4.3: Classifying Chemical Reactions - Precipitation Reactions

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Scott Van Bramer
Widener University

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Learning Objectives

Predict the solubility of common inorganic compounds by using solubility rules
Identify when a precipitation reaction will occur
Write a balanced chemical equation that describes what happens when a precipitation reaction occurs
Solve stoichiometry problems with precipitation reactions

Humans interact with one another in various and complex ways, and we classify these interactions according to common patterns of behavior. When two humans exchange information, we say they are communicating. When they exchange blows with their fists or feet, we say they are fighting. Faced with a wide range of varied interactions between chemical substances, scientists have likewise found it convenient (or even necessary) to classify chemical interactions by identifying common patterns of reactivity. This module will provide an introduction to precipitation reactions, one of the most prevalent types of chemical reactions.

Precipitation Reactions and Solubility Rules

A precipitation reaction is one in which dissolved substances react to form one (or more) solid products. Many reactions of this type involve the exchange of ions between ionic compounds in aqueous solution and are sometimes referred to as double displacement, double replacement, or metathesis reactions. These reactions are common in nature and are responsible for the formation of coral reefs in ocean waters and kidney stones in animals. They are used widely in industry for production of a number of commodity and specialty chemicals. Precipitation reactions also play a central role in many chemical analysis techniques, including spot tests used to identify metal ions and gravimetric methods for determining the composition of matter.

The extent to which a substance may be dissolved in water, or any solvent, is quantitatively expressed as its solubility, defined as the maximum concentration of a substance that can be achieved under specified conditions. Substances with relatively large solubilities are said to be soluble. A substance will precipitate when solution conditions are such that its concentration exceeds its solubility. Substances with relatively low solubilities are said to be insoluble, and these are the substances that readily precipitate from solution. For purposes of predicting the identities of solids formed by precipitation reactions, one may simply refer to patterns of solubility that have been observed for many ionic compounds (Table \(\PageIndex{1}\)).

Table \(\PageIndex{1}\): Solubilities of Common Ionic Compounds in Water
Always Soluble compounds contain
alkali metal cations (Li⁺, Na⁺, K⁺) ammonium ion \(\left(\ce{NH4+}\right)\) acetate \(\ce{(C2H3O2- )}\) ion nitrate \(\ce{(NO3- )}\) ion
Usually Soluble compounds contain	Except if they also contain
halide ions (F⁻, Cl⁻, Br⁻, and I⁻) sulfate \(\ce{(SO4^2- )}\) ion	halides of Ag⁺ and Pb²⁺ sulfates of Ag⁺ and Pb²⁺ and Ba²⁺, Ca²⁺, and Sr²⁺

Usually Insoluble compounds contain	Exceptions include
carbonate ion (\(\ce{(CO3^2- )}\) ) phosphate ion (\(\ce{(PO4^3- )}\) ) hydroxide ion (OH⁻)	carbonate with alkali metals or ammonium \(\left(\ce{NH4+}\right)\) phosphate with alkali metals or ammonium \(\left(\ce{NH4+}\right)\) hydroxides with alkali metals or ammonium \(\left(\ce{NH4+}\right)\), Ba²⁺, or Sr²⁺

A vivid example of precipitation is shown in Figure \(\PageIndex{1}\) when solutions of potassium iodide and lead nitrate are mixed, resulting in the formation of solid lead iodide. Lead iodide is a bright yellow solid that was formerly used as an artist’s pigment known as iodine yellow. The properties of pure PbI₂ crystals make them useful for fabrication of X-ray and gamma ray detectors. The balanced chemical reaction is:

\[\ce{2KI}(aq)+\ce{Pb(NO3)2}(aq)\rightarrow \ce{PbI2}(s)+\ce{2KNO3}(aq)\]

The formation of the precipitate observed in Figure \(\PageIndex{1}\) is consistent with the solubility guidelines: The only insoluble compound among all those involved is lead iodide, one of the exceptions to the general solubility of iodide salts.

The net ionic equation for this reaction is:

\[\ce{Pb^2+}(aq)+\ce{2I-}(aq)\rightarrow \ce{PbI2}(s)\]

A photograph is shown of a yellow green opaque substance swirled through a clear, colorless liquid in a test tube. — Figure \(\PageIndex{1}\): A precipitate of PbI₂ forms when solutions containing Pb²⁺ and I⁻ are mixed. (credit: Der Kreole/Wikimedia Commons)

The solubility guidelines in Table \(\PageIndex{1}\) will predict if a precipitation reaction occurs when solutions of soluble ionic compounds are mixed together. To do this, first identify all the ions present in the solution and then consider if any possible cation/anion combination forms an insoluble compound. For example, mixing solutions of silver nitrate and sodium fluoride will yield a solution containing Ag⁺, \(\ce{NO3-}\), Na⁺, and F⁻ ions. The possible combinations include the two ionic compounds originally present in the solutions, AgNO₃ and NaF, which are both soluble in water. And two additional ionic compounds NaNO₃ and AgF. The solubility guidelines state all nitrate salts are soluble, so NaNO₃ will not form a precipitate. However, Ag⁺ is an exception for halide ions so AgF forms a precipitate. The reaction is described by the following equations:

\[\ce{NaF}(aq)+\ce{AgNO3}(aq)\rightarrow \ce{AgF}(s)+\ce{NaNO3}(aq)\hspace{20px}\ce{(molecular)}\]

\[\ce{Na+}(aq)+\ce{F-}(aq)+\ce{Ag+}(aq)+\ce{NO3-}(aq)\rightarrow \ce{AgF}(s)+\ce{Na+}(aq)+\ce{NO3-}(aq)\hspace{20px}\ce{(complete\: ionic)}\]

\[\ce{Ag+}(aq)+\ce{F-}(aq)\rightarrow \ce{AgF}(s)\hspace{20px}\ce{(net\: ionic)}\]

Example \(\PageIndex{1}\): Predicting Precipitation Reactions

Predict the result of mixing reasonably concentrated solutions of the following ionic compounds. If precipitation is expected, write a balanced net ionic equation for the reaction.

potassium sulfate and barium nitrate
lithium chloride and silver acetate
lead nitrate and ammonium carbonate

Solution

(a) The two possible products for this combination are KNO₃ and BaSO₄. The solubility guidelines indicate BaSO₄ is insoluble, and so a precipitation reaction is expected. The net ionic equation for this reaction, derived in the manner detailed in the previous module, is

\[\ce{Ba^2+}(aq)+\ce{SO4^2-}(aq)\rightarrow \ce{BaSO4}(s) \nonumber\]

(b) The two possible products for this combination are LiC₂H₃O₂ and AgCl. The solubility guidelines indicate AgCl is insoluble, and so a precipitation reaction is expected. The net ionic equation for this reaction, derived in the manner detailed in the previous module, is

\[\ce{Ag+}(aq)+\ce{Cl-}(aq)\rightarrow \ce{AgCl}(s) \nonumber\]

(c) The two possible products for this combination are PbCO₃ and NH₄NO₃. The solubility guidelines indicate PbCO₃ is insoluble, and so a precipitation reaction is expected. The net ionic equation for this reaction, derived in the manner detailed in the previous module, is

\[\ce{Pb^2+}(aq)+\ce{CO3^2-}(aq)\rightarrow \ce{PbCO3}(s) \nonumber\]

Exercise \(\PageIndex{1}\)

Which solution could be used to precipitate the barium ion, Ba²⁺, in a water sample: sodium chloride, sodium hydroxide, or sodium sulfate? What is the formula for the expected precipitate?

Answer: sodium sulfate, BaSO₄

Solubility of Ionic Compounds - Video

Video Topics

This video discusses how to predict if a given ionic compound is soluble or insoluble in water. Solubility rules make these prediction based on the species making up the ionic compound. If the ionic compound is soluble it will disassociate in water to form strong electrolyte aqueous solution.

Link to Video

Predicting the Solubility of Ionic Compounds: https://youtu.be/U3QNwnfmvGU

Determining the Products of a Precipitation Reaction - Video

Video Topics

During a precipitation reaction, also called a double substitution reaction, the ions of two soluble ionic compounds recombine to form an insoluble ionic compound and a precipitate (solid) forms. This video discusses how to determining the molecular formula of the precipitate given the ionic species present in the reactants. In particular, combining different charged species to create a neutral compounds will be discussed.

Link to Video

Determining the Products for Precipitation Reactions: https://youtu.be/r0kYeZVuTAM

Determining the Net Ionic Equation - Video

Determining Net Ionic Equation for a Precipitation Reaction: https://youtu.be/AMJz1Sdz8IA

Gravimetric Analysis

A gravimetric analysis is one in which a sample is subjected to some treatment that causes a change in the physical state of the analyte that permits its separation from the other components of the sample. Mass measurements of the sample, the isolated analyte, or some other component of the analysis system, used along with the known stoichiometry of the compounds involved, permit calculation of the analyte concentration. Gravimetric methods were the first techniques used for quantitative chemical analysis, and they remain important tools in the modern chemistry laboratory.

The required change of state in a gravimetric analysis may be achieved by various physical and chemical processes. For example, the moisture (water) content of a sample is routinely determined by measuring the mass of a sample before and after it is subjected to a controlled heating process that evaporates the water. Also common are gravimetric techniques in which the analyte is subjected to a precipitation reaction of the sort described earlier in this chapter. The precipitate is typically isolated from the reaction mixture by filtration, carefully dried, and then weighed (Figure \(\PageIndex{2}\)). The mass of the precipitate may then be used, along with relevant stoichiometric relationships, to calculate analyte concentration.

"A photo is shown of a flask and funnel used for filtration. The flask contains a slightly opaque liquid filtrate with a slight yellow tint. A funnel, which contains a bright yellow and orange material, sits atop the flask. The flask is held in place by a clamp and is connected to a vacuum line. The connection between the funnel and flask is sealed with a rubber bung or gasket." — Figure \(\PageIndex{2}\): Precipitate may be removed from a reaction mixture by filtration.

Example \(\PageIndex{2}\): Gravimetric Analysis

A 0.4550-g solid mixture containing MgSO₄ is dissolved in water and treated with an excess of Ba(NO₃)₂, resulting in the precipitation of 0.6168 g of BaSO₄.

\[\ce{MgSO4}(aq)+\ce{Ba(NO3)2}(aq)\rightarrow \ce{BaSO4}(s)+\ce{Mg(NO3)2}(aq) \nonumber \]

What is the concentration (percent) of MgSO₄ in the original 0.4550 g solid mixture?

Solution

The plan for this calculation is similar to others used in stoichiometric calculations, the central step being the connection between the moles of BaSO₄ and MgSO₄ through their stoichiometric factor. Once the mass of MgSO₄ is computed, it may be used along with the mass of the sample mixture to calculate the requested percentage concentration.

The mass of MgSO₄ that would yield the provided precipitate mass is

\[\mathrm{0.6168\:\cancel{g\: BaSO_4}\times \dfrac{1\:\cancel{mol\: BaSO_4}}{233.43\:\cancel{g\: BaSO_4}}\times \dfrac{1\:\cancel{mol\: MgSO_4}}{1\:\cancel{mol\: BaSO_4}}\times \dfrac{120.37\:g\: MgSO_4}{1\:\cancel{mol\: MgSO_4}}=0.3181\:g\: MgSO_4} \nonumber \]

The concentration of MgSO₄ in the sample mixture is then calculated to be

\[\begin{align*}
\ce{percent\: MgSO4}&=\ce{\dfrac{mass\: MgSO4}{mass\: sample}}\times100\%\\
\mathrm{\dfrac{0.3181\: g}{0.4550\: g}}\times100\%&=69.91\%
\end{align*} \nonumber \]

Exercise \(\PageIndex{2}\)

What is the percent of chloride ion in a sample if 1.1324 g of the sample produces 1.0881 g of AgCl when treated with excess Ag⁺?

\[\ce{Ag+}(aq)+\ce{Cl-}(aq)\rightarrow \ce{AgCl}(s) \nonumber \]

Answer: 23.76%

Summary

Chemical reactions are classified according to similar patterns of behavior. A large number of important reactions are included in three categories: precipitation, acid-base, and oxidation-reduction (redox). Precipitation reactions involve the formation of one or more insoluble products. Acid-base reactions involve the transfer of hydrogen ions between reactants. Redox reactions involve a change in oxidation number for one or more reactant elements. Writing balanced equations for some redox reactions that occur in aqueous solutions is simplified by using a systematic approach called the half-reaction method.

Glossary

insoluble: of relatively low solubility; dissolving only to a slight extent

precipitate

insoluble product that forms from reaction of soluble reactants

precipitation reaction: reaction that produces one or more insoluble products; when reactants are ionic compounds, sometimes called double-displacement or metathesis

salt: ionic compound that can be formed by the reaction of an acid with a base that contains a cation and an anion other than hydroxide or oxide

single-displacement reaction: (also, replacement) redox reaction involving the oxidation of an elemental substance by an ionic species

soluble: of relatively high solubility; dissolving to a relatively large extent

solubility: the extent to which a substance may be dissolved in water, or any solvent

analyte

chemical species of interest
gravimetric analysis: quantitative chemical analysis method involving the separation of an analyte from a sample by a physical or chemical process and subsequent mass measurements of the analyte, reaction product, and/or sample
quantitative analysis: the determination of the amount or concentration of a substance in a sample

Contributors and Attributions

Paul Flowers (University of North Carolina - Pembroke), Klaus Theopold (University of Delaware) and Richard Langley (Stephen F. Austin State University) with contributing authors. Textbook content produced by OpenStax College is licensed under a Creative Commons Attribution License 4.0 license. Download for free at http://cnx.org/contents/85abf193-2bd...a7ac8df6@9.110).
Prof. Steven Farmer (Sonoma State University)

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