AP Physics 2 Ultimate Guide

Substances which can flow.

Mass per unit volume of a substance

kg/m³

g/cc

Magnitude of normal force acting per unit area

Pascal

Pressure due to liquid

Density of liquid and depth below the surface

Archimedes Principle

If a body is fully or partially immersed in a fluid, it experiences an upward force due to the fluid called buoyant force.

Volume of fluid that passes through a particular point per unit of time.

F = Av

A = cross-sectional area

v=flow speed

The density of fluid is constant. Thus, A1V1 = A2V2.

At comparable heights, the pressure is lower where the flow speed is greater.

atm, bar, torr

m³/s

The fluid is incompressible.

The fluid’s viscosity is negligible.

The fluid is streamlined.

The air on the bottom has greater pressure and pushes up on the wing, giving the airplane lift force.

Thermal energy is transmitted from one body to another.

Energy in transit.

It is a measure of an object’s internal energy.

• It relates to the macroscopic properties of gases such as pressure, temperature, etc.

• Every gas consists of small particles known as molecules.

• The gas molecules are identical but different from those of another gas.

• The volume of molecules is negligible compared to the volume of gas.

• The density of a gas is constant at all points.

• Consequently, pressure is exerted by gas molecules on the walls of the container.

• No attractive or repulsive force exists between the gas molecules.

Pv = nRT

• P = pressure

• V = volume

• n = no. of moles

• R = Gas constant

• T = temperature

The pressure exerted by N molecules of gas in a container is related to the average kinetic energy.

K avg = 3/2 kb T

• K avg = average kinetic energy

• kb = Boltzmann’s constant

• T = temperature

It gives us a type of average speed that is easy to calculate from the temperature of the gas.

vrms = √3 kb T/ m

• vrms = root mean square velocity

• kb = Boltzmann’s constant

• T = temperature

• m = mass

• The Kinetic theory of gases applies to a large number of particles.

• Some molecules will be moving faster than average and some much slower.

It is a device which uses heat to produce useful work.

The movement caused within a fluid by the tendency of hotter and therefore less dense material to rise, and colder, denser material to sink under the influence of gravity, which consequently results in transfer of heat.

Emission or transmission of energy in the form of waves or particles through space or through a material medium.

If objects 1 and 2 are in thermal equilibrium with Object 3, then Objects 1 and 2 are in thermal equilibrium with each other.

It is a special case of the law of conservation of energy that describes processes in which only internal energy changes and the only energy transfers are by heat and work.

∆ U = Q + W

• Q = heat added

• W = work done by the system

• ∆ U = change in internal energy

It is used to calculate work done

Temperature remains constant

No transfer of heat

Pressure remains constant

Volume remains constant

It describes how systems evolve over time.

It is associated with a state of randomness, disorder, or uncertainty

Heat conducts from one point to another only if there is a temperature difference between the two objects.

• In an isolated system, the charge is always conserved.

• Protons and electrons have a quality called electric charge.

• The charge is invariant in nature.

• The charge is quantized.

• (Q = n e)

  • e = 1.6 * 10^-19 C

  • n = no. of electrons

  • Q = charge

The electric force between two particles with charges q1 and q2 separated by distance r has a magnitude by the equation:

F = Kq1q2/r^2

• F = force

• K = coulomb’s constant

• q1 and q2 = charges

• r = distance between the charges

Consider three point charges: q1, q2, and q3. The total electric force acting on, say, is simply the sum of F1-on-2, the electric force on q2 due to q1, and F3-on-2, the electric force on q2 due to q3:

The space is surrounded by a charge in which another charged particle experiences the force.

E = F on q/ q

It describes the electric field vector from the force vector on a positive charge.

The electric field surrounding the point charge is:

E = 1/4πε0 * Q/r^2

• E = electric field

• Q = charger = distance between charges

• ε0 = permittivity of free space

• Radial field

• It is generated by a collection of point charges.

• An infinite sheet of charge.

• The electric fields follow the same addition properties as the electric force.

• The electric field lines never cross.

A lot of problems deal with the uniform electric field. The field may be taken as uniform at least in the middle. The uniform field just signifies the constant force.

Materials which allow the flow of excess charge without resisting it.

Materials that resist the flow of electrons.

It involves rubbing the insulator against another material, thereby stripping electrons from one to another material.

When we connect two conductors charge flows from one to another until the potential of both the conductors becomes the same.

The process of charging by induction may be used to redistribute charges among a pair of neutrally charged spheres.

There aren’t any free electrons. The atoms make up the sphere will become polarised.

positive

negative

the directions of the electric forces on the charges of mutual interaction; like charges repel, opposite charges attract.

an object with an excess of positive or negative charges

accomplished by Friction, Contact, Induction, or Polarization

Charging by Polarization

By gaining/losing electrons

Conserved

1 e = 1.6 x 10^-19 Coulombs

coulombs

Only the small spot which was directly contacted with a charge remains charged.

semiconductors

two equal and opposite charged

From positive to negative charges ALWAYS

The density of field lines

a weak field

law of conservation of electric charge

We is the work done by the electric force, then the change in the charge’s electrical potential energy is defined by:

Ue = electrical potential energy

We = work done by electric force

Electrical potential energy required to move along the field lines surrounding a point charge is given by:

• q1 and q2 = charges

• e0 = permeability of free space

• Ue = electrical potential energy

• r = distance

Electric potential is the electric potential energy per unit of charge at a point in an electric field, measured in volts (V). It's the work done per unit charge in bringing a test charge from infinity to that point.

V = U/q

Consider the electric field created by a point source charge Q. If a charge moves from a distance rA to a distance rB from Q, then the change in the potential energy is:

• Ub and Ua = electrical potential energies for a and b

• ra and rb = distances for a and b

• e0 = permeability of free space

An equipotential surface is a surface in a region of space where every point on the surface is at the same potential. In other words, no work is required to move a charge along an equipotential surface. Equipotential surfaces are perpendicular to electric field lines and can be used to visualize the electric field in a given region.

V = kQ/r

• V = electric potential energy

• q = point charger = distance between any point around the charge to the point charge

• k = Coulomb constant; k = 9.0 × 109 N

Equipotential curves are curves of constant elevation. If you walk along any of the contour lines and you neither ascend nor descend, then the curve is known as the equipotential curve.

A drawing of several equipotential curves at various values of the potential for a charge distribution is called an equipotential map.

Two conductors, separated by some distance carry equal but opposite charges +Q and -Q. The pair comprises a system called a capacitor.

The capacitor is in the form of parallel metal plates or sheets.

The capacitance measures the capacity for holding charge.

C = κε₀A/d (k = dielectric constant)

Fringing fields extend beyond conductor or magnetic material edges. They weaken as the distance from the edge increases. They're important in device design but can cause interference and affect performance.

The energy stored in a capacitor can be calculated using the formula

Uc = ½QV = ½CV² where

U is the energy stored in joules, C is the capacitance of the capacitor in farads and V is the voltage across the capacitor in volts.

To keep the plates of the capacitor apart they are filled with dielectric which increases the capacitance of the capacitor.

W = q E d

• W = work done

• q = charge

• E = electric field

• d = distance

increases

reciprocal

series

adding

parallel

1 Farad

capacitance

∆V = -Ed