nternal energy increase=Heat +Work Heat as energy c can be considered constant where the substance is not having significant internal structure changes (away from phase transitions). gy can be transferred into a system by heat and work l energy is part of internal energy that depends on temperatu emperature reflects kinetic energy: For monoatomic gases: W Q U dT c M dU th T k molecule per K B avg 2 3 ) ( T Nk U B th 2 3
Internal energy increase=Heat +Work Heat as energy c can be considered constant where the substance is not having significant internal structure changes.
Dec 17, 2015
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WQU Internal energy increase=Heat +Work
Heat as energy
dTcMdU th c can be considered constant where the substance is not having significant internal structure changes (away from phase transitions).
Energy can be transferred into a system by heat and work
Thermal energy is part of internal energy that depends on temperature.
TkmoleculeperK Bavg 2
3)( Temperature reflects kinetic energy:
TNkU Bth
2
3For monoatomic gases:
Potential energy diagrams
CMrdFdV
Vz
V
y
V
x
VF
),,(
Given a potential energy diagram one can get the behavior of systems affected by the potential.
Systems with E>Vh are unbound;Systems with E<Vh are bound;
Vh
Latent heat is energy spent in transforming the state of the substance: it doesn’t change its temperature.(Example: boiling water)
Microscopically: energy is spent into separating atomsagainst their attractions.
C11T.1 An object is free to move along the x axis. It is connected through two identical springs to two points ±y0 on the y axis. When the object is at x=0, both springs are equally compressed. What kind of position is x=0?
A. Unstable equilibrium;
B. Stable equilibrium;
C. Not an equilibrium position.
C11T.1 An object is free to move along the x axis. It is connected through two identical springs to two points ±y0 on the y axis. When the object is at x=0, both springs are equally compressed. What kind of position is x=0?
A. Unstable equilibrium;
B. Stable equilibrium;
C. Not an equilibrium position.
C11T.2 If your stove provides thermal energy at a rate of 4500 J/s, about how much water can you boil in a minute?
A. 0.002 kg;
B. 0.12 kg;
C. 2 kg;
D. 120 kg.
C11T.2 If your stove provides thermal energy at a rate of 4500 J/s, about how much water can you boil in a minute?
A. 0.002 kg;
B. 0.12 kg;
C. 2 kg;
D. 120 kg.
C11T.3 A 300-g hunk of ice at 0 degree C is placed in a thermos bottle containing 1 kg of water at 20 degree C. If the thermos perfectly insulates the ice-water system from the outside world, what will be the final temperature of the system?
A. Below 0 degree C;
B. Almost exactly 0 degree C;
C. Somewhat above 0 degree C;
D. Very roughly 10 degrees C;
E. Somewhat below 20 degrees C.
C11T.3 A 300-g hunk of ice at 0 degree C is placed in a thermos bottle containing 1 kg of water at 20 degree C. If the thermos perfectly insulates the ice-water system from the outside world, what will be the final temperature of the system?
A. Below 0 degree C;
B. Almost exactly 0 degree C;
C. Somewhat above 0 degree C;
D. Very roughly 10 degrees C;
E. Somewhat below 20 degrees C.
C11T.4 A The thermal energy of a block of ice at 0 degree C melting to a puddle of water at 0 degree C?
A. Increases;
B. Decreases;
C. Doesn’t change.
C11T.4 A The thermal energy of a block of ice at 0 degree C melting to a puddle of water at 0 degree C?
A. Increases;
B. Decreases;
C. Doesn’t change.
C11T.5 An egg will not cook any faster in furiously boiling water than it will in gently simmering water, true or false?
A. True;
B. False.
C11T.5 An egg will not cook any faster in furiously boiling water than it will in gently simmering water, true or false?
A. True;
B. False.
C11T.8 Imagine that the light atom approaches the big atom from infinity with an initial kinetic energy K=5x10-21 J. How close to the big atom does it get?
A. X=0 nm;
B. X=0.04 nm;
C. X=0.11 nm;
D. X=0.2 nm
E. X=0.3 nm.
C11T.8 Imagine that the light atom approaches the big atom from infinity with an initial kinetic energy K=5x10-21 J. How close to the big atom does it get?
A. X=0 nm;
B. X=0.04 nm;
C. X=0.11 nm;
D. X=0.2 nm
E. X=0.3 nm.
C11T.9 Imagine that at a certain instant of time, the light atom is at position x=0.11 nm and has a kinetic energy K=5x10-21 J. About how much energy would we need to add to break the bond?
A. 1x10-21 J;
B. 6x10-21 J;
C. 12x10-21 J;D. None. Bond is
already broken.
C11T.9 Imagine that at a certain instant of time, the light atom is at position x=0.11 nm and has a kinetic energy K=5x10-21 J. About how much energy would we need to add to break the bond?
A. 1x10-21 J;
B. 6x10-21 J;
C. 12x10-21 J;D. None. Bond is
already broken.
C11T.10 Imagine that at a certain instant of time, the light atom is at rest at x=0.20 nm. What is the closest that it will ever get to the heavier atom subsequently (in the absence of external effects)?
A. X=0.03 nm;
B. X=0.05 nm;
C. X=0.20 nm;
D. X=0.40 nm.
C11T.10 Imagine that at a certain instant of time, the light atom is at rest at x=0.20 nm. What is the closest that it will ever get to the heavier atom subsequently (in the absence of external effects)?
A. X=0.03 nm;
B. X=0.05 nm;
C. X=0.20 nm;
D. X=0.40 nm.
C11T.11 If this system has a total energy of +3x10-21 J and the light atom is at x=0.11 nm at a certain time, the atoms are:
A. Bound;
B. Unbound;
C. Depends on the light atom’s initial direction;
D. Depends on the light atom’s initial speed.
C11T.11 If this system has a total energy of +3x10-21 J and the light atom is at x=0.11 nm at a certain time, the atoms are:
A. Bound;
B. Unbound;
C. Depends on the light atom’s initial direction;
D. Depends on the light atom’s initial speed.
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