https://ejercicios-fyq.com/ Ejercicios Resueltos, Situaciones de aprendizaje y VÍDEOS de Física y Química para Secundaria y Bachillerato es SPIP - www.spip.net https://ejercicios-fyq.com/local/cache-vignettes/L144xH25/siteon0-da713.png?1758361862 https://ejercicios-fyq.com/ 25 144 https://ejercicios-fyq.com/Application-of-limiting-reagent-purity-of-reagents-and-reaction-yield-8281 https://ejercicios-fyq.com/Application-of-limiting-reagent-purity-of-reagents-and-reaction-yield-8281 2024-08-09T03:25:18Z text/html es F_y_Q Chemical reactions Solutions Purity Limiting reagent Yield SOLVED <p>You have 87 g of silver nitrate, with purity, reacting with 50 mL of a hydrochloric acid solution, by mass concentration and density 1.07 g/mL, producing silver chloride and nitric acid, with a reaction yield of . <br class='autobr' /> a) Write the chemical reaction and balance it if necessary. <br class='autobr' /> b) Calculate the amount of silver chloride and nitric acid produced in the reaction. <br class='autobr' /> c) Determine the amount of the excess reagent that does not react. <br class='autobr' /> Atomic masses: H = 1; O = 16; N = 14; Cl = 35.5; Ag = 108.</p> - <a href="https://ejercicios-fyq.com/Chemical-reactions-270" rel="directory">Chemical reactions</a> / <a href="https://ejercicios-fyq.com/Chemical-reactions" rel="tag">Chemical reactions</a>, <a href="https://ejercicios-fyq.com/Solutions" rel="tag">Solutions</a>, <a href="https://ejercicios-fyq.com/Purity" rel="tag">Purity</a>, <a href="https://ejercicios-fyq.com/Limiting-reagent" rel="tag">Limiting reagent</a>, <a href="https://ejercicios-fyq.com/Yield" rel="tag">Yield</a>, <a href="https://ejercicios-fyq.com/SOLVED" rel="tag">SOLVED</a> <div class='rss_texte'><p>You have 87 g of silver nitrate, with <img src='https://ejercicios-fyq.com/local/cache-vignettes/L44xH14/2bf66c4f215d4c415da7f6b3d6319cc3-e2b06.png?1733013185' style='vertical-align:middle;' width='44' height='14' alt="87.9\ \%" title="87.9\ \%" /> purity, reacting with 50 mL of a hydrochloric acid solution, <img src='https://ejercicios-fyq.com/local/cache-vignettes/L32xH14/e51c2fe4de430b9b440b61ec3ed8449a-0bb01.png?1732974743' style='vertical-align:middle;' width='32' height='14' alt="37\ \%" title="37\ \%" /> by mass concentration and density 1.07 g/mL, producing silver chloride and nitric acid, with a reaction yield of <img src='https://ejercicios-fyq.com/local/cache-vignettes/L44xH14/6870c0e169d2ecbf015e1c48045e4f07-057d0.png?1733013185' style='vertical-align:middle;' width='44' height='14' alt="89.2\ \%" title="89.2\ \%" />.</p> <p>a) Write the chemical reaction and balance it if necessary.</p> <p>b) Calculate the amount of silver chloride and nitric acid produced in the reaction.</p> <p>c) Determine the amount of the excess reagent that does not react.</p> <p>Atomic masses: H = 1; O = 16; N = 14; Cl = 35.5; Ag = 108.</math></p></div> <hr /> <div <div class='rss_ps'><p>a) First, it is necessary to write the chemical reaction and check its stoichiometry: <br/> <br/> <p class="spip" style="text-align: center;"><img src='https://ejercicios-fyq.com/local/cache-TeX/703e3a812fd0cf31ea9d443863b745fd.png' style="vertical-align:middle;" width="286" height="25" alt="\fbox{\color[RGB]{192,0,0}{\textbf{\ce{AgNO3 + HCl -> AgCl + HNO3}}}}" title="\fbox{\color[RGB]{192,0,0}{\textbf{\ce{AgNO3 + HCl -> AgCl + HNO3}}}}" /></p> <br/> The stoichiometry of the reaction is 1:1, which will greatly simplify the calculations. <br/> <br/> b) You need to determine the limiting reagent in the reaction, and for this, you must know the moles of each reagent you have at the beginning. Be very careful with the data treatment because you must consider that the reagents are <b>not</b> pure. <br/> <br/> <u>Moles of pure silver nitrate</u>: <br/> <br/> <img src='https://ejercicios-fyq.com/local/cache-TeX/60a5149ed419c0dbb21fa59daaee25e5.png' style="vertical-align:middle;" width="419" height="41" alt="87\ \cancel{g\ \ce{AgNO3^{\prime}}}\cdot \frac{87.9\ \cancel{g}\ \ce{AgNO3}}{100\ \cancel{g\ \ce{AgNO3^{\prime}}}}\cdot \frac{1\ mol}{170\ \cancel{g}} = \color[RGB]{0,112,192}{\textbf{0.45\ mol\ \ce{AgNO3}}}" title="87\ \cancel{g\ \ce{AgNO3^{\prime}}}\cdot \frac{87.9\ \cancel{g}\ \ce{AgNO3}}{100\ \cancel{g\ \ce{AgNO3^{\prime}}}}\cdot \frac{1\ mol}{170\ \cancel{g}} = \color[RGB]{0,112,192}{\textbf{0.45\ mol\ \ce{AgNO3}}}" /> <br/> <br/> <u>Moles of pure hydrochloric acid</u>: <br/> <br/> <img src='https://ejercicios-fyq.com/local/cache-TeX/b6535057ab306780c09f6e0b5426548b.png' style="vertical-align:middle;" width="420" height="42" alt="50\ \cancel{mL\ D}\cdot \frac{1.07\ \cancel{g\ D}}{1\ \cancel{mL\ D}}\cdot \frac{37\ \cancel{g}\ \ce{HCl}}{100\ \cancel{g\ D}}\cdot \frac{1\ mol}{36.5\ \cancel{g}} = \color[RGB]{0,112,192}{\textbf{0.542\ mol\ \ce{HCl}}}" title="50\ \cancel{mL\ D}\cdot \frac{1.07\ \cancel{g\ D}}{1\ \cancel{mL\ D}}\cdot \frac{37\ \cancel{g}\ \ce{HCl}}{100\ \cancel{g\ D}}\cdot \frac{1\ mol}{36.5\ \cancel{g}} = \color[RGB]{0,112,192}{\textbf{0.542\ mol\ \ce{HCl}}}" /> <br/> <br/> It is easy to conclude that the <b>limiting reagent</b> is <img src='https://ejercicios-fyq.com/local/cache-TeX/2b83e9a5a01eb0ddbac21852ba71e296.png' style="vertical-align:middle;" width="59" height="16" alt="\color[RGB]{2,112,20}{\textbf{\ce{AgNO_3}}}" title="\color[RGB]{2,112,20}{\textbf{\ce{AgNO_3}}}" /> because it is the one with the fewest initial moles, and the stoichiometry is 1:1. <br/> <br/> Since the reaction does not go to completion, you will calculate how many moles react from the initial 0.45 moles. <br/> <br/> <img src='https://ejercicios-fyq.com/local/cache-TeX/2119438b53319aeec7e08c58c6d5a41c.png' style="vertical-align:middle;" width="320" height="35" alt="0.45\ mol\ \ce{AgNO3}\cdot \frac{89.2}{100} = \color[RGB]{0,112,192}{\textbf{0.40\ mol\ \ce{AgNO3}}}" title="0.45\ mol\ \ce{AgNO3}\cdot \frac{89.2}{100} = \color[RGB]{0,112,192}{\textbf{0.40\ mol\ \ce{AgNO3}}}" /> <br/> <br/> This means that only 0.40 moles of each reactant react, and the same moles of each product are obtained. You calculate the mass of each product: <br/> <br/> <p class="spip" style="text-align: center;"><img src='https://ejercicios-fyq.com/local/cache-TeX/1f5ba824337cb4d9f3385cc06f6dc1bd.png' style="vertical-align:middle;" width="299" height="38" alt="0.40\ \cancel{mol}\ \ce{AgCl}\cdot \frac{143.5\ g}{1\ \cancel{mol}} = \fbox{\color[RGB]{192,0,0}{\textbf{57.4\ g\ \ce{AgCl}}}}" title="0.40\ \cancel{mol}\ \ce{AgCl}\cdot \frac{143.5\ g}{1\ \cancel{mol}} = \fbox{\color[RGB]{192,0,0}{\textbf{57.4\ g\ \ce{AgCl}}}}" /></p> <br/> <p class="spip" style="text-align: center;"><img src='https://ejercicios-fyq.com/local/cache-TeX/cdba9b1e9d343a580975421cdc358e7c.png' style="vertical-align:middle;" width="305" height="37" alt="0.40\ \cancel{mol}\ \ce{HNO3}\cdot \frac{63\ g}{1\ \cancel{mol}} = \fbox{\color[RGB]{192,0,0}{\textbf{25.2\ g\ \ce{HNO3}}}}" title="0.40\ \cancel{mol}\ \ce{HNO3}\cdot \frac{63\ g}{1\ \cancel{mol}} = \fbox{\color[RGB]{192,0,0}{\textbf{25.2\ g\ \ce{HNO3}}}}" /></p> <br/> c) The excess reagent is HCl, of which 0.40 moles react, leaving unreacted: (0.542 - 0.40) mol = 0.142 mol. You convert this to mass: <br/> <br/> <p class="spip" style="text-align: center;"><img src='https://ejercicios-fyq.com/local/cache-TeX/48e5a0f066000c109358c2daa2c24c4d.png' style="vertical-align:middle;" width="281" height="37" alt="0.142\ \cancel{mol}\ \ce{HCl}\cdot \frac{36.5\ g}{1\ \cancel{mol}} = \fbox{\color[RGB]{192,0,0}{\textbf{5.18\ g\ \ce{HCl}}}}" title="0.142\ \cancel{mol}\ \ce{HCl}\cdot \frac{36.5\ g}{1\ \cancel{mol}} = \fbox{\color[RGB]{192,0,0}{\textbf{5.18\ g\ \ce{HCl}}}}" /></p> </math></p></div>