Once you have carried out your experiment and have some results, you shouldA. make a new hypothesis that fits your results
B. keep your results only if they support your hypothesis
C. design a new experiment to test your results
D. analyze your results and draw a conclusion
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Answer:
I think the answer is D
Explanation:
not sure
but if its correct can i get brainliest??
Related Questions
DEFINE UNIFORM AND NON UNIFORM VELOCITY
A magnetic field forms around a moving electric charge, resulting in a magnetic field. Which does this describe? A. how electric charges can be used to make current flow B. how electric charges can be used to create a magnetic field C. how a magnetic field can be used to generate an electric current D. how a magnetic field can be used to generate electrons
Answer to number 8 please
A block of metal initially at 25°C is submerged in water initially at 75°C in a coffee cup. Which of the following is true? a. The final temperature of the coffee cup will be less than 20°C. b. The final temperature of the coffee cup will be higher than 25°C but less than 75°C. c. The final temperature of the coffee cup will be more than 80°C. d. The final temperature of the coffee cup will be 80°C.
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Answer:
C. small bodies and long limbs in warm-blooded organisms, light colored fur or feathers to reflect sunlight, lack of sweat glands in many organisms, hibernation during hot months
Explanation:
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Answer:
The formula for acceleration due to gravity at the surface of a celestial body is:
a = (G * M) / r^2
Where:
G (the gravitational constant) is approximately 6.67430 x 10^-11 m^3 kg^-1 s^-2.
M (the mass of Jupiter) is approximately 1.898 x 10^27 kilograms.
r (the mean radius of Jupiter) is approximately 71,492,000 meters.
Now, let's calculate it:
a = (6.67430 x 10^-11 m^3 kg^-1 s^-2 * 1.898 x 10^27 kg) / (71,492,000 meters)^2
a ≈ 24.79 m/s^2
So, the free-fall acceleration at the surface of Jupiter is approximately 24.79 m/s^2.
Final answer:
The free-fall acceleration on the surface of Jupiter (g) is calculated by using Newton's Universal Law of Gravitation (g = G * M / r^2), where G is the gravitational constant, M is the mass of Jupiter and r is the radius of Jupiter.
Explanation:
To calculate the acceleration due to gravity at the surface of Jupiter, we can use Newton's Universal Law of Gravitation. It states that the force of gravity is equal to the gravitational constant (G) times the mass of the body (in this case, Jupiter) divided by the radius of the body squared. The formula can be expressed as F = G * (M * m / r^2), where F is the force of gravity, G is the gravitational constant, M is the mass of the larger body (Jupiter), m is the mass of the smaller body (object in question), and r is the distance between the centers of the two bodies - which is the radius of Jupiter when the object is on its surface.
The formula to find the acceleration due to gravity (g) on the surface of Jupiter is found by setting the weight of an object (F = m*g) equal to the gravity force (F = G * (M * m / r^2)) leading to the cancellation of the mass of the object (m). That results in g = G * M / r^2. This means that the acceleration due to gravity on the surface of Jupiter depends on the mass of Jupiter and the radius of Jupiter, and not on the mass of the object.
Learn more about Jupiter's Free-fall Acceleration here:
#SPJ11
= 0.334 MJ/kg,
= 2.26 MJ/kg.
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Answer:
2726.54 J/K
Explanation:
Entropy change =
where
m = mass of water = 450g = 0.45kg
= 2.26 MJ/kg = 2260000 J/kg
T = temperature at which water change from liquid to steam = 100 degree Celsius = 272 + 100 = 373 degree kelvin.
Entropy change = = 2726.54 J/K
cooled air
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I also think it's hot air, but I'm pretty sure it's because hot air rises. I'm not 100% sure so I'm sorry if it wrong :)
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90-95 Percent, (I took the test and got an 100).
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Answer: The amount of heat required for this process is 172.5 kJ.