WJEC AS Physics

Ver más

Affordable and Clean Energy

por Carolina Antonchuk

Todoist

por Matteo Gentile

Floods

por Tung Wai Kiong Derek (Mr) N/A

Force,Work,Power,Energy

por Vincent Esmena

WJEC AS Physics

Waves and Particles

Motion, Energy and Charge

Resistance

Collisions between free electrons and ions give rise to

electrical resistance, and to a steady drift velocity under a given p.d.,

Superconductivity

Superconducting transition temperature: The temperature at which a material, when cooled, loses all its electrical resistance, and becomes super-conducting. Some materials (e.g. copper) never become superconducting however low the temperature.

certain special materials (high temperature

superconductors) have transition temperatures above the boiling

point of nitrogen (–196°C), and can therefore be kept below their

transition temperatures using liquid nitrogen

Resistivity

The resistance, R, of a metal wire of length L and cross-sectional area A is given by R = Ro L / A, in which Ro the resistivity, is a constant (at constant temperature) for the material of the wire.

Unit: ohm x m

recall and use

P=IV

Ohm's Law

The current flowing through a metal wire at constant temperature is proportional to the p.d. across it.

P.D

The p.d. between two points is the energy converted from electrical potential energy to some other form per coulomb of charge flowing from one point to the other. Unit: volt (V) [= JC-1].

Conduction of Energy

I = nAve

current is just number of electrons (times its charge) passing by in a given time (in seconds for amps).

say you have a volume filled with moving electrons (ignore the inner shell electrons since they stay put) if this volume is constantly moving, the current is just the total charge of this moving volume divided by the total time it takes to pass a certain surface. total charge is e*n*A*L where l is the length (this is just total volume*charge density*charge/electron) the time it takes this to move a distance L is the time for all the charges to move across some 'measuring' surface, time=distance/velocity=L/v

Current=total charge/total time=enAL/[L/v]=nAve

Current

understand that electric current is rate of flow of charge;

recall and use the equation

I=ΔQ

Δt

recall that current is measured in ampère (A), where A = Cs-1;

Units

recall that the unit of charge is the coulomb (C), and that an electron's

charge, e, is a very small fraction of a coulomb;

Energy Concepts

Power

the rate of energy transfer

Energy

Efficiency

Efficiency = Useful energy obtained x 100%

Energy input

GPE

This is energy possessed by virtue of position. (e.g. Gravitational PE = mgh). Unit: J

Kinetic

This is energy possessed by an object by virtue of its motion. Unit: J

Ek = 1/2 m(v^2)

Springs

Elastic Potential Energy

elastic potential energy is 1/2 kx^2

Spring Constant

The spring constant is the force per unit extension.

Unit: Nm-1.

Hooke's Law

The tension in a spring or wire is proportional to its extension from its natural length, provided the extension is not too great.

Work

Work done by a force is the product of the magnitude of the force and the distance moved in the direction of the force.( W.D. = Fxcos  )

Unit: J [= Nm]

Kinematics

Uniform acceleration Equations

Initial velocity u

Final velocity v

Displacement x

Acceleration a

Time taken t

v = u + at

x = (u + v)t

2

x = ut + ½ at ^2

v2 = u2 + 2ax

Definitions

Displacement Mean SpeedInstantaneous SpeedMean VelocityInstantaneous VelocityMean AccelerationInstantaneous Acceleration

The displacement of a point B from a point A is the shortest distance from A to B, together with the direction. Unit: m.

Mean speed = Total Distance/ Total time taken

Unit: ms-1.

instantaneous speed = rate of change of distance

Unit: ms-1.

Mean velocity = Total Displacement/ Total time taken

Unit: ms-1.

The velocity of a body is the rate of change of displacement.

Unit: ms-1

Mean Acceleration = Change in Velocity/ Time taken

Unit: ms-2.

The instantaneous acceleration of a body is its rate of change of velocity.

Unit: ms-2

Terminal Velocity

The terminal velocity is the constant, maximum velocity of an object when the resistive forces on it are equal and opposite to the ‘accelerating’ force (e.g. pull of gravity).

Basic Physics

Equilibrium

understand that a body is in equilibrium when the resultant force is

zero and the net moment is zero, and be able to perform simple

calculations.

Centre of Gravity

The centre of gravity is the single point within a body at which the entire weight of the body may be considered to act

Moments

The moment (or torque) of a force about a point is defined as the force  the perpendicular distance from the point to the line of action of the force,

i.e. moment = F  d.

Unit: Nm. [N.B. the unit is not J]

Principle of moments

For a system to be in equilibrium,  anticlockwise moments about a point =  clockwise moments about the same point

ΣF = ma

The mass of a body  its acceleration is equal to the vector sum of the forces acting on the body. This vector sum is called the resultant force.

A Force

A force on a body is a push or a pull acting on the body from some external body.

Unit: N

Scalar vs Vector

Vector

Has a size and a direction

E.g - Force, velocity, acceleration, displacement

Scalar

Has only a size

E.g - density, mass, energy, time, speed, distance,