Complete The Following Equations (note That The Equations Are Not Balanced). Use The Activity Series If Necessary.Activity Series:$\[ \begin{array}{l} \text{Li \ \textgreater \ K \ \textgreater \ Ba \ \textgreater \ Sr \ \textgreater \ Ca \

Feb 27, 2025 by ADMIN 249 views

**Solving Unbalanced Equations with the Activity Series**

Understanding the Activity Series

The activity series, also known as the reactivity series, is a list of metals arranged in order of their reactivity from highest to lowest. This series helps us predict the products of single displacement reactions, where one metal displaces another metal from a compound. The activity series is essential in solving unbalanced equations, especially when dealing with metals that are not in their standard state.

The Activity Series: A Quick Review

Here's a quick review of the activity series:

Metal	Reactivity
Lithium (Li)	Most reactive
Potassium (K)	Highly reactive
Barium (Ba)	Moderately reactive
Strontium (Sr)	Less reactive
Calcium (Ca)	Least reactive

Solving Unbalanced Equations with the Activity Series

Now that we have a basic understanding of the activity series, let's apply it to solve some unbalanced equations.

Equation 1: Unbalanced Equation with Lithium and Calcium

Unbalanced Equation: Li + CaO → ?

Using the activity series, we know that lithium is more reactive than calcium. Therefore, lithium will displace calcium from the compound. The correct products are:

Li + CaO → Li2O + Ca

Equation 2: Unbalanced Equation with Potassium and Barium

Unbalanced Equation: K + Ba → ?

Using the activity series, we know that potassium is more reactive than barium. Therefore, potassium will displace barium from the compound. The correct products are:

K + Ba → K2Ba

Equation 3: Unbalanced Equation with Strontium and Calcium

Unbalanced Equation: Sr + Ca → ?

Using the activity series, we know that strontium is more reactive than calcium. Therefore, strontium will displace calcium from the compound. The correct products are:

Sr + Ca → SrCa

Equation 4: Unbalanced Equation with Lithium and Barium

Unbalanced Equation: Li + Ba → ?

Using the activity series, we know that lithium is more reactive than barium. Therefore, lithium will displace barium from the compound. The correct products are:

Li + Ba → LiBa

Equation 5: Unbalanced Equation with Potassium and Strontium

Unbalanced Equation: K + Sr → ?

Using the activity series, we know that potassium is more reactive than strontium. Therefore, potassium will displace strontium from the compound. The correct products are:

K + Sr → K2Sr

Equation 6: Unbalanced Equation with Calcium and Barium

Unbalanced Equation: Ca + Ba → ?

Using the activity series, we know that calcium is less reactive than barium. Therefore, calcium will not displace barium from the compound. The correct products are:

Ca + Ba → CaBa

Equation 7: Unbalanced Equation with Lithium and Strontium

Unbalanced Equation: Li + Sr → ?

Using the activity series, we know that lithium is more reactive than strontium. Therefore, lithium will displace strontium from the compound. The correct products are:

Li + Sr → LiSr

Equation 8: Unbalanced Equation with Potassium and Calcium

Unbalanced Equation: K + Ca → ?

Using the activity series, we know that potassium is more reactive than calcium. Therefore, potassium will displace calcium from the compound. The correct products are:

K + Ca → K2Ca

Equation 9: Unbalanced Equation with Barium and Calcium

Unbalanced Equation: Ba + Ca → ?

Using the activity series, we know that barium is more reactive than calcium. Therefore, barium will displace calcium from the compound. The correct products are:

Ba + Ca → BaCa

Equation 10: Unbalanced Equation with Strontium and Calcium

Unbalanced Equation: Sr + Ca → ?

Using the activity series, we know that strontium is more reactive than calcium. Therefore, strontium will displace calcium from the compound. The correct products are:

Sr + Ca → SrCa

Conclusion

Solving unbalanced equations with the activity series requires a basic understanding of the reactivity of metals. By applying the activity series, we can predict the products of single displacement reactions and balance the equations. Remember to always use the activity series to determine the reactivity of metals and to balance the equations accordingly.

Key Takeaways

The activity series is a list of metals arranged in order of their reactivity from highest to lowest.
The activity series helps us predict the products of single displacement reactions.
By applying the activity series, we can balance unbalanced equations and determine the reactivity of metals.

Practice Problems

Try solving the following unbalanced equations using the activity series:

Li + CaO → ?
K + Ba → ?
Sr + Ca → ?
Li + Ba → ?
K + Sr → ?
Ca + Ba → ?
Li + Sr → ?
K + Ca → ?
Ba + Ca → ?
Sr + Ca → ?

Answer Key

Li + CaO → Li2O + Ca
K + Ba → K2Ba
Sr + Ca → SrCa
Li + Ba → LiBa
K + Sr → K2Sr
Ca + Ba → CaBa
Li + Sr → LiSr
K + Ca → K2Ca
Ba + Ca → BaCa
Sr + Ca → SrCa
Q&A: Solving Unbalanced Equations with the Activity Series =====================================================

Frequently Asked Questions

Q: What is the activity series?

A: The activity series, also known as the reactivity series, is a list of metals arranged in order of their reactivity from highest to lowest. This series helps us predict the products of single displacement reactions, where one metal displaces another metal from a compound.

Q: How do I use the activity series to solve unbalanced equations?

A: To use the activity series to solve unbalanced equations, you need to identify the metals involved in the reaction and determine their reactivity using the activity series. Then, you can predict the products of the reaction and balance the equation accordingly.

Q: What are some common mistakes to avoid when using the activity series?

A: Some common mistakes to avoid when using the activity series include:

Not considering the reactivity of the metals involved in the reaction
Not balancing the equation correctly
Not using the correct products of the reaction

Q: Can I use the activity series to predict the products of reactions involving non-metals?

A: No, the activity series is only applicable to reactions involving metals. For reactions involving non-metals, you need to use other methods, such as the periodic table or the rules of acid-base chemistry.

Q: How do I determine the reactivity of a metal using the activity series?

A: To determine the reactivity of a metal using the activity series, you need to locate the metal on the activity series and determine its position relative to other metals. The higher the metal is on the activity series, the more reactive it is.

Q: Can I use the activity series to predict the products of reactions involving acids and bases?

A: No, the activity series is only applicable to reactions involving metals. For reactions involving acids and bases, you need to use other methods, such as the rules of acid-base chemistry.

Q: How do I balance an equation using the activity series?

A: To balance an equation using the activity series, you need to identify the products of the reaction and determine the correct coefficients for each product. Then, you can balance the equation by adjusting the coefficients as needed.

Q: Can I use the activity series to predict the products of reactions involving gases?

A: No, the activity series is only applicable to reactions involving metals. For reactions involving gases, you need to use other methods, such as the rules of gas chemistry.

Q: How do I determine the reactivity of a metal ion using the activity series?

A: To determine the reactivity of a metal ion using the activity series, you need to locate the metal ion on the activity series and determine its position relative to other metal ions. The higher the metal ion is on the activity series, the more reactive it is.

Q: Can I use the activity series to predict the products of reactions involving electrolytes?

A: No, the activity series is only applicable to reactions involving metals. For reactions involving electrolytes, you need to use other methods, such as the rules of electrolyte chemistry.

Q: How do I balance an equation involving multiple metals using the activity series?

A: To balance an equation involving multiple metals using the activity series, you need to identify the products of the reaction and determine the correct coefficients for each product. Then, you can balance the equation by adjusting the coefficients as needed.

Q: Can I use the activity series to predict the products of reactions involving compounds?

A: No, the activity series is only applicable to reactions involving metals. For reactions involving compounds, you need to use other methods, such as the rules of compound chemistry.

Q: How do I determine the reactivity of a metal compound using the activity series?

A: To determine the reactivity of a metal compound using the activity series, you need to locate the metal compound on the activity series and determine its position relative to other metal compounds. The higher the metal compound is on the activity series, the more reactive it is.

Q: Can I use the activity series to predict the products of reactions involving solutions?

A: No, the activity series is only applicable to reactions involving metals. For reactions involving solutions, you need to use other methods, such as the rules of solution chemistry.

Q: How do I balance an equation involving multiple metal compounds using the activity series?

A: To balance an equation involving multiple metal compounds using the activity series, you need to identify the products of the reaction and determine the correct coefficients for each product. Then, you can balance the equation by adjusting the coefficients as needed.