? In what sense is it consistent with proposals preceding Thomson's work that the cathode rays are a wave phenomenon?

Calculate the uncertainty in the position of (a) an electron moving at a speed of \((3.00 \pm 0.01) \times 10^{5} \mathrm{~m} / \mathrm{s},(\mathbf{b})\) a neutron moving at this same speed. (The masses of an electron and a neutron are given in the table of fundamental constants in the inside cover of the text.) (c) Based on your answers to parts (a) and (b), which can we know with greater precision, the position of the electron or of the neutron?

Give the values for \(n, l,\) and \(m_{l}\) for \((\mathbf{a})\) each orbital in the \(3 p\) subshell, (b) each orbital in the \(4 f\) subshell.

Use the de Broglie relationship to determine the wavelengths of the following objects: (a) an \(85-\mathrm{kg}\) person skiing at \(50 \mathrm{~km} / \mathrm{hr},(\mathbf{b})\) a \(10.0-\mathrm{g}\) bullet fired at \(250 \mathrm{~m} / \mathrm{s},(\mathbf{c})\) a lithium atom moving at \(2.5 \times 10^{5} \mathrm{~m} / \mathrm{s},(\mathbf{d})\) an ozone \(\left(\mathrm{O}_{3}\right)\) molecule in the upper atmosphere moving at \(550 \mathrm{~m} / \mathrm{s}\).

Does the hydrogen atom "expand" or "contract" when an electron is excited from the \(n=1\) state to the \(n=3\) state?
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