Kinematics

It is neither a scalar or a vector? Scalar and vectors are used to describe quantities, for example scalars include distance and mass, while vectors include weight and velocity. We do not say that a situation is a scalar or a vector.

"100 mph tape" is a nickname often used for duct tape because of its versatility, durability, and ability to hold up even at high speeds like 100 mph. It is known for its strong adhesive properties and wide range of uses in emergency situations, repairs, and construction work.

yes we can have.

for eg electric current, pressure etc

though these quantities have both magnitude and direction their directions are not necessary to define them

and vectors are those quantities which has magnitude and requires direction to be defined

" quantities having both magnitude and direction is a vector" is not a corrrect definition ofa vector

Current is not scalar. Current is a vector quantity. For simplicity, in electric circuits, current is scalar because the direction is assumed to be one way or another, rather than three dimensional.

It depends on the size of the disappearing sphere. If a small sphere disappeared then air from adjoining space would move in and balance would soon be be restored. However, if a large sphere disappeared then the adjustment could involve extreme turbulence.

If one assumes air resistance to be negligible, then:

final velocity = sqrt( g * 2 * h )

where g is 9.8 metres per second per second.

The quantities v and m do not matter, because gravitational acceleration does not depend on mass (all objects fall at the same rate) and because the horizontal velocity is independent of the vertical velocity.

If the required time is measured from 0 then s = t2 - 8t, therefore 9 = t2 - 8t, which can be written as t2 - 8t - 9 = 0

This equation can be factored as (t - 9)(t + 1) = 0

As we are only concerned with a positive time then the answer is when t - 9 = 0, thus t = 9 seconds.

47.3 miles per hour is approximately equal to 76.1 kilometers per hour when converted using the conversion factor 1 mile = 1.60934 kilometers.

To find the increase in temperature of the brakes, you need to calculate the total kinetic energy of the car before braking and then determine the amount of energy absorbed by the brakes during braking. Using the equation for kinetic energy (0.5 x mass x velocity^2) for the car before braking and equating it to the energy absorbed by the brakes, you can then find the increase in the temperature of the brakes using the specific heat capacity of iron.

Kilometers are not dimensionally equivalent to miles per hour, and thus cannot be converted without an additional time measurement.\

250 km = 155.34 mi

250 km/h = 155.34 mph

These are the only true conversions.

When a moving train stops, its kinetic energy is primarily converted into heat energy due to friction between the train's brakes and the track. Additionally, some kinetic energy may also be converted into sound energy and vibration energy during the process of stopping.

22 miles per hour is approximately equivalent to 35.4 kilometers per hour.

No, kinetic energy is measured in Joules (J), as this is the SI unit for energy.

Not necessarily. The total momentum of a system of objects is conserved unless external forces are present. In a collision involving three objects, the total momentum before the collision could be equal to, greater than, or less than the total momentum after the collision, depending on the specific circumstances of the collision.

The top speed of a 1977 Bandit Trans Am is around 125-130 mph, depending on factors such as engine condition and modifications. These cars were equipped with a 6.6L V8 engine producing around 200-220 horsepower.

The potential energy of the pear can be calculated using the formula: PE = mgh, where m is the mass (0.14 kg), g is the acceleration due to gravity (9.81 m/s^2), and h is the height (3.5 m). Plugging in these values, we get PE = 0.14 kg * 9.81 m/s^2 * 3.5 m = 4.857 J.

Cover your face, now... a sneeze. Incidentally, when you sneeze, it is impossible for you to keep your eyes open by force of will. Your eyes will close.

500 n is a force created by a mass (500 / 9.807) = 50.98 kg

so: potential energy = m * g * h = 50.98 * 9.807 * 10 = 5000 joules.

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if it was 500 kg (not newtons) weight, then m*g*h = 500 * 9.807 * 10 = 49035 joules.

Generally speed. But also, if the obect is for example travellin up, the potential energy also increases.

A pendulum is a classic example where kinetic energy is continually converted to potential energy and vice versa. As the pendulum swings, it reaches its highest point where it has maximum potential energy and minimum kinetic energy, and at the lowest point of its swing, the opposite is true with maximum kinetic energy and minimum potential energy.

A skater will pull his/her arms in close to their body while spinning to increase the speed and force of the spin in routines this also helps to improve the fluency of the routine and is able to keep going in time to the music. They extend their arms to improve the look of the spin within a performance or routine

hope this answered your question :)

To convert feet per second to miles per hour, you can use the conversion factor of 1 foot per second is approximately 0.6818 miles per hour. You can multiply the value in feet per second by 0.6818 to get the equivalent value in miles per hour.

Engine bounce is a phenomenon where the engine speed rises rapidly and then drops back down while the vehicle is idling. This can be caused by issues with the fuel system, ignition system, or engine timing. It can lead to rough idling and poor engine performance.

The kinetic energy of the person riding a bicycle on a road corresponds to mechanical energy. This energy is due to the motion of the person and the bicycle as they travel on the road. It represents the ability to do work or cause a change in the system due to their movement.