Given that the pressure in an automobile tire is 2.3 0 atm at a temperature of 20.0 o C . The pressure in the tire if after 10 miles of driving the temperature of the tire increased to 47. 0 o C should be calculated. Concept Introduction: The final pressure of the gas at the varying temperatures can be calculated using Gay-Lussac’s law, which states the relationship between pressure and temperature of the gas. According to Gay-Lussac’s Law, for the gas held at constant volume, the pressure of a given amount of gas is directly proportional to the temperature of the gas. Mathematically, it is given as. P ∝ T . P T = constant = k . We two different sets of temperature and pressure of the gas is considered, the above equation becomes as follows: P 1 T 1 = P 2 T 2 . where P 1 and T 1 are initial pressure and temperature of the gas, while P 2 and T 2 are final pressure and temperature of the gas.
Given that the pressure in an automobile tire is 2.3 0 atm at a temperature of 20.0 o C . The pressure in the tire if after 10 miles of driving the temperature of the tire increased to 47. 0 o C should be calculated. Concept Introduction: The final pressure of the gas at the varying temperatures can be calculated using Gay-Lussac’s law, which states the relationship between pressure and temperature of the gas. According to Gay-Lussac’s Law, for the gas held at constant volume, the pressure of a given amount of gas is directly proportional to the temperature of the gas. Mathematically, it is given as. P ∝ T . P T = constant = k . We two different sets of temperature and pressure of the gas is considered, the above equation becomes as follows: P 1 T 1 = P 2 T 2 . where P 1 and T 1 are initial pressure and temperature of the gas, while P 2 and T 2 are final pressure and temperature of the gas.
Solution Summary: The author explains that the final pressure of the gas at the varying temperatures can be calculated using Gay-Lussac's law.
Given that the pressure in an automobile tire is 2.30 atm at a temperature of 20.0oC. The pressure in the tire if after 10 miles of driving the temperature of the tire increased to 47.0 oC should be calculated.
Concept Introduction:
The final pressure of the gas at the varying temperatures can be calculated using Gay-Lussac’s law, which states the relationship between pressure and temperature of the gas.
According to Gay-Lussac’s Law, for the gas held at constant volume, the pressure of a given amount of gas is directly proportional to the temperature of the gas. Mathematically, it is given as.
P∝T.
PT=constant=k.
We two different sets of temperature and pressure of the gas is considered, the above equation becomes as follows:
P1T1=P2T2.
where P1 and T1 are initial pressure and temperature of the gas, while P2 and T2 are final pressure and temperature of the gas.
(f) SO:
Best Lewis Structure
3
e group geometry:_
shape/molecular geometry:,
(g) CF2CF2
Best Lewis Structure
polarity:
e group arrangement:_
shape/molecular geometry:
(h) (NH4)2SO4
Best Lewis Structure
polarity:
e group arrangement:
shape/molecular geometry:
polarity:
Sketch (with angles):
Sketch (with angles):
Sketch (with angles):
1.
Problem Set 3b
Chem 141
For each of the following compounds draw the BEST Lewis Structure then sketch the molecule (showing
bond angles). Identify (i) electron group geometry (ii) shape around EACH central atom (iii) whether the
molecule is polar or non-polar (iv)
(a) SeF4
Best Lewis Structure
e group arrangement:_
shape/molecular geometry:
polarity:
(b) AsOBr3
Best Lewis Structure
e group arrangement:_
shape/molecular geometry:
polarity:
Sketch (with angles):
Sketch (with angles):
(c) SOCI
Best Lewis Structure
2
e group arrangement:
shape/molecular geometry:_
(d) PCls
Best Lewis Structure
polarity:
e group geometry:_
shape/molecular geometry:_
(e) Ba(BrO2):
Best Lewis Structure
polarity:
e group arrangement:
shape/molecular geometry:
polarity:
Sketch (with angles):
Sketch (with angles):
Sketch (with angles):
Chapter 5 Solutions
Student Solutions Manual for Bettelheim/Brown/Campbell/Farrell/Torres' Introduction to General, Organic and Biochemistry, 11th
Author:Steven D. Gammon, Ebbing, Darrell Ebbing, Steven D., Darrell; Gammon, Darrell Ebbing; Steven D. Gammon, Darrell D.; Gammon, Ebbing; Steven D. Gammon; Darrell
Author:Steven D. Gammon, Ebbing, Darrell Ebbing, Steven D., Darrell; Gammon, Darrell Ebbing; Steven D. Gammon, Darrell D.; Gammon, Ebbing; Steven D. Gammon; Darrell