As the temperature of a substance decreases, theaverage kinetic energy of its particles
(1) decreases
(2) increases
(3) remains the same
Answers
Answer: Option (1) is the correct answer.
Explanation:
Kinetic energy is the energy that arises due to the motion of molecules. Average kinetic energy involves the sum of vibrational, translational and rotational kinetic energies.
When we decrease the temperature then the movement of molecules starts to decrease. As a result, there will be decrease in the average kinetic energy of its particles.
Thus, we can conclude that as the temperature of a substance decreases, the average kinetic energy of its particles decreases.
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Express your answer using three significant figures.
Answers
Answer:
-115°C is the temperature on planet X.
Explanation:
Pressure inside the space station =
1 atm = 760 mmHg
Temperature inside the space station =
Volume of the air filled in the balloon =
1 mL = 0.001 L
Atmospheric pressure on planet X =
Temperature on the planet X =
Volume of the air filled in the balloon on planet X =
Using combined gas equation :
-115°C is the temperature on planet X.
Final answer:
Using the ideal gas law, the temperature on planet X is calculated to be approximately -148.5 °C, after converting all units to standard and then adjusting the final result from Kelvin to Celsius.
Explanation:
This is a classic problem in physics that uses the ideal gas law, which states that the pressure of a gas multiplied by its volume is directly proportional to the amount of gas and the temperature. Using the provided data about the initial conditions inside the space station and the final conditions on planet X, the final temperature can be found by using the equation P1V1/T1 = P2V2/T2, where P refers to pressure, V refers to volume, and T refers to temperature.
First, we need to convert all measurements to the standard units: Pressure in atm and volume in liters. So, initially the pressure inside the space station is 761 mmHg or approximately 1 atm (since 1 atm = 760 mmHg), the volume of the balloon is 855 mL or 0.855 L, and the temperature is 27 °C or 300.15 K (since 0 °C = 273.15 K). On planet X, the pressure is given as 0.14 atm and the volume as 3.21 L.
Substituting these values into our ideal gas law equation, we can find the final temperature T2 on planet X: T2 = P2V2T1 / P1V1 = (0.14 atm * 3.21 L * 300.15 K) / (1 atm * 0.855 L) = approximately 124.68 K.
To convert this value from Kelvin to degrees Celsius, we subtract 273.15, getting approximately -148.47 °C.
Therefore, the temperature on planet X is approximately -148.5 °C, given to three significant figures.
Learn more about Ideal Gas Law here:
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Answer:
V=d/t
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T = 18 + 273
T = 291 K
hope this helps!
Answer:
T = 291 K
Explanation:
(b) waste materials
(c) blood
(d) nutrients
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nutrients between the mother and the fetus. The fetal blood comes extremely
close to the maternal blood in the placenta, but there is no intermingling of fetal
and maternal blood. The fetus and mother can even have, and often do have,
different blood types.
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Answer:
In the image below
Explanation:
Hope this helps you :)