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Chapter 7: Problem 32

Scientists use emission spectra to confirm the presence of an element in materials of unknown composition. Why is this possible?

Short Answer

Expert verified
Emission spectra can be used to confirm the presence of an element in materials of unknown composition because each element has a unique emission spectrum, which is determined by its electron configuration. By comparing the emission spectra of the unknown material with known spectra of various elements, scientists can identify and confirm the presence of specific elements within the sample.

Step by step solution

01

Introduction to Emission Spectra

Emission spectra refer to the specific pattern of wavelengths of light that are emitted by atoms of an element when they are excited. These patterns are unique to each element because each element has a distinct electron configuration, and these configurations determine the energy levels available for electrons to jump between.
02

Excitation and Relaxation of Electrons

When an atom is subjected to an external energy source, such as heat or an electric discharge, its electrons absorb the energy and jump from a lower energy level to a higher one. This is called excitation. When the electrons relax back down to their original energy levels, they release the absorbed energy in the form of a specific wavelength of light. The collection of these emitted wavelengths results in an emission spectrum.
03

Uniqueness of Emission Spectra

Since each element has its own electron configuration, the energy levels and the differences between them are unique for each element. This means the wavelengths of light emitted during the relaxation process will also be unique for each element. As a result, the emission spectrum produced by one element will be different from those produced by other elements.
04

Identifying Elements Through Emission Spectra

Scientists can use the unique emission spectra of elements to identify them. By analyzing the wavelength patterns produced by an unknown material and comparing them to the known emission spectra of various elements, scientists can determine which elements are present in the material. This method is valuable not only for determining the composition of unknown materials but also for confirming the presence of certain elements in a sample. In summary, emission spectra can be used to confirm the presence of an element in materials of unknown composition because each element has a unique emission spectrum, which is determined by its electron configuration. By comparing the emission spectra of the unknown material with known spectra of various elements, scientists can identify and confirm the presence of specific elements within the sample.

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Most popular questions from this chapter

The work function of an element is the energy required to remove an electron from the surface of the solid element. The work function for lithium is \(279.7 \mathrm{~kJ} / \mathrm{mol}\) (that is, it takes \(279.7 \mathrm{~kJ}\) of energy to remove one mole of electrons from one mole of Li atoms on the surface of Li metal). What is the maximum wavelength of light that can remove an electron from an atom on the surface of lithium metal?

Write the expected electron configurations for each of the following atoms: \(\mathrm{Sc}, \mathrm{Fe}, \mathrm{P}, \mathrm{Cs}\), Eu, \(\mathrm{Pt}, \mathrm{Xe}, \mathrm{Br}\).

Cesium was discovered in natural mineral waters in 1860 by R. W. Bunsen and G. R. Kirchhoff using the spectroscope they invented in \(1859 .\) The name came from the Latin caesius ("sky blue") because of the prominent blue line observed for this element at \(455.5 \mathrm{~nm} .\) Calculate the frequency and energy of a photon of this light.

Give the name and formula of each of the binary compounds formed from the following elements. a. \(\mathrm{Li}\) and \(\mathrm{N}\) b. \(\mathrm{Na}\) and \(\mathrm{Br}\) c. \(\mathrm{K}\) and \(\mathrm{S}\)

Photogray lenses incorporate small amounts of silver chloride in the glass of the lens. When light hits the AgCl particles, the following reaction occurs: $$ \mathrm{AgCl} \stackrel{h v}{\longrightarrow} \mathrm{Ag}+\mathrm{Cl} $$ The silver metal that is formed causes the lenses to darken. The enthalpy change for this reaction is \(3.10 \times 10^{2} \mathrm{~kJ} / \mathrm{mol}\). Assuming all this energy must be supplied by light, what is the maximum wavelength of light that can cause this reaction?
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