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Summary

Terminal velocity

In a nutshell

Terminal velocity is the maximum possible velocity an object has as it travels through a fluid. When an object has reached terminal velocity the resultant forces acting on the object is zero.

Equations

DESCRIPTION	SYMBOL EQUATION
Drag	$F = ma$
Drag for a falling object	$W=mg$

Constants

CONSTANT	SYMBOL	VALUE
$acceleration\ due \ to \ gravity$	$g$	$9.81 \, ms^{-2}$

Variable Definitions

QUANTITY NAME	SYMBOL	DERIVED UNIT	SI BASE UNITS
$force$	$F$	$N$	$kgms^{-2}$
$mass$	$m$	$kg$	$kg$
$weight$	$W$	$N$	$kgms^{-2}$
$acceleration$	$a$	$m\,s^{-2}$	$m\,s^{-2}$

Drag

An object moving through a fluid feels a resistive force acting on it called drag. Drag is a frictional force opposing motion. The force depends on multiple factors such as: the speed of the object, the cross-sectional area of the object and the density of the fluid.

When an object is falling through a uniform gravitational field, it is assumed to have a uniform attractive force acting on it:

$W= mg$

Drag forces oppose the force of gravity, and therefore decrease the net force acting on an object. The drag force will increase until it equals the force from the weight of the object, resulting in terminal velocity.

If an object is not under freefall then the generalised equation of Newtons second law can be used:

$F=ma$

Curiosity: fast cars are very low profile and streamlined to reduce the air resistance acting on them.

Terminal velocity

As the velocity increases due to free fall, the drag force also increases. As the weight remains constant, the net force will decrease until it reaches zero. Throughout this period, acceleration will also decrease, as this is proportional to the force.

At the point where the net force is zero, the object will no longer accelerate, and is said to have reached its terminal velocity. It will remain at this velocity until it reaches the ground.

Terminal velocity of a skydiver

Terminal velocity is the maximum possible velocity an object has as it travels through a fluid. An example of terminal velocity is that of a skydiver jumping out of a plane:

1	As soon as the skydiver jumps out of the plane, the skydiver begins to accelerate as their force due to gravity (weight) is much larger than the air resistance.
2	The skydiver's downward velocity rapidly increases, which increases the air resistance. This causes the downwards acceleration of the skydiver to slowly decrease.
3	The downwards acceleration of the skydiver decreases gradually, until the point where the driving force (weight) is equal to the air resistance. The skydiver has reached terminal velocity.
4	The skydiver opens their parachute. This causes the air resistance acting on the skydiver to sharply increase, as the cross-sectional area of the object has increased. The weight of the skydiver has not changed. The force due to gravity is now much less than the air resistance, so the skydiver begins to decelerate.
5	As the skydiver's velocity decreases, so does the air resistance acting on them. The air resistance decreases until it is equal to the skydiver's weight. The skydiver has reached a new, lower terminal velocity.
6	The skydiver falls slowly to the ground.

In summary, skydivers use parachutes to greatly increase the drag acting on them, which acts to decrease their terminal velocity to a value which is safe enough to fall to the ground to.

Moving vehicles can also have terminal velocity as they travel through the air. For a car, the driving force is generated by the engine, and the resistive forces are friction and air resistance.

Note: The amount of drag that is generated depends on the cross-sectional area of the object.

Example

Below is a graph of a shuttlecock falling after it reached $0 \ ms^{-1}$ after it had been hit. Initially, the resultant force was equal to that of it's weight. Then, the drag force increased until both drag and weight were equal. The shuttlecock then reached terminal velocity.

Determining terminal velocity in a fluid

The terminal velocity of a viscous fluid can be determined experimentally. A viscous fluid is placed in a cylinder, marks are made on the cylinder at equal intervals.

A ball bearing is released from rest into the liquid and the timer is started. When the ball bearing passes a mark, the stopwatch is lapped.

The distances between the marks is known and as the time is collected from the stopwatch, so the velocity can be calculated.

When the ball bearing has reached terminal velocity, the velocity of the ball will become constant.

Physics; Fluids; KS5 Year 12; Terminal velocity

1.	Ball bearing enters the viscous fluid.
2.	The distance between markers are at regular intervals.
3.	The cylinder.
4.	Ball reaches terminal velocity.
5.	The bottom of the cylinder.

Learn with Basics

Length:

Unit 1

Air and water resistance

Unit 2

Friction and terminal velocity

Jump Ahead

Unit 3

Terminal velocity

Final Test

Create an account to complete the exercises

FAQs - Frequently Asked Questions

What is drag?

Drag is something that occurs when an object passes through a fluid, such as a boat moving through water.

Why do skydivers use parachutes?

Skydivers use parachutes to greatly increase the drag acting on them, which acts to decrease their terminal velocity to a value which is safe enough to fall to the ground to.

What is terminal velocity?

Terminal velocity is the maximum possible velocity an object has as it travels through a fluid.

Home

Physics

Forces in action

Terminal velocity

Videos

Summary

Exercises

Select Lesson

Exam Board

Select an option

Medical physics

X-rays: structure, uses and attenuation

Medical tracers

Ultrasound and the piezoelectric effect

Acoustic impedance

Nuclear physics

Einstein's mass-energy equation

Nuclear fission and nuclear reactors

Nuclear fusion

Radioactivity

Radioactivity: alpha, beta and gamma radiation

Half-life and radioactive decay

Modelling radioactive decay

Particle physics

The nuclear model of the atom

Magnitudes of the atom

Fundamental particles

Quarks and anti-quarks

Electromagnetism

Magnetic fields and electromagnetism

Magnetic flux density

Charged particles in a magnetic field

Faraday's and Lenz's Laws

Uses of electromagnetic induction

Electric fields

Coulomb's law

Electric field between two parallel plates

Motion of charged particles in an electric field

Electric potential and potential energy

Capacitance

Capacitors and capacitance

Energy stored in a capacitor

Charging and discharging capacitors

Cosmology

Units for astronomical distances

Hubble's law

The evolution of the Universe

Stars

The life cycle of stars

Energy levels and spectra

Black-body radiaton and stellar luminosity

Gravitational fields

The law of gravitation

Kepler's laws

Gravitational potential and gravitational potential energy

Oscillations

Simple harmonic motion

Displacement, velocity and acceleration for simple harmonic motion

Energy within simple harmonic motion

Damping and resonance

Circular motion

Angular velocity and the radian

Centripetal acceleration

Centripetal force

Thermal physics

Measuring temperature and temperature scales

Solids, liquids and gases

Internal energy

Specific latent heat and specific heat capacity

Ideal gases

The ideal gas law

Kinetic theory of gases: Root mean square speed

Quantum physics

The photon model

The photoelectric effect

The photoelectric effect equation

Wave-particle duality

Waves

Progressive waves

Waves: displacement-time and distance-time graphs

Refraction and Snell's law

Reflection and the critical angle

Intensity of a wave

Diffraction and polarisation

The principle of superposition

Young's double-slit experiment

Stationary waves

Harmonics

Electrical circuits

Circuits: diagrams and components

Potential difference and electromotive force

Resistance and Ohm's Law

Resistivity

I-V characteristics

The kilowatt hour and paying for electricity

Combining resistors and Kirchhoff's Laws

Internal resistance

Potential dividers

Current and charge

Current and charges

Conventional current and electron flow

Mean drift velocity

The electronvolt and work done on electrons

Newton's laws of motion and momentum

Momentum: definition, conservation and calculations

Collisions in two dimensions

Newton's laws of motion

Materials

Hooke's law

Elastic and plastic deformation

Stress, strain and Young's modulus

Stress-strain graphs

Work, energy and power

Forms of energy, conservation and work done

Kinetic energy and gravitational potential energy

Power and efficiency

Forces in action

Mass, weight and centre of mass

Resolving forces

Triangle of forces

The principle of moments

Couples and torques

Terminal velocity

Density and pressure

Motion

Displacement and velocity

Acceleration and velocity-time graphs

Equations of motion

Speed and stopping distances

Acceleration and free fall

Projectile motion

Foundations of physics

Physical quantities and units

How to plan an experiment

Hazards, risks and results

Analysing data

Evaluating data

Scalar and vector quantities

Resolving vectors

Explainer Video

Tutor: Kirsty

Summary

Terminal velocity

In a nutshell

Terminal velocity is the maximum possible velocity an object has as it travels through a fluid. When an object has reached terminal velocity the resultant forces acting on the object is zero.

Equations

DESCRIPTION	SYMBOL EQUATION
Drag	$F = ma$
Drag for a falling object	$W=mg$

Constants

CONSTANT	SYMBOL	VALUE
$acceleration\ due \ to \ gravity$	$g$	$9.81 \, ms^{-2}$

Variable Definitions

QUANTITY NAME	SYMBOL	DERIVED UNIT	SI BASE UNITS
$force$	$F$	$N$	$kgms^{-2}$
$mass$	$m$	$kg$	$kg$
$weight$	$W$	$N$	$kgms^{-2}$
$acceleration$	$a$	$m\,s^{-2}$	$m\,s^{-2}$

Drag

When an object is falling through a uniform gravitational field, it is assumed to have a uniform attractive force acting on it:

$W= mg$

If an object is not under freefall then the generalised equation of Newtons second law can be used:

$F=ma$

Curiosity: fast cars are very low profile and streamlined to reduce the air resistance acting on them.

Terminal velocity

At the point where the net force is zero, the object will no longer accelerate, and is said to have reached its terminal velocity. It will remain at this velocity until it reaches the ground.

Terminal velocity of a skydiver

Terminal velocity is the maximum possible velocity an object has as it travels through a fluid. An example of terminal velocity is that of a skydiver jumping out of a plane:

1	As soon as the skydiver jumps out of the plane, the skydiver begins to accelerate as their force due to gravity (weight) is much larger than the air resistance.
2	The skydiver's downward velocity rapidly increases, which increases the air resistance. This causes the downwards acceleration of the skydiver to slowly decrease.
3	The downwards acceleration of the skydiver decreases gradually, until the point where the driving force (weight) is equal to the air resistance. The skydiver has reached terminal velocity.
4	The skydiver opens their parachute. This causes the air resistance acting on the skydiver to sharply increase, as the cross-sectional area of the object has increased. The weight of the skydiver has not changed. The force due to gravity is now much less than the air resistance, so the skydiver begins to decelerate.
5	As the skydiver's velocity decreases, so does the air resistance acting on them. The air resistance decreases until it is equal to the skydiver's weight. The skydiver has reached a new, lower terminal velocity.
6	The skydiver falls slowly to the ground.

In summary, skydivers use parachutes to greatly increase the drag acting on them, which acts to decrease their terminal velocity to a value which is safe enough to fall to the ground to.

Moving vehicles can also have terminal velocity as they travel through the air. For a car, the driving force is generated by the engine, and the resistive forces are friction and air resistance.

Note: The amount of drag that is generated depends on the cross-sectional area of the object.

Example

Determining terminal velocity in a fluid

The terminal velocity of a viscous fluid can be determined experimentally. A viscous fluid is placed in a cylinder, marks are made on the cylinder at equal intervals.

A ball bearing is released from rest into the liquid and the timer is started. When the ball bearing passes a mark, the stopwatch is lapped.

The distances between the marks is known and as the time is collected from the stopwatch, so the velocity can be calculated.

When the ball bearing has reached terminal velocity, the velocity of the ball will become constant.

1.	Ball bearing enters the viscous fluid.
2.	The distance between markers are at regular intervals.
3.	The cylinder.
4.	Ball reaches terminal velocity.
5.	The bottom of the cylinder.

Learn with Basics

Length:

Unit 1

Air and water resistance

Unit 2

Friction and terminal velocity

Jump Ahead

Unit 3

Terminal velocity

Final Test

Create an account to complete the exercises

FAQs - Frequently Asked Questions

What is drag?

Drag is something that occurs when an object passes through a fluid, such as a boat moving through water.

Why do skydivers use parachutes?

Skydivers use parachutes to greatly increase the drag acting on them, which acts to decrease their terminal velocity to a value which is safe enough to fall to the ground to.

What is terminal velocity?

Terminal velocity is the maximum possible velocity an object has as it travels through a fluid.

Terminal velocity

Videos

Summary

Exercises

Select Lesson

Exam Board

Medical physics

Nuclear physics

Radioactivity

Particle physics

Electromagnetism

Electric fields

Capacitance

Cosmology

Stars

Gravitational fields

Oscillations

Circular motion

Thermal physics

Quantum physics

Waves

Electrical circuits

Current and charge

Newton's laws of motion and momentum

Materials

Work, energy and power

Forces in action

Motion

Foundations of physics

Explainer Video

Summary

Terminal velocity

​​In a nutshell

Equations

DESCRIPTION

SYMBOL EQUATION

Constants

​​CONSTANT

SYMBOL

VALUE

Variable Definitions

QUANTITY NAME

SYMBOL

DERIVED UNIT

SI BASE UNITS

Drag

​​Terminal velocity

Terminal velocity of a skydiver

Example

Determining terminal velocity in a fluid

1.

2.

3.

4.

5.

Learn with Basics

Unit 1

Air and water resistance

Unit 2

Friction and terminal velocity

Jump Ahead

Unit 3

Terminal velocity

Final Test

FAQs - Frequently Asked Questions

What is drag?

Why do skydivers use parachutes?

What is terminal velocity?

Terminal velocity

Videos

Summary

Exercises

Select Lesson

Exam Board

Medical physics

Nuclear physics

Radioactivity

Particle physics

Electromagnetism

Electric fields

In a nutshell

CONSTANT

Terminal velocity

In a nutshell

CONSTANT

Terminal velocity