Any help,hints,tips for studing Paper2 Physics

[Mohamed Ghareeb]

Can anyone plz post studing notes for physics or any thing that helps for studing physics

 

[Mohamed Ghareeb]

By : areebaization
GENERAL RULES FOR DOING PHYSICS EXAM PAPERS

1. Read all of the parts of a question before answering it.
2. Pay attention to the number of marks on offer (eg for 3 marks, you must say at least three things).
3. 1 mark questions saying 'State' or 'Recall' require short, simple answers.
4. Learn all definitions and formulas word-for-word.
5. Give enough detail in your answers. State the obvious eg a force is a push or a pull.
6. Show that you can use Physics vocabulary whenever you can.
7. Note the action words in the question (and answer accordingly): State; Explain; Complete; Describe; Use (the graph); Suggest; Evaluate
8. Part questions are usually on a single topic eg the answer to part (a) feeds into (b).
9. Stay aware of the time (1 mark per minute). If you get stuck, move on and return if you have time at the end.
10. Don't be afraid to physically act out the electromagnetism hand rules in the exam.
11. Never leave a question blank. If nothing else, write down relevant formulas or definitions.
12. As you finish a question, quickly re-read your answer to make sure it makes sense.
13. Don't leave early. Check and re-check your answers.
14. After the exam, don't waste time discussing your answers. Look ahead to the next paper.

Calculations: always show your working: there are many marks for this even if the answer is wrong.
These are the stages: Formula - Rearrange - Information - Substitute - Calculate - Answer - Unit
Underline: Show your final answer clearly highlighting or underlining.
Significant figures: There are marks for getting this right. Every answer should be given to the correct number of sf (the same sf as the numbers given in the question). eg 5.2*9.8 = 51 (2 sf). It is a good idea to state the sf to show that you know about it.
Equations: if you are asked to write one down, use words not just symbols.
Rounding: if you are asked to show a quantity is 'approximately equal to' a given value, show the rounding step: eg 8.7A (rounded to 9A).
Prefixes: convert units such as kN (kilo-newtons) and mA (milli-amperes) by multiplying or dividing by 1000.
Assumptions: many formulas can only be used with particular assumptions eg a fixed mass of gas or temperature is kept constant etc.
Common-sense: consider whether numerical answers make sense eg a person of mass 5.0 or 500 kg is not likely.

Graphs are often marked for the following features:

• Size (more than 50% of the graph paper)
• Axis (label quantity and unit; numbers evenly spaced)
• Plotting (usually 2 marks for accuracy of points). Mark points with small dots.
• Line of best fit (don't join the dots; don't force it through the origin; only draw a straight line if it looks straight; and if it is straight, use a ruler).
• Anomalies can be identified as points far from the line of best fit.

Calculating gradient: actually draw the rise-run triangle (make it large). Use measurements of the triangle for the calculation, NOT values from the coordinates. A gradient has a unit.

Proportional quantities: state that a relationship is proportional or linear if A = kB, but not if A = kB + C or if A = kB2. Example: "kinetic energy increases with velocity, but the KE-v graph is non-linear (KE is prop. to v squared)".

Questions about experimental skills
Method: describe all the steps in the right order.
Quantities: give the number and unit (in a table, unit is in the heading).
Repeat readings. The reasons for this are:

• make the result more reliable (gives the same result each time);
• to find a mean value;
• to spot anomalies.

Scales: read them with your eye level with the reading (avoid parallax error).
Zero error: make sure the ruler or meter starts at zero.
Apparatus: learn the names eg measuring cylinder; ray box; ticker-timer; air-track; stand and clamp etc

Examples of Safety precautions
Weights must not fall on toes.
Hot objects must be carried with insulating handles.
Fasten clamp stands to the bench.
Protect eyes from stretched wires; liquids; flying objects.
Lab-coats protect skin and clothes from chemicals and hot materials.
Electricity supplies should be low voltage.
Mop up water if it is spilled.
Radioactive materials must be stored inside lead containers and handled with forceps.
Avoid damage to apparatus (don't exceed limits for elasticity/ current/ temperature/ force etc).

Variables
Independent variable is the one which you choose to change. You can make decisions about the range and number of values. It should be the leftmost column in a table and the horizontal axis on a graph.
Dependent variable is the one which you measure. This is the variable you average when there are repetitions.
Controlled variables are the ones you keep constant to ensure a fair test.

Evaluating conclusions
Precision - this means how many significant figures are used in a measurement. (eg 0.25s has a precision of 0.01s). It can be useful to estimate the precision as a percentage of the reading (eg here it is 4%)
Accuracy - this means how close to the true value the result is.
Reliability - whether a result can be repeated.

Improvements
Reaction time - this can adversely affect measurements of time (add 0.1s). To reduce it, use electronic timing or measurelonger times.
For oscillations, measure several and divide to find time period which will reduce effect of reaction time.
To improve precision you can use a scale with smaller divisions.
Repeat measurement (consider if it is appropriate in each situation).
Does the question require improvement in the method (same apparatus used differently) or equipment (same method, different instruments)?

Explanations
When explaining, give reasons.
Use labelled diagrams if it helps you to explain something.
Mention all of the relevant physics vocabulary.
When explaining a quantity, consider the relevant formulas: eg pressure depends force exerted on an area.
In questions about kinetic theory, talk about particles.

Diagrams
Use a ruler and pencil. Don't rush. Draw large and clearly.
For magnetic fields, the lines must show the direction, form complete loops and NEVER cross nor touch.
In light diagrams, draw the normal and arrows on the rays. Light travels into the eye.
In electric circuits, show conventional current.
By : areebaization
Post your tips below

 

[areebaization]

^areebaization here
I found some more tips for p2!
These are the papers that test your knowledge and understanding of Physics theory and the
ability to apply your knowledge to situations described on the paper. The following includes
some tips on how to read the questions and advice on particular items in the syllabus that
often seem to be poorly understood or applied. (This does not mean that other parts of the
syllabus require any less revision of course!).
Reading the questions:
• It is very easy when presented with a diagram question to look at the diagram and then
try to answer the question. You must read and understand the introductory sentences
above the diagram first before trying to answer the question. There may be a part of the
question near the end which requires you to use a piece of information that is included in
the introductory sentences in your answer.
• Be careful how you answer your questions. An explanation of some Physics (even if
correct) that does not answer the question set does not score marks.
• If there are three marks available for a calculation, two of the three marks are for showing
your working.
• If a question states ‘accurately mark’ or ‘accurately draw', the examiners expect points
(e.g. a centre of gravity) to be carefully positioned and lines to be drawn with care using a ruler. In the case of ray diagrams it is expected that rays drawn should pass at least
within 1 mm of the relevant point (e.g. principal focus).
• When reading the questions, decide which area of Physics you are being asked about.
Do not just look at a few words as you may then misunderstand the question. For
example a question that mentions heat radiation is not about radioactivity (just because
the word 'radiation' is seen). If you are asked for a convection current diagram do not
draw a circuit just because the word ‘current’ is in the question!
Answering the questions:
• You must understand the turning effect of a force and that it is called the moment of the
force.
• You must be clear about the names given to types of energy and use them appropriately.
• You should know that a substance melts and freezes at the same temperature and also
understand the ice and steam points as used in the calibration of thermometers.
• You should know the circuit symbols required for use in describing electrical circuits. The
symbol for a fuse is often not known and the symbols for a thermistor and a variable
resistor are commonly confused with each other.
• You must know how to connect a voltmeter in parallel with the component across which
you are measuring the potential difference.
• You must have a clear understanding of electromagnetic induction. For example, you
must know that when a magnet is moved in or out of a solenoid that is part of a circuit, a
current will be induced. It is the movement of the magnet in the solenoid that causes the
current as its magnetic field lines cut the coil.
• You must understand and be able to explain the concept of terminal velocity.
• You must understand the difference between mass and weight.
• You must be confident in drawing diagrams showing wavefronts as well as those showing
rays.
• You must understand basic radioactivity. You should know about the characteristics of
the three types of emission (alpha, beta and gamma), half-life and safety precautions.
The difference between nuclear fission and nuclear fusion must also be understood.

 

[Mohamed Ghareeb]

Thank u so much areebaization !
You're so helpful
Thnx again

 

[Mohamed Ghareeb]

Rules
Average speed = total distance travelled / total time taken.
v = d / t
v = speed in m/s
t = time taken in s
d = distance
—————–
Acceleration = change in velocity/time taken.
a = (v – u)/ t
Or by using this formula
v = u + a t
Where
a = acceleration in m/s2
u = initial velocity in m/s
v = final velocity in m/s
t = time taken in s
————-
F = ma
F = force N
m = mass kg
a = acceleration m/s2
———-
Weight = mg
weight is a force of gravity acting on a body N
m = mass kg
g = acceleration due to gravity in m/s2
Force has unit of N or kg.m/s2
——-
density = mass / volume
density kg/m3
(or according to the unit used)
————
Moment about a point = Force × Perpendicular distance from the pivot
————–
Load = constant x extension
F = k.X
————-
Pressure = force / area
pressure in Pa or N/m2
force in newton
area in meter squared
—————–
in Manometer
Actual pressure = atmospheric pressure + excess pressure (difference)
————–
K.E. = 1/2 mv2
P.E. =m g h
—————
Work (energy) = F x distance
work in J
Power = Work (energy) / time
power in W
———<a
gas law


Image via Wikipedia

as volume decreases pressure increases (inversely proportional)
but
and the other two relationships are directly proportional
as temp increases volume increases (expansion)
as temp increases pressure increases
————
Revise …………………units
length m
mass kg
speed m/s
acceleration m/s2
force , weight N
work J
energy J
(any form of energy as heat, PE, KE, others) J
Power W
Revise…………………. tools used to measure
time
mass
weight
length
measuring time differences
measuring irregular volumes
calculating
- density
- speed
- acceleration