QUESTION IMAGE
Question
i. \\(\text{h}_2(\text{g}) + \text{i}_2(\text{g}) \
ightleftharpoons 2\text{hi}(\text{g})\\)
\\(k = 54\\) @ \\(700\text{ k}\\)
ii. \\(\text{n}_2(\text{g}) + 3\text{h}_2(\text{g}) \
ightleftharpoons 2\text{nh}_3(\text{g})\\)
\\(k = 1.04 \times 10^{-4}\\) @ \\(700\text{ k}\\)
what is the \\(k\\) value for the reaction below?
\\(2\text{nh}_3(\text{g}) + 3\text{i}_2(\text{g}) \
ightleftharpoons 6\text{hi}(\text{g}) + \text{n}_2(\text{g})\\)
\\(k = ? \times 10^{?}\\)
<pre_analysis>
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<reasoning>
Identify the target reaction and given equations
Using the Chemical Equilibrium and Equilibrium Constant knowledge points
Given reactions:
- \(\text{H}_2(g) + \text{I}_2(g)
ightleftharpoons 2\text{HI}(g)\) with \(K_1 = 54\)
- \(\text{N}_2(g) + 3\text{H}_2(g)
ightleftharpoons 2\text{NH}_3(g)\) with \(K_2 = 1.04 \times 10^{-4}\)
Target reaction:
\(\text{2NH}_3(g) + 3\text{I}_2(g)
ightleftharpoons 6\text{HI}(g) + \text{N}_2(g)\) with \(K_{\text{target}}\)
Manipulate given equations to match target
Using the Chemical Equilibrium and Equilibrium Constant knowledge points
- Reverse reaction (2) to place \(\text{2NH}_3(g)\) on the reactant side:
\(2\text{NH}_3(g)
ightleftharpoons \text{N}_2(g) + 3\text{H}_2(g)\)
\(K_2' = \frac{1}{K_2} = \frac{1}{1.04 \times 10^{-4}}\)
- Multiply reaction (1) by 3 to get \(3\text{I}_2(g)\) and \(6\text{HI}(g)\):
\(3\text{H}_2(g) + 3\text{I}_2(g)
ightleftharpoons 6\text{HI}(g)\)
\(K_1' = (K_1)^3 = 54^3\)
Combine reactions and calculate target K
Using the Chemical Equilibrium and Equilibrium Constant knowledge points
Adding the two manipulated equations yields the target equation:
\(2\text{NH}_3(g) + 3\text{I}_2(g)
ightleftharpoons 6\text{HI}(g) + \text{N}_2(g)\)
\[
\]
Format the final answer
Using the Chemical Equilibrium and Equilibrium Constant knowledge points
The target value is expressed in scientific notation as \(K = [?] \times 10^{[?]}\).
Comparing \(1.51 \times 10^9\) to the format \(K = [?] \times 10^{[?]}\):
The coefficient is \(1.51\) (or \(1.5\)) and the exponent is \(9\).
</reasoning>
<answer>
What is the K value for the reaction below?
\(2\text{NH}_3(g) + 3\text{I}_2(g)
ightleftharpoons 6\text{HI}(g) + \text{N}_2(g)\)
\(K =\) <blank>\(1.5\)</blank> \(\times 10^{\text{
</answer>
<post_analysis>
{
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"question_type": "Fill-in-the-blank",
"knowledge_point": [
"Natural Science",
"Chemistry",
"Chemical Equilibrium"
]
}
</post_analysis>
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<pre_analysis>
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"step_cot",
"blank_filling_formatter",
"explain_then_answer",
"tutor",
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],
"needs_drawing": false,
"concepts_used": [
"Chemical Equilibrium",
"Equilibrium Constant"
],
"new_concepts": [
"Manipulating Equilibrium Constants",
"Hess's Law for Equilibrium"
],
"current_concepts": [
"Chemical Equilibrium",
"Equilibrium Constant",
"Manipulating Equilibrium Constants"
]
}
</pre_analysis>
<reasoning>
Identify the target reaction and given equations
Using the Chemical Equilibrium and Equilibrium Constant knowledge points
Given reactions:
- \(\text{H}_2(g) + \text{I}_2(g)
ightleftharpoons 2\text{HI}(g)\) with \(K_1 = 54\)
- \(\text{N}_2(g) + 3\text{H}_2(g)
ightleftharpoons 2\text{NH}_3(g)\) with \(K_2 = 1.04 \times 10^{-4}\)
Target reaction:
\(\text{2NH}_3(g) + 3\text{I}_2(g)
ightleftharpoons 6\text{HI}(g) + \text{N}_2(g)\) with \(K_{\text{target}}\)
Manipulate given equations to match target
Using the Chemical Equilibrium and Equilibrium Constant knowledge points
- Reverse reaction (2) to place \(\text{2NH}_3(g)\) on the reactant side:
\(2\text{NH}_3(g)
ightleftharpoons \text{N}_2(g) + 3\text{H}_2(g)\)
\(K_2' = \frac{1}{K_2} = \frac{1}{1.04 \times 10^{-4}}\)
- Multiply reaction (1) by 3 to get \(3\text{I}_2(g)\) and \(6\text{HI}(g)\):
\(3\text{H}_2(g) + 3\text{I}_2(g)
ightleftharpoons 6\text{HI}(g)\)
\(K_1' = (K_1)^3 = 54^3\)
Combine reactions and calculate target K
Using the Chemical Equilibrium and Equilibrium Constant knowledge points
Adding the two manipulated equations yields the target equation:
\(2\text{NH}_3(g) + 3\text{I}_2(g)
ightleftharpoons 6\text{HI}(g) + \text{N}_2(g)\)
\[
\]
Format the final answer
Using the Chemical Equilibrium and Equilibrium Constant knowledge points
The target value is expressed in scientific notation as \(K = [?] \times 10^{[?]}\).
Comparing \(1.51 \times 10^9\) to the format \(K = [?] \times 10^{[?]}\):
The coefficient is \(1.51\) (or \(1.5\)) and the exponent is \(9\).
</reasoning>
<answer>
What is the K value for the reaction below?
\(2\text{NH}_3(g) + 3\text{I}_2(g)
ightleftharpoons 6\text{HI}(g) + \text{N}_2(g)\)
\(K =\) <blank>\(1.5\)</blank> \(\times 10^{\text{
</answer>
<post_analysis>
{
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"question_type": "Fill-in-the-blank",
"knowledge_point": [
"Natural Science",
"Chemistry",
"Chemical Equilibrium"
]
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</post_analysis>