Assuming that Earth is an inertial frame, and that the refraction index of air=1, the maximum possible velocity on Earth is the speed of the light, which equals 299 792 458 m/s. Albert Einstein postulated this back in early 1900's.
When a pendulum reaches its maximum elongation the velocity is zero and the acceleration is maximum
The Earth's rotation
Perhaps you mean terminal velocity. This is the maximum velocity reached by an object falling to the ground when the acceleration due to gravity is matched by the drag resistance of the air through which it is falling.
No. Terminal velocity is a particular kind of velocity and friction is a particular kind of force. The terminal velocity of a falling object is the maximum velocity it can have because air resistance prevents it from going any faster. And air resistance is a type of friction. So terminal velocity is due to a type of friction.
The maximum speed of any object is hardly equal to speed of light which is 3*10^8 approximately.
The maximum possible impact speed of an object falling freely from far away to the surface of the Earth is known as the escape velocity of the Earth, which is approximately 11.2 km/s. This represents the speed required to escape the Earth's gravitational pull and reach infinity.
The declination of Arcturus is approximately +19 degrees. This star is located in the northern hemisphere sky. The maximum velocity of Earth's revolution occurs around January 3rd, when Earth is closest to the Sun in its elliptical orbit, a position known as perihelion.
Maximum velocity is the fastest an intem can go, while optimum velocity is the "best" speed it can travel on. For a car optimum velocity could mean either where you get the best MPG, or where you can go round corners/over bumps without the car starting swaying, or something like that.
There is no such thing as "maximum terminal velocity", neither on Jupiter nor hear on Earth. The "terminal velocity" depends on the specific object - and on the atmospheric conditions. For example, a very heavy object will typically have a larger terminal velocity than one that is very light; and near Earth's surface, the terminal velocity (for a given object) will be smaller than in the upper atmosphere, where there is less air resistance.
To determine the maximum height reached by an object launched with a given initial velocity, you can use the formula for projectile motion. The maximum height is reached when the vertical velocity of the object becomes zero. This can be calculated using the equation: Maximum height (initial velocity squared) / (2 acceleration due to gravity) By plugging in the values of the initial velocity and the acceleration due to gravity (which is approximately 9.81 m/s2 on Earth), you can find the maximum height reached by the object.
When a pendulum reaches its maximum elongation the velocity is zero and the acceleration is maximum
The maximum velocity of photoelectrons is determined by the energy of the incident photons in the photoelectric effect. The higher the energy of the photons, the higher the maximum velocity of the emitted photoelectrons.
The condition for maximum velocity is acceleration equals zero; dv/dt = a= o.
The spring has maximum velocity when it is at its equilibrium position or at maximum compression or extension. This is where the spring has stored the most potential energy, which is then converted into kinetic energy, resulting in the highest velocity.
Maximum Velocity - 2003 is rated/received certificates of: USA:PG-13
A pendulum attains maximum velocity at the lowest point of its swing, when its potential energy is at a minimum and its kinetic energy is at a maximum.
In the case of an object thrown, batted, teed off, or dropped, its acceleration at the instant of its maximum velocity is 9.8 meters per second2 downward.