Answer : Mass
Explanation : An object's resistance to change in motion is solely dependent on the mass of the quantity. The tendency to resist the change in motion is called as inertia. Which is highly influenced by the factor called "mass" of the object. The mass of the quantity will decide the direction for change in the motion of a particular object.
C:a gymnast doing a cart wheel
D:a swimwear doing the backstroke
Please answer asapppppp I need help
I think it's B. A car stopped at the top the hill
A: bird making a nest
I may be wrong. Hope it helps.
A)
amplitudes
B)
wave speeds
C)
wavelengths
D)
polarization
Different colors after reflection appear due to the different wavelengths of light. Therefore, option C is correct.
The wavelength of the light can be defined as the distance between the two points in phase w.r.t. each other such as two crests or troughs on a wave. The frequency of the light is the number of oscillations of a wave in one second and has S.I. units of per second or hertz.
The expression between frequency (ν), wavelength (λ), and speed of light (c) is:
c = νλ
A wave moving at a fixed wave speed has a wavelength that is inversely proportional to the frequency therefore, the waves with higher frequencies have shorter wavelengths, while lower frequencies have higher wavelengths.
The speed depends upon the medium as it propagates. In particular, the speed of light in a particular medium is less than in a vacuum, therefore the same frequency will have a shorter wavelength.
When the light is reflected the colors are formed as due to different wavelengths.
Learn more about wavelength and frequency, here:
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a real image
a virtual image
a refracted image
Answer:
a virtual image
Explanation:
gradpoint
Answer:
V = 5.5 mL
Explanation:
The volume filled in the graduated cylinder is 12.7 mL
now when a stone is dropped into the cylinder then the volume of liquid is raised to final level of 18.2 mL
so as per the theory of given by Archimidies we can say that the volume of the object is exactly same as the volume displaced by the object
So here the volume displaced by the object is given as
so the volume of the object is given as