no it does not
As density increases, the velocity of sound increases because there are more particles for the sound wave to travel through. Conversely, if the density decreases, the velocity of sound will also decrease because there are fewer particles for the sound wave to travel through.
As height increases, the velocity generally decreases due to the effect of gravity. This is because potential energy increases while kinetic energy decreases, resulting in a slower velocity.
Kinetic energy is affected by an object's mass and its velocity. The kinetic energy of an object increases as its mass or velocity increases. Conversely, kinetic energy decreases as mass or velocity decreases.
A logarithmic graph would best represent the relationship between stream velocity and the size of particles it can carry downstream. As velocity increases, the stream can carry larger particles due to increased erosion and transport capacity. However, there will be a limit to the size of particles carried downstream as velocity continues to increase.
If the frequency of a wave increases while the velocity stays the same, the wavelength of the wave must decrease. This relationship is governed by the equation v = f * λ, where v is the velocity, f is the frequency, and λ (lambda) is the wavelength. As frequency increases, wavelength decreases in order to keep the velocity constant.
As density increases, the velocity of sound increases because there are more particles for the sound wave to travel through. Conversely, if the density decreases, the velocity of sound will also decrease because there are fewer particles for the sound wave to travel through.
As height increases, the velocity generally decreases due to the effect of gravity. This is because potential energy increases while kinetic energy decreases, resulting in a slower velocity.
no it increases
Viscosity increases
Kinetic energy is affected by an object's mass and its velocity. The kinetic energy of an object increases as its mass or velocity increases. Conversely, kinetic energy decreases as mass or velocity decreases.
flattened clay particles
It is a direct relationship as the velocity of the water increases , the rate of erosion also increases. As the velocity increases it will pick up larger objects such as boulders and cobble but remember the biggest objects always get deposited first.
A logarithmic graph would best represent the relationship between stream velocity and the size of particles it can carry downstream. As velocity increases, the stream can carry larger particles due to increased erosion and transport capacity. However, there will be a limit to the size of particles carried downstream as velocity continues to increase.
When the temperature of a gas increases, the average kinetic energy of the gas particles also increases. This leads to an increase in the velocity of the gas particles as they move faster on average. According to the ideal gas law, an increase in temperature causes an increase in the average speed of gas particles.
Kinetic energy is directly proportional to the square of the velocity of an object. This means that as the velocity of an object increases, its kinetic energy increases exponentially. Conversely, if the velocity decreases, the kinetic energy will decrease accordingly.
Particles settle at the mouth of a river when the river water mixes with the calmer ocean water, causing a decrease in flow velocity. This reduction in velocity leads to sediment settling as the river's capacity to transport particles decreases. Additionally, the ocean's higher salinity can also play a role in causing sediment particles to settle due to changes in water density.
When the discharge of a stream increases, so does it's velocity. When it decreases, so does the velocity.