The qualitative graphs that distinguish between the following properties have to be drawn. PV versus V at constant T Concept Introduction Ideal gas law : This law expressed by following equation is, PV = nRT Where, P - Pressure V - volume n - Number of moles R - Gasconstant T -Temperature Boyle’s law: Boyle’s law states that relationship between pressure of the gas and volume. That is pressure is inversely proportional to volume. Pressure α 1 Volume Charles’s law: This law states that relationship between volume of an ideal gas and temperature at constant pressure. That is volume is directly proportional to temperature. Volume α Temperature
The qualitative graphs that distinguish between the following properties have to be drawn. PV versus V at constant T Concept Introduction Ideal gas law : This law expressed by following equation is, PV = nRT Where, P - Pressure V - volume n - Number of moles R - Gasconstant T -Temperature Boyle’s law: Boyle’s law states that relationship between pressure of the gas and volume. That is pressure is inversely proportional to volume. Pressure α 1 Volume Charles’s law: This law states that relationship between volume of an ideal gas and temperature at constant pressure. That is volume is directly proportional to temperature. Volume α Temperature
Study of body parts and their functions. In this combined field of study, anatomy refers to studying the body structure of organisms, whereas physiology refers to their function.
Chapter 5, Problem 131AE
a)
Interpretation Introduction
Interpretation: The qualitative graphs that distinguish between the following properties have to be drawn.
PV versus V at constant T
Concept Introduction
Ideal gas law: This law expressed by following equation is,
PV = nRT
Where,
P - PressureV - volumen - Number of molesR - GasconstantT -Temperature
Boyle’s law: Boyle’s law states that relationship between pressure of the gas and volume. That is pressure is inversely proportional to volume.
Pressureα1Volume
Charles’s law: This law states that relationship between volume of an ideal gas and temperature at constant pressure. That is volume is directly proportional to temperature.
Volume α Temperature
b)
Interpretation Introduction
Interpretation: The qualitative graphs that distinguish between the following properties have to be drawn.
P versus T at constant V
Concept Introduction
Ideal gas law: This law expressed by following equation is,
PV = nRT
Where,
P - PressureV - volumen - Number of molesR - GasconstantT -Temperature
Boyle’s law: Boyle’s law states that relationship between pressure of the gas and volume. That is pressure is inversely proportional to volume.
Pressureα1Volume
Charles’s law: This law states that relationship between volume of an ideal gas and temperature at constant pressure. That is volume is directly proportional to temperature.
Volume α Temperature
c)
Interpretation Introduction
Interpretation: The qualitative graphs that distinguish between the following properties have to be drawn.
T versus V at constant P
Concept Introduction
Ideal gas law: This law expressed by following equation is,
PV = nRT
Where,
P - PressureV - volumen - Number of molesR - GasconstantT -Temperature
Boyle’s law: Boyle’s law states that relationship between pressure of the gas and volume. That is pressure is inversely proportional to volume.
Pressureα1Volume
Charles’s law: This law states that relationship between volume of an ideal gas and temperature at constant pressure. That is volume is directly proportional to temperature.
Volume α Temperature
d)
Interpretation Introduction
Interpretation: The qualitative graphs that distinguish between the following properties have to be drawn.
P versus V at constant T
Concept Introduction
Ideal gas law: This law expressed by following equation is,
PV = nRT
Where,
P - PressureV - volumen - Number of molesR - GasconstantT -Temperature
Boyle’s law: Boyle’s law states that relationship between pressure of the gas and volume. That is pressure is inversely proportional to volume.
Pressureα1Volume
Charles’s law: This law states that relationship between volume of an ideal gas and temperature at constant pressure. That is volume is directly proportional to temperature.
Volume α Temperature
e)
Interpretation Introduction
Interpretation: The qualitative graphs that distinguish between the following properties have to be drawn.
P versus
1V at constant T
Concept Introduction
Ideal gas law: This law expressed by following equation is,
PV = nRT
Where,
P - PressureV - volumen - Number of molesR - GasconstantT -Temperature
Boyle’s law: Boyle’s law states that relationship between pressure of the gas and volume. That is pressure is inversely proportional to volume.
Pressureα1Volume
Charles’s law: This law states that relationship between volume of an ideal gas and temperature at constant pressure. That is volume is directly proportional to temperature.
Volume α Temperature
f)
Interpretation Introduction
Interpretation: The qualitative graphs that distinguish between the following properties have to be drawn.
PVT versus P
Concept Introduction
Ideal gas law: This law expressed by following equation is,
PV = nRT
Where,
P - PressureV - volumen - Number of molesR - GasconstantT -Temperature
Boyle’s law: Boyle’s law states that relationship between pressure of the gas and volume. That is pressure is inversely proportional to volume.
Pressureα1Volume
Charles’s law: This law states that relationship between volume of an ideal gas and temperature at constant pressure. That is volume is directly proportional to temperature.
(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):
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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