If the Earth and distant stars were stationary (motionless) in space, what would we observe about the wavelength from these stars?

A. Wavelengths measured would match the actual wavelengths emitted.

B. Wavelengths measured would be shorter than the actual wavelengths emitted.

C. Wavelengths measured would be longer than the actual wavelengths emitted.

If a star is moving toward us in space, what would we observe about the wavelength from these stars?

A. Wavelengths measured would be shorter than the actual wavelengths emitted.

B. Wavelengths measured would match the actual wavelengths emitted.

C. Wavelengths measured would be longer than the actual wavelengths emitted.

Question

Physics

Savion Murray

Today, 15:36

If the Earth and distant stars were stationary (motionless) in space, what would we observe about the wavelength from these stars?

A. Wavelengths measured would match the actual wavelengths emitted.

B. Wavelengths measured would be shorter than the actual wavelengths emitted.

C. Wavelengths measured would be longer than the actual wavelengths emitted.

If a star is moving toward us in space, what would we observe about the wavelength from these stars?

A. Wavelengths measured would be shorter than the actual wavelengths emitted.

B. Wavelengths measured would match the actual wavelengths emitted.

C. Wavelengths measured would be longer than the actual wavelengths emitted.

+2

Answers (1)

Know the Answer?

Bobby Moreno · Answer 1

There's no such thing as "stationary in space". But if the distance

between the Earth and some stars is not changing, then (A) w avelengths

measured here would match the actual wavelengths emitted from these

stars.

If a star is moving toward us in space, then (A) Wavelengths measured

would be shorter than the actual wavelengths emitted from that star.

In order to decide what's actually happening, and how that star is moving,

the trick is: How do we know the actual wavelengths the star emitted?