The compound hexaazaisowurtzitane is one of the highest-energy explosives known ( C & E News, Jan. 17, 1994, p. 26). The compound, also known as CL-20, was first synthesized in 1987. The method of synthesis and detailed performance data are still classified because of CL-20’s potential military application in rocket boosters and in warheads of “smart” weapons. The structure of CL-20 is In such shorthand structures, each point where lines meet represents a carbon atom. In addition, the hydrogens attached to the carbon atoms are omitted; each of the six carbon atoms has one hydrogen atom attached. Finally, assume that the two O atoms in the NO 2 groups are attached to N with one single bond and one double bond. Three possible reactions for the explosive decomposition ofCL-20 are i. C 6 H 6 N 12 O 12 ( s ) → 6CO ( g ) + 6 N 2 ( g ) + 3H 2 O ( g ) + 3 2 O 2 ( g ) ii. C 6 H 6 N 12 O 12 ( s ) → 3CO( g ) + 3CO 2 (g) + 6N 2 ( g ) + 3H 2 O( g ) iii. C 6 H 6 N 12 O 12 ( s ) → 6CO 2 ( g ) + 6N 2 ( g ) + 3H 2 ( g ) a. Use bond energies to estimate ∆E for these three reactions. b. Which of the above reactions releases the largest amount of energy per kilogram of CL-20?
The compound hexaazaisowurtzitane is one of the highest-energy explosives known ( C & E News, Jan. 17, 1994, p. 26). The compound, also known as CL-20, was first synthesized in 1987. The method of synthesis and detailed performance data are still classified because of CL-20’s potential military application in rocket boosters and in warheads of “smart” weapons. The structure of CL-20 is In such shorthand structures, each point where lines meet represents a carbon atom. In addition, the hydrogens attached to the carbon atoms are omitted; each of the six carbon atoms has one hydrogen atom attached. Finally, assume that the two O atoms in the NO 2 groups are attached to N with one single bond and one double bond. Three possible reactions for the explosive decomposition ofCL-20 are i. C 6 H 6 N 12 O 12 ( s ) → 6CO ( g ) + 6 N 2 ( g ) + 3H 2 O ( g ) + 3 2 O 2 ( g ) ii. C 6 H 6 N 12 O 12 ( s ) → 3CO( g ) + 3CO 2 (g) + 6N 2 ( g ) + 3H 2 O( g ) iii. C 6 H 6 N 12 O 12 ( s ) → 6CO 2 ( g ) + 6N 2 ( g ) + 3H 2 ( g ) a. Use bond energies to estimate ∆E for these three reactions. b. Which of the above reactions releases the largest amount of energy per kilogram of CL-20?
The compound hexaazaisowurtzitane is one of the highest-energy explosives known (C & E News, Jan. 17, 1994, p. 26). The compound, also known as CL-20, was first synthesized in 1987. The method of synthesis and detailed performance data are still classified because of CL-20’s potential military application in rocket boosters and in warheads of “smart” weapons. The structure of CL-20 is
In such shorthand structures, each point where lines meet represents a carbon atom. In addition, the hydrogens attached to the carbon atoms are omitted; each of the six carbon atoms has one hydrogen atom attached. Finally, assume that the two O atoms in the NO2 groups are attached to N with one single bond and one double bond.
Three possible reactions for the explosive decomposition ofCL-20 are
i.
C
6
H
6
N
12
O
12
(
s
)
→
6CO
(
g
)
+
6
N
2
(
g
)
+
3H
2
O
(
g
)
+
3
2
O
2
(
g
)
ii. C6H6N12O12(s) → 3CO(g) + 3CO2(g) + 6N2(g) + 3H2O(g)
iii. C6H6N12O12(s) → 6CO2(g) + 6N2(g) + 3H2 (g)
a. Use bond energies to estimate ∆E for these three reactions.
b. Which of the above reactions releases the largest amount of energy per kilogram of CL-20?
(a) (i)
Expert Solution
Interpretation Introduction
Interpretation: The change in energy for the given chemical reactions has to be calculated.
Concept introduction: In a chemical reaction, energy is either gained, endothermic reactions, or released, exothermic reactions. The change in energy can be stated as the difference between the energy required to break the bonds in case of reactants and the energy released on the formation of the products.
To determine: The change in energy for the stated reactions.
Answer to Problem 163CP
The change in energy
=-2635.5kJ_
Explanation of Solution
Given
The chemical reaction involved is,
C6H6N12O12(s)→6CO(g)+6N2(g)+3H2O(g)+32O2(g)
Formula
The change in energy =(Energy required to breakthe bonds in reactants)–(Energy released whenproductsareformed)
Energy for reactants,
6C−H=413kJ1mol×6mol=2478kJ
6N=O=607kJ1mol×6mol=3642kJ
3C−C=347kJ1mol×3mol=1041kJ
12C−N=305kJ1mol×12mol=3660kJ
6N−N=160kJ1mol×6mol=960kJ
The total energy
=(3660+1041+960+3642+2478)kJ=12987kJ (1)
For products,
6C≡O=1072kJ1mol×6mol=6432kJ
6N≡N=941kJ1mol×6mol=5646kJ
6O−H=467kJ1mol×6mol=2802kJ
32O=O=495kJ1mol×32mol=742.5kJ
The total energy
=(6432+5646+2802+742.5)kJ=15622.5kJ (2)
The change in energy
=(12987-15622.5)kJ=-2635.5kJ_ (from equation (1) and (2))
(ii)
Expert Solution
Interpretation Introduction
Interpretation: The change in energy for the given chemical reactions has to be calculated.
Concept introduction: In a chemical reaction, energy is either gained, endothermic reactions, or released, exothermic reactions. The change in energy can be stated as the difference between the energy required to break the bonds in case of reactants and the energy released on the formation of the products.
To determine: The change in energy for the stated reactions.
Answer to Problem 163CP
The change in energy
=-3147kJ_
Explanation of Solution
Given
The chemical reaction involved is,
C6H6N12O12(s)→3CO(g)+3CO2(g)+6N2(g)+3H2O(g)
Formula
The change in energy =(Energy required to breakthe bonds in reactants)–(Energy released whenproductsareformed)
Energy for reactants,
6C−H=413kJ1mol×6mol=2478kJ
6N=O=607kJ1mol×6mol=3642kJ
3C−C=347kJ1mol×3mol=1041kJ
12C−N=305kJ1mol×12mol=3660kJ
6N−N=160kJ1mol×6mol=960kJ
The total energy
=(3660+1041+960+3642+2478)kJ=12987kJ (1)
For products,
3C≡O=1072kJ1mol×3mol=3216kJ
6C=O=745kJ1mol×6mol=4470kJ
6N−N=941kJ1mol×6mol=5646kJ
6O−H=467kJ1mol×6mol=2802kJ
The total energy
=(3216+4470+5646+2802)kJ=16134kJ (2)
The change in energy
=(12987-16134)kJ=-3147kJ_ (from equation (1) and (2))
(iii)
Expert Solution
Interpretation Introduction
Interpretation: The change in energy for the given chemical reactions has to be calculated.
Concept introduction: In a chemical reaction, energy is either gained, endothermic reactions, or released, exothermic reactions. The change in energy can be stated as the difference between the energy required to break the bonds in case of reactants and the energy released on the formation of the products.
To determine: The change in energy for the stated reactions.
Answer to Problem 163CP
The change in energy
=-4191kJ_
Explanation of Solution
Given
The chemical reaction involved is,
C6H6N12O12(s)→6CO2(g)+6N2(g)+6H2(g)
Formula
The change in energy =(Energy required to breakthe bonds in reactants)–(Energy released whenproductsareformed)
Energy for reactants,
6C−H=413kJ1mol×6mol=2478kJ
6N=O=607kJ1mol×6mol=3642kJ
3C−C=347kJ1mol×3mol=1041kJ
12C−N=305kJ1mol×12mol=3660kJ
6N−N=160kJ1mol×6mol=960kJ
The total energy
=(3660+1041+960+3642+2478)kJ=12987kJ (1)
For products,
12C=O=745kJ1mol×12mol=8940kJ
6N−N=941kJ1mol×6mol=5646kJ
6H−H=432kJ1mol×6mol=2592kJ
The total energy
=(8940+5646+2592)kJ=17178kJ (2)
The change in energy
=(12987-17178)kJ=-4191kJ_ (from equation (1) and (2))
Conclusion
The change in energy can be stated as the difference between the energy required to break the bonds in case of reactants and the energy released on the formation of the products.
(b)
Expert Solution
Interpretation Introduction
Interpretation: The change in energy for the given chemical reactions has to be calculated.
Concept introduction: In a chemical reaction, energy is either gained, endothermic reactions, or released, exothermic reactions. The change in energy can be stated as the difference between the energy required to break the bonds in case of reactants and the energy released on the formation of the products.
To determine: The reaction that releases the larger amount of energy per kilogram of
CL−20.
Answer to Problem 163CP
The reaction (iii) releases the largest amount of energy per kilogram of
CL−20.
Explanation of Solution
One mole of
C6H6N12O12 gives
438g.
In case of the (i) reaction,
438g of the reactant gives energy
=−2635.5kJ
Hence,
1kg of the reactant gives energy
=−2635.5438×1000kJ=-6017.12kJ
In case of the (ii) reaction,
438g of the reactant gives energy
=−3147kJ
Hence,
1kg of the reactant gives energy
=−3147438×1000kJ=-7184.9kJ
In case of the (iii) reaction,
438g of the reactant gives energy
=−4191kJ
Hence,
1kg of the reactant gives energy
=−4191438×1000kJ=-9568.49kJ_
The reaction (iii) releases the largest amount of energy per kilogram of
CL−20.
Conclusion
The third stated reaction releases the largest amount of energy per kilogram of
CL−20.
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Unshared, or lone, electron pairs play an important role in determining the chemical and physical properties of organic compounds.
Thus, it is important to know which atoms carry unshared pairs.
Use the structural formulas below to determine the number of unshared pairs at each designated atom.
Be sure your answers are consistent with the formal charges on the formulas.
CH.
H₂
fo
H2
H
The number of unshared pairs at atom a is
The number of unshared pairs at atom b is
The number of unshared pairs at atom c is
HC
HC
HC
CH
The number of unshared pairs at atom a is
The number of unshared pairs at atom b is
The number of unshared pairs at atom c is
Draw curved arrows for the following reaction step.
Arrow-pushing Instructions
CH3
CH3 H
H-O-H
+/
H3C-C+
H3C-C-0:
CH3
CH3 H
1:14 PM Fri 20 Dec
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Grade 7 CBE 03/12/2024 (OOW_7D 2024-25 Ms Sunita Harikesh)
Activity
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Skill: Advanced or complex data
representation or interpretation.
Vidya lit a candle and covered it with a glass.
The candle burned for some time and then went
off. She wanted to check whether the length of
the candle would affect the time for which it
burns. She performed the experiment again after
changing something.
Which of these would be the correct
experimental setup for her to use? * (1 Point)
She wanted to check whether the length of the candle would affect the time for which it burns.
She performed the experiment again after changing something.
Which of these would be the correct experimental setup for her to use?
A
Longer candle;
No glass
C
B
Longer candle;
Longer glass
D
D
B
Longer candle;
Same glass
Same candle;
Longer glass
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