0
What else can I help you with?
What best describes a flight approaching the speed of sound?
If accelerating to the speed of sound, the subsonic.
What best describes a flight that is approaching speed of sound?
We call them ultra sonic planes. There is a sonic boom it is traveling when this speed.
If a light source is approaching you at a speed very close to the speed of light it will appear to be what color?
That all depends what color it was when it left the source. Whatever wavelength it had at the source, if it's approaching you, you'll measure a shorter wavelength (higher frequency) as it passes you. But don't forget that regardless of the speed or direction of the source, you'll measure the light passing you at the 'speed of light' ... no more or less.
If a light source is approaching you at a speed very close to the speed of light, it will appear?
to be blue-shifted and brighter due to the relativistic Doppler effect.
What is the equation for velocity approaching that the speed of light?
The equation for velocity approaching the speed of light is given by the relativistic velocity addition formula: v = (u + v') / (1 + u*v'/c^2), where v is the relative velocity between two objects, u is the velocity of the first object, v' is the velocity of the second object, and c is the speed of light in a vacuum.
What best describes a flight approaching the speed of sound?
If accelerating to the speed of sound, the subsonic.
What best describes a flight that is approaching speed of sound?
We call them ultra sonic planes. There is a sonic boom it is traveling when this speed.
If a light source is approaching you at a speed very close to the speed of light it will appear to be what color?
That all depends what color it was when it left the source. Whatever wavelength it had at the source, if it's approaching you, you'll measure a shorter wavelength (higher frequency) as it passes you. But don't forget that regardless of the speed or direction of the source, you'll measure the light passing you at the 'speed of light' ... no more or less.
If a light source is approaching you at a speed very close to the speed of light, it will appear?
to be blue-shifted and brighter due to the relativistic Doppler effect.
How fast is Hannah Erickson?
Almost as fast as wonderwoman--or approaching the speed of light which ever your prefer.
Which of these best describes a flight that is approaching the speed of sound?
more drag is created because the air molecules are not moving out of the way of the airplane
How does the speed of light change relative to a moving object?
The speed of light remains constant regardless of the motion of the observer or the source of light. This principle is known as the constant speed of light in a vacuum, as described by Einstein's theory of relativity.
How long is the flight from Montreal to Lebanon?
1 second if you go at the speed of light
What is speed of light raised to the speed of light?
The speed of light is roughly 300 million meters per second.The mathematical operation described in the question has no meaning and can't be carried out,since the exponent must be a dimensionless number.
Why is the speed of light constant?
The speed of light is constant because it is a fundamental property of the universe, as described by the theory of relativity. This constant speed of light plays a crucial role in maintaining the consistency of physical laws and the structure of spacetime.
What is the equation for velocity approaching that the speed of light?
The equation for velocity approaching the speed of light is given by the relativistic velocity addition formula: v = (u + v') / (1 + u*v'/c^2), where v is the relative velocity between two objects, u is the velocity of the first object, v' is the velocity of the second object, and c is the speed of light in a vacuum.
Why does light move at a constant speed in a vacuum?
Light moves at a constant speed in a vacuum because of the properties of space and time, as described by the theory of relativity. According to this theory, the speed of light is a fundamental constant and does not change regardless of the observer's motion or the source of the light.
