Which Equation Is Balanced In An Acidic Solution?A. $SO_4^{2-} + 2 H_2O (\ell) + 2 E^- \rightarrow SO_2(g) + 4 OH^-$B. $SO_4^{2-} + 2 E^- \rightarrow SO_2(g$\]C. $SO_4^{2-} + 4 H^+ + 2 E^- \rightarrow SO_2(g) + 2 H_2O

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In chemistry, balancing equations is a crucial step in understanding chemical reactions. It involves ensuring that the number of atoms for each element is the same on both the reactant and product sides of the equation. In this article, we will examine three different equations involving the reduction of sulfate ions (SO42-) and determine which one is balanced in an acidic solution.

Understanding the Basics of Acidic Solutions

Before we dive into the equations, let's briefly discuss what an acidic solution is. An acidic solution is a solution that has a pH level below 7, indicating the presence of hydrogen ions (H+). In an acidic solution, the concentration of hydrogen ions is higher than in a neutral solution. This is in contrast to basic solutions, which have a higher concentration of hydroxide ions (OH-).

Equation A: SO42βˆ’+2H2O(β„“)+2eβˆ’β†’SO2(g)+4OHβˆ’SO_4^{2-} + 2 H_2O (\ell) + 2 e^- \rightarrow SO_2(g) + 4 OH^-

The first equation involves the reduction of sulfate ions in the presence of water and electrons. The equation is as follows:

SO42βˆ’+2H2O(β„“)+2eβˆ’β†’SO2(g)+4OHβˆ’SO_4^{2-} + 2 H_2O (\ell) + 2 e^- \rightarrow SO_2(g) + 4 OH^-

At first glance, this equation may seem balanced, but let's take a closer look. On the reactant side, we have one sulfate ion (SO42-), two water molecules (H2O), and two electrons (e-). On the product side, we have one sulfur dioxide molecule (SO2) and four hydroxide ions (OH-). However, the number of oxygen atoms on the reactant side is 4 (from the sulfate ion and two water molecules), while the number of oxygen atoms on the product side is 2 (from the sulfur dioxide molecule). This means that the equation is not balanced.

Equation B: SO42βˆ’+2eβˆ’β†’SO2(g)SO_4^{2-} + 2 e^- \rightarrow SO_2(g)

The second equation involves the reduction of sulfate ions in the absence of water and hydrogen ions. The equation is as follows:

SO42βˆ’+2eβˆ’β†’SO2(g)SO_4^{2-} + 2 e^- \rightarrow SO_2(g)

This equation is also not balanced. On the reactant side, we have one sulfate ion (SO42-) and two electrons (e-). On the product side, we have one sulfur dioxide molecule (SO2). However, the number of oxygen atoms on the reactant side is 4 (from the sulfate ion), while the number of oxygen atoms on the product side is 2 (from the sulfur dioxide molecule). This means that the equation is not balanced.

Equation C: SO42βˆ’+4H++2eβˆ’β†’SO2(g)+2H2OSO_4^{2-} + 4 H^+ + 2 e^- \rightarrow SO_2(g) + 2 H_2O

The third equation involves the reduction of sulfate ions in the presence of hydrogen ions. The equation is as follows:

SO42βˆ’+4H++2eβˆ’β†’SO2(g)+2H2OSO_4^{2-} + 4 H^+ + 2 e^- \rightarrow SO_2(g) + 2 H_2O

This equation is balanced. On the reactant side, we have one sulfate ion (SO42-), four hydrogen ions (H+), and two electrons (e-). On the product side, we have one sulfur dioxide molecule (SO2) and two water molecules (H2O). The number of oxygen atoms on both sides is 4, and the number of hydrogen atoms on both sides is 4. This means that the equation is balanced.

Conclusion

In conclusion, the equation that is balanced in an acidic solution is Equation C: SO42βˆ’+4H++2eβˆ’β†’SO2(g)+2H2OSO_4^{2-} + 4 H^+ + 2 e^- \rightarrow SO_2(g) + 2 H_2O. This equation involves the reduction of sulfate ions in the presence of hydrogen ions, which is a characteristic of acidic solutions. The other two equations are not balanced, as they do not account for the presence of hydrogen ions or water molecules.

Importance of Balancing Equations

Balancing equations is a crucial step in understanding chemical reactions. It ensures that the number of atoms for each element is the same on both the reactant and product sides of the equation. This is important because it allows us to predict the products of a reaction and understand the underlying chemistry. In this article, we have seen how balancing equations can help us determine which equation is balanced in an acidic solution.

Common Mistakes in Balancing Equations

When balancing equations, it is easy to make mistakes. Some common mistakes include:

  • Not accounting for the presence of hydrogen ions or water molecules
  • Not balancing the number of oxygen atoms
  • Not balancing the number of hydrogen atoms
  • Not checking the charge balance

To avoid these mistakes, it is essential to carefully examine the equation and ensure that the number of atoms for each element is the same on both the reactant and product sides.

Tips for Balancing Equations

Balancing equations can be a challenging task, but there are some tips that can help. Here are a few:

  • Start by balancing the number of atoms for each element
  • Use coefficients to balance the equation
  • Check the charge balance
  • Use a flowchart or diagram to help visualize the reaction

By following these tips, you can ensure that your equations are balanced and accurate.

Conclusion

In our previous article, we discussed the importance of balancing equations in acidic solutions. We also examined three different equations involving the reduction of sulfate ions and determined which one is balanced in an acidic solution. In this article, we will answer some frequently asked questions about balancing equations in acidic solutions.

Q: What is the importance of balancing equations in acidic solutions?

A: Balancing equations in acidic solutions is crucial because it ensures that the number of atoms for each element is the same on both the reactant and product sides of the equation. This is important because it allows us to predict the products of a reaction and understand the underlying chemistry.

Q: How do I balance an equation in an acidic solution?

A: To balance an equation in an acidic solution, you need to follow these steps:

  1. Start by balancing the number of atoms for each element.
  2. Use coefficients to balance the equation.
  3. Check the charge balance.
  4. Use a flowchart or diagram to help visualize the reaction.

Q: What are some common mistakes to avoid when balancing equations in acidic solutions?

A: Some common mistakes to avoid when balancing equations in acidic solutions include:

  • Not accounting for the presence of hydrogen ions or water molecules
  • Not balancing the number of oxygen atoms
  • Not balancing the number of hydrogen atoms
  • Not checking the charge balance

Q: How do I determine if an equation is balanced in an acidic solution?

A: To determine if an equation is balanced in an acidic solution, you need to check the following:

  • The number of oxygen atoms on both sides of the equation
  • The number of hydrogen atoms on both sides of the equation
  • The charge balance on both sides of the equation

Q: What is the difference between an acidic solution and a basic solution?

A: An acidic solution is a solution that has a pH level below 7, indicating the presence of hydrogen ions (H+). A basic solution, on the other hand, is a solution that has a pH level above 7, indicating the presence of hydroxide ions (OH-).

Q: How do I write a balanced equation for a reaction in an acidic solution?

A: To write a balanced equation for a reaction in an acidic solution, you need to follow these steps:

  1. Write the unbalanced equation.
  2. Balance the number of atoms for each element.
  3. Use coefficients to balance the equation.
  4. Check the charge balance.
  5. Use a flowchart or diagram to help visualize the reaction.

Q: What are some tips for balancing equations in acidic solutions?

A: Some tips for balancing equations in acidic solutions include:

  • Start by balancing the number of atoms for each element.
  • Use coefficients to balance the equation.
  • Check the charge balance.
  • Use a flowchart or diagram to help visualize the reaction.
  • Practice, practice, practice!

Q: How do I check the charge balance in an equation?

A: To check the charge balance in an equation, you need to follow these steps:

  1. Calculate the total charge on the reactant side of the equation.
  2. Calculate the total charge on the product side of the equation.
  3. Compare the two charges to ensure that they are equal.

Q: What is the significance of the charge balance in an equation?

A: The charge balance in an equation is significant because it ensures that the number of electrons transferred in the reaction is equal to the number of electrons required to balance the charges. This is important because it allows us to predict the products of a reaction and understand the underlying chemistry.

Conclusion

In conclusion, balancing equations in acidic solutions is a crucial step in understanding chemical reactions. By following the tips and avoiding common mistakes, you can ensure that your equations are balanced and accurate. Remember to check the charge balance and use coefficients to balance the equation. Practice, practice, practice!