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September 2008 October 2008 November 2008 December 2008 February 2009 March 2009 April 2009 May 2009 June 2009 July 2009 September 2009 October 2009 June 2010

Monday, June 7, 2010, 11:32 PM

ica

narator:
A 13 year-old Girl was practising her gymnastic at the gymnastic school and it was already late night. she was practising so hard for the tomorrow;s competition. as she was practising her jumping on the rail bar, she lost her balance.(too tired and loosing focus) unfortunately, she fell hard and fracture her arm. her mother, mrs priya quickly drive her to the nearest hospital.(her mother was there).
at the A & E department, they went to the counter and asked the nurse whom is in charge.

Nurse: how can i help you?(serving the customer with a messy hair and showing her frustrating look)
Mrs Priya: aahhhmmm..arrhhhmmm.. anak i tangan break (my daughter fracture her arm)
nurse: tsk.. you mean fracture is it? i need you to fill in the form.
Mrs. Priya: ouh ouh.. ok ok. ( her hand was shaking when she fill in the form)

Sunday, October 25, 2009, 3:39 PM

physics/chem

SUBJECT CONTENT
PHYSICS SECTION
Students are expected to have adequate mathematical skills to cope with the curriculum.
Throughout the course, attention should be paid to showing the relevance of concepts to the
students' everyday life and to the natural and man-made world.
1. Physical Quantities and Units
Content
1.1 Measurement of length, time and volume
Learning Outcomes:
Candidates should be able to:
(a) use and describe how to use rules, micrometers, vernier scales and calipers to determine
lengths
(b) use and describe how to use clocks and other devices for measuring an interval of time,
including the period of a pendulum
(c) use and describe how to use a measuring cylinder to measure a volume
2. Kinematics
Content
2.1 Speed, velocity and acceleration
2.2 Graphical analysis of motion
2.3 Free fall
Learning Outcomes:
Candidates should be able to:
(a) state what is meant by speed, velocity and acceleration
(b) recognise motion for which the acceleration is constant and calculate the acceleration
(c) recognise motion for which the acceleration is not constant
(d) plot and interpret a speed-time graph
(e) recognise from the shape of a speed-time graph when a body is
(i) at rest
(ii) moving with constant speed
(iii) moving with constant acceleration
(iv) moving with an acceleration that is not constant
(f) calculate the area under a speed-time graph to determine the distance travelled for motion
with constant speed or constant acceleration
(g) show understanding that the acceleration of free fall for a body near to the Earth is constant
(h) describe qualitatively the motion of bodies falling in a uniform gravitational field
with and without air resistance (including reference to terminal velocity)
3. Dynamics
Content
3.1 Motion
3.2 Friction
Learning Outcomes:
Candidates should be able to:
(a) describe the ways in which a force may change the motion of a body
(b) use the relation between force, mass and acceleration
(c) demonstrate an understanding of the effects of friction on the motion of a body
COMBINED SCIENCES O LEVEL 2009
5
4. Mass, Weight and Density
Content
4.1 Mass and weight
4.2 Density
Learning Outcomes:
Candidates should be able to:
(a) demonstrate an understanding that mass is a measure of the amount of substance in a
body
(b) demonstrate an understanding of inertia as the property of a mass which resists change
from its state of rest or motion
(c) describe, and use the concept of, weight as the effect of a gravitational field on a mass
(d) demonstrate understanding that two weights, and therefore masses, can be compared
using a balance
(e) use appropriate balances to measure mass and weight
(f) describe experiments to determine the density of a liquid, of a regularly shaped solid and of
an irregularly shaped solid (by the method of displacement) and make the necessary
calculations
5. Turning Effect of Forces
Content
5.1 Moments
5.2 Centre of mass
5.3 Stability
Learning Outcomes:
Candidates should be able to:
(a) describe the moment of a force in terms of its turning effect and give everyday examples
(b) perform and describe an experiment to verify the principle of moments
(c) make calculations involving the principle of moments
(d) perform and describe an experiment to determine the position of the centre of mass of a
plane lamina
(e) describe qualitatively the effect of the position of the centre of mass on the stability of
simple objects
6. Deformation
Content
6.1 Elastic deformation
Learning Outcomes:
Candidates should be able to:
(a) state that a force may produce a change in size and shape of a body
(b) plot, draw and interpret extension-load graphs for elastic solids and describe the associated
experimental procedure
(c) recognise the significance of the term limit of proportionality for an extension-load graph of
an elastic solid
(d) use proportionality of an elastic solid in simple calculations involving extension or force
required
7. Energy, Work and Power
Content
7.1 Energy conversion and conservation
7.2 Major sources of energy
7.3 Work
7.4 Power
Learning Outcomes:
Candidates should be able to:
(a) give examples of energy in different forms, its conversion and conservation, and apply the
principle of energy conservation to simple examples
(b) use the terms kinetic energy and potential energy in context
(c) calculate kinetic energy and gravitational potential energy
COMBINED SCIENCES O LEVEL 2009
6
(d) describe, and express a qualitative understanding of, processes by which energy is
converted from one form to another, including reference to
(i) chemical/fuel energy (a re-grouping of atoms)
(ii) hydroelectric generation (emphasising the mechanical energies involved)
(iii) solar energy (nuclei of atoms in the Sun)
(iv) nuclear energy
(v) geothermal energy
(vi) wind energy
(e) show a qualitative understanding of efficiency
(f) relate work done to the magnitude of a force and the distance moved and make calculations
involving F x d
(g) relate power to energy transferred and time taken, using appropriate examples and using
the equation P=E/t in simple systems
8. Transfer of Thermal Energy
Content
8.1 Conduction
8.2 Convection
8.3 Radiation
Learning Outcomes:
Candidates should be able to:
(a) describe experiments to distinguish between good and bad conductors of heat
(b) give a simple molecular account of heat transfer in solids
(c) relate convection in fluids to density changes and describe experiments to illustrate
convection
(d) describe experiments to distinguish between good and bad emitters and good and bad
absorbers of infra-red radiation
(e) identify and explain some of the everyday applications and consequences of conduction,
convection and radiation
9. Temperature
Content
9.1 Principles of thermometry
9.2 Liquid-in-glass thermometers
Learning Outcomes:
Candidates should be able to:
(a) appreciate how a physical property which varies with temperature may be used for the
measurement of temperature and state examples of such properties
(b) recognise the need for, and identify, fixed points
(c) show understanding of sensitivity and range
(d) apply a given property to the measurement of temperature
(e) describe the structure and action of liquid-in-glass thermometers (laboratory and clinical)
and of a thermocouple thermometer, showing an appreciation of its use for measuring high
temperatures and those which vary rapidly
10. Thermal Properties of Matter
Content
10.1 Thermal expansion of solids, liquids and gases
10.2 Melting, boiling and evaporation
Learning Outcomes:
Candidates should be able to:
(a) describe qualitatively the thermal expansion of solids, liquids and gases
(b) show an appreciation of the relative order of magnitude of the expansion of solids, liquids
and gases
(c) identify and explain some of the everyday applications and consequences of thermal
expansion
(d) describe melting/solidification and boiling/condensation in terms of energy transfer without a
change in temperature
(e) state the meaning of melting point and of boiling point
(f) distinguish between boiling and evaporation
COMBINED SCIENCES O LEVEL 2009
7
11. General Wave Properties
Content
11.1 Describing wave motion
11.2 Wave terms
11.3 Longitudinal and transverse waves
Learning Outcomes:
Candidates should be able to:
(a) describe what is meant by wave motion as illustrated by vibration in ropes, springs and by
experiments using a ripple tank
(b) give the meaning of speed, frequency, wavelength and amplitude and use the equation
c = f x λ
(c) distinguish between longitudinal and transverse waves and give suitable examples
12. Light
Content
12.1 Reflection of light
12.2 Refraction of light
12.3 Thin converging lens
Learning Outcomes:
Candidates should be able to:
(a) perform and describe experiments to illustrate the laws of reflection
(b) describe an experiment to find the position of an optical image formed by a plane mirror
(c) use the law i = r in reflection
(d) perform simple constructions, measurements and calculations for reflection
(e) describe and perform experiments to demonstrate refraction of light through glass blocks
(f) use the terminology for the angles i and r in refraction and describe the passage of light
through parallel-sided transparent material
(g) use the equation sin i/sin r = n (refractive index)
(h) give the meaning of refractive index
(i) describe the action of a thin converging lens on a beam of light
(j) use and understand the term focal length
(k) draw ray diagrams to illustrate the formation of real and virtual images of an object by a lens
(l) use and describe the use of a single lens as a magnifying glass
13. Electromagnetic Spectrum
Content
13.1 Properties of electromagnetic waves
Learning Outcomes:
Candidates should be able to:
(a) state that all electromagnetic waves are transverse waves that travel with the same high
speed in vacuo and state the magnitude of this speed
(b) describe the main components of the electromagnetic spectrum
14. Sound
Content
14.1 Sound waves
14.2 Speed of sound
Learning Outcomes:
Candidates should be able to:
(a) describe the production of sound by vibrating sources
(b) describe the longitudinal nature of sound waves and describe compression and rarefaction
(c) state the approximate range of audible frequencies
(d) show understanding that a medium is required in order to transmit sound waves
(e) describe an experiment to determine the speed of sound in air and make the necessary
calculation
(f) state the order of magnitude of the speed of sound in air, liquids and solids
COMBINED SCIENCES O LEVEL 2009
8
15. Static Electricity
Content
15.1 Principles of electrostatics
Learning Outcomes:
Candidates should be able to:
(a) show understanding that there are positive and negative charges and that charge is measured
in coulombs
(b) show understanding that unlike charges attract and that like charges repel
16. Current Electricity
Content
16.1 Electric current
16.2 Electromotive force
16.3 Potential difference
16.4 Resistance
Learning Outcomes:
Candidates should be able to:
(a) show understanding that a current is a rate of flow of charge and is measured in amperes
(b) use the equation I = Q/t
(c) use and describe the use of an ammeter
(d) use the concept that the e.m.f. is measured by-
the energy dissipated by a source in driving
charge round the complete circuit
(e) show appreciation that the volt is given by J/C
(f) show understanding that the potential difference across a circuit component is measured in
volts
(g) use and describe the use of a voltmeter
(h) state that resistance = p.d./current and use the equation R = V/I
(i) describe an experiment to determine resistance using a voltmeter and an ammeter and make
the necessary calculation
(j) use quantitatively the relationship between resistance and the length and the cross-sectional
area of a wire
(k) sketch and interpret the V/I characteristic graphs for metallic (ohmic) and non-ohmic
conductors
(l) appreciate the limitations of Ohm's Law
17. d.c. Circuits
Content
17.1 Current and potential difference in circuits
17.2 Series and parallel circuits
Learning Outcomes:
Candidates should be able to:
(a) draw and interpret circuit diagrams containing sources, switches, resistors (fixed and
variable), ammeters, voltmeters, magnetising coils, bells, fuses and relays
(b) show understanding that the current at every point in a series circuit is the same
(c) use the fact that the sum of the p.d.s in a series circuit is equal to the p.d. across the whole
circuit
(d) calculate the combined resistance of two or more resistors in series
(e) use the fact that the current from the source is the sum of the currents in the separate
branches of a parallel circuit, the current from the source being larger than the current in each
branch
(f) calculate the effective resistance of two resistors in parallel
COMBINED SCIENCES O LEVEL 2009
9
18. Practical Electricity
Content
18.1 Electric power and energy
18.2 Dangers of electricity
18.3 Safe use of electricity in the home
Learning Outcomes:
Candidates should be able to:
(a) describe the use of electricity in heating, lighting (including lamps in parallel) and motors
(b) use the equations P = VI and E = VIt
(c) calculate the cost of using electrical appliances
(d) state the hazards of
(i) damaged insulation
(ii) overheating of cables
(iii) damp conditions
(e) show understanding of the use of fuses and fuse ratings
(f) explain the need for earthing metal cases and for double insulation
(g) give the meaning of the terms live, neutral and earth
(h) wire, and describe how to wire, a mains plug
(i) give the reasons for switches and fuses in live leads
19. Magnetism
Content
19.1 Laws of magnetism
19.2 Magnetic properties of matter
Learning Outcomes:
Candidates should be able to:
(a) state the properties of magnets
(b) give an account of induced magnetism
(c) distinguish between magnetic and non-magnetic materials
(d) describe methods of magnetisation and of demagnetisation
(e) describe the use of a plotting compass to plot the field lines of magnetic field (Earth's field
excluded)
(f) distinguish between the magnetic properties of iron and steel
(g) distinguish between the design and use of permanent magnets and electromagnets
20. Electromagnetic Induction
Content
20.1 Principles of electromagnetic induction
20.2 The a.c. generator
20.3 The transformer
Learning Outcomes:
Candidates should be able to:
(a) describe an experiment which shows that a changing magnetic field can induce an e.m.f. in a
circuit
(b) state the factors affecting the magnitude of the induced e.m.f
(c) show understanding that the direction of the induced e.m.f. opposes the change producing it
(d) describe a simple form of generator (e.g. rotating coil or rotating magnet) and the use of slip
rings
(e) sketch a graph of voltage output against time for a simple a.c. generator
(f) describe the structure and principle of operation of a basic iron-cored transformer as used for
voltage transformations
(g) use the equations (Vp/Vs) = (Np/Ns) and VpIp = VS IS (for 100% efficiency)
COMBINED SCIENCES O LEVEL 2009
10
21. The Nuclear Atom
Content
21.1 Atomic model
21.2 Composition of a nucleus
21.3 Proton number and nucleon number
21.4 Nuclide notation
Learning Outcomes:
Candidates should be able to:
(a) describe the structure of an atom in terms of a nucleus and electrons
(b) describe the composition of the nucleus in terms of protons and neutrons
(c) use the term nucleon number, A
(d) use the term proton number, Z
(e) use the term nuclide and use the nuclide notation x
A
Z
22. Radioactivity
Content
22.1 Detection of radioactivity
22.2 Characteristics of the three types of emission
22.3 Nuclear reactions
22.4 Half-life
22.5 Safety precautions
Learning Outcomes:
Candidates should be able to:
(a) describe the detection of alpha-particles, beta-particles and gamma-rays
(b) show understanding that radioactive emissions occur randomly over space and time
(c) state, for radioactive emissions,
(i) their nature
(ii) their relative ionising effects
(iii) their relative penetrating powers
(d) show understanding of the meaning of radioactive decay, using equations (involving symbols)
to represent changes in the composition of the nucleus when particles are emitted
(e) use the term half-life in simple calculations which might involve information in tables or in
decay curves
(f) describe how radioactive materials are handled, used, stored and disposed of, in a safe way
COMBINED SCIENCES O LEVEL 2009
11
CHEMISTRY SECTION
It is important that, throughout the course, attention should be drawn to:
(i) the finite life of the world's resources and hence the need for recycling and conservation;
(ii) some economic considerations in the chemical industry, such as the availability and cost of
raw materials and energy;
(iii) the importance of chemicals in industry and in everyday life.
1. Experimental Chemistry
Content
1.1 Experimental design
1.2 Methods of purification and analysis
1.3 Identification of ions and gases
Learning Outcomes:
Candidates should be able to:
(a) name and use appropriate apparatus for the measurement of time, temperature, mass and
volume, including burettes, pipettes and measuring cylinders
(b) design arrangements of apparatus, given information about the substances involved
(c) describe and use methods of purification by the use of a suitable solvent, filtration,
crystallisation and distillation (including description but not use of fractional distillation)
(Refer to the fractional distillation of
(i) crude oil (petroleum) (topic 20.2(c))
(ii) fermented liquor (topic 23.1(a)).)
(d) suggest suitable purification techniques, given information about the substances involved
(e) describe and use paper chromatography and interpret chromatograms
(f) identify substances and test their purity by melting point and boiling point determination and
by paper chromatography
(g) identify
nitrate (by reduction with aluminium)
carbonate (by reaction with acid and then limewater)
chloride and iodide (by reaction with acidified silver nitrate or with acidified lead(II) nitrate)
sulfate (by reaction with acidified barium nitrate)
(h) identify
aluminium, calcium, copper(II), iron(II), iron(III), zinc and ammonium (by using aqueous
sodium hydroxide and aqueous ammonia, as appropriate). (Formulae of complex ions are
not required)
(i) identify
hydrogen (by lighted splint)
oxygen (by glowing splint)
carbon dioxide (by limewater)
chlorine (using indicator paper)
ammonia (using indicator paper)
2. Kinetic Particle Theory
Learning Outcomes:
Candidates should be able to:
(a) describe the states of matter and explain their inter-conversion in terms of the kinetic particle
theory
3. Atomic Structure
Content
3.1 Atomic structure
3.2 Isotopes
Learning Outcomes:
Candidates should be able to:
(a) state the relative charge and approximate relative mass of a proton, a neutron and an electron
(b) define proton number and nucleon number
(c) use and interpret such symbols as 12C
6
COMBINED SCIENCES O LEVEL 2009
12
(d) use proton number and the simple structure of atoms to explain the Periodic Table, with
special reference to the elements of proton number 1 to 20
(e) define isotopes
(f) describe the build-up of electrons in ‘shells' and understand the significance of outer electrons
and the noble gas electronic structures. (The ideas of the distribution of electrons in s- and
p-orbitals and in d-block elements are not required. Note that a copy of the Periodic Table
will be available in the examination.)
4. Structure and Properties of Materials
Learning Outcomes:
Candidates should be able to:
(a) describe the differences between elements, compounds and mixtures, and between metals
and non-metals
(b) describe alloys, such as brass, as a mixture of a metal with other elements
5. Ionic Bonding
Content
5.1 Ion formation
5.2 Ionic bond formation
Learning Outcomes:
Candidates should be able to:
(a) describe the formation of ions by electron loss or gain
(b) describe the formation of ionic bonds between metallic and non-metallic elements (e.g. in
NaCl and CaCl2)
6. Covalent Bonding
Content
6.1 Covalent bond formation
6.2 Physical properties of covalent compounds
Learning Outcomes:
Candidates should be able to:
(a) describe the formation of covalent bonds as the sharing of pairs of electrons leading to the
noble gas configuration (e.g. H2, Cl2, HCl, H2O, CH4 and CO2)
(b) deduce the electron arrangement in other covalent molecules
(c) construct ‘dot and cross' diagrams to show the outer electrons in covalent molecules
(d) describe the differences in volatility, solubility and electrical conductivity between ionic and
covalent compounds
7. Formulae, Stoichiometry and the Mole Concept
Content
7.1 Formulae
7.2 Equations
7.3 Stoichiometric calculations
Learning Outcomes:
Candidates should be able to:
(a) state the symbols of the elements and the formulae of the compounds mentioned in the
syllabus
(b) deduce the formula of a simple compound from the relative numbers of atoms present and
vice versa
(c) determine the formula of an ionic compound from the charges on the ions present and vice
versa
(d) construct equations with state symbols, including ionic equations
(e) deduce, from experimental results, the identity of the reactants and the products and the
balanced chemical equation for a chemical reaction
(f) define relative atomic mass, Ar
(g) define relative molecular mass, Mr
(h) use the mole and the Avogadro constant
(i) use molar gas volume, taken as 24 dm
3
at room temperature and pressure
COMBINED SCIENCES O LEVEL 2009
13
(j) calculate the stoichiometric reacting masses and volumes of gases. (Questions on the gas
laws and the conversion of gaseous volumes to different temperatures and pressures will not
be set.)
(k) use solution concentrations expressed in g/dm
3
and mol/dm
3
. (Calculations based on reacting
volumes of solution (e.g. titrimetric data) will not be set.)
8. Energy from Chemicals
Content
8.1 Exothermic and endothermic reactions
8.2 Photosynthesis
Learning Outcomes:
Candidates should be able to:
(a) describe the meaning of exothermic and endothermic reactions
(b) describe bond breaking as an endothermic process and bond forming as an exothermic
process
(c) describe the use of silver salts in photography as an endothermic process involving the
reduction of silver ions to silver
(d) describe photosynthesis as the reaction between carbon dioxide and water in the presence of
chlorophyll and using sunlight (energy) to produce glucose
9. Chemical Reactions
Content
9.1 Rate of reaction
9.2 Redox
Learning Outcomes:
Candidates should be able to:
(a) describe the effect of concentration, pressure, particle size, catalysts (including enzymes) and
temperature on the rates of reactions
(b) describe how the above factors are used to explain the danger of explosive combustion with
fine powders (e.g. in flour mills) and combustible gases (e.g. in mines)
(c) interpret data obtained from experiments concerned with rate of reaction
(d) define oxidation and reduction in terms of oxygen/hydrogen gain/loss
(e) define redox in terms of electron transfer
10. The Chemistry and Uses of Acids, Bases and Salts
Content
10.1 Characteristic properties of acids and bases
10.2 pH
10.3 Types of oxides
10.4 Preparation of salts
Learning Outcomes:
Candidates should be able to:
(a) describe the meanings of the terms acid and alkali in terms of the ions they contain or
produce in aqueous solution
(b) describe the characteristic properties of acids as in their reactions with metals, bases,
carbonates and their effects on indicator paper
(c) describe the characteristic properties of bases as in their reactions with acids and with
ammonium salts and their effects on indicator paper
(d) describe neutrality and relative acidity and alkalinity in terms of pH (whole numbers only),
measured using Universal Indicator paper
(e) describe and explain the importance of controlling acidity in soil
(f) classify oxides as either acidic, basic, or amphoteric related to metallic/non-metallic character
(g) describe the preparation, separation and purification of salts as examples of some of the
techniques specified in topic 1.2(c): methods of preparing salts to illustrate the practical
techniques should include the action of acids with insoluble bases, and acids with insoluble
carbonates
(h) suggest a method of preparing a given salt from suitable starting materials, given appropriate
information
COMBINED SCIENCES O LEVEL 2009
14
11. The Periodic Table
Content
11.1 Periodic trends
11.2 Group properties
Learning Outcomes:
Candidates should be able to:
(a) describe the Periodic Table as a method of classifying elements and describe its use in
predicting properties of elements
(b) describe the change from metallic to non-metallic character across a period
(c) describe the relationship between group number, number of outer electrons and
metallic/non-metallic character
(d) describe lithium, sodium and potassium in Group I (the alkali metals) as a collection of
relatively soft metals showing a trend in melting point and in reaction with water and with
chlorine
(e) predict the properties of other elements in Group I, given data, where appropriate
(f) describe chlorine, bromine and iodine in Group VII (the halogens) as a collection of diatomic
non-metals showing a trend in colour, state, and in their displacement reactions with other
halide ions
(g) predict the properties of other elements in Group VII, given data, where appropriate
(h) identify trends in other groups, given information about the elements concerned
(i) describe the noble gases as being unreactive
(j) describe the uses of the noble gases in providing an inert atmosphere (e.g. argon in lamps
and helium for filling balloons)
12. Properties of Metals
Content
12.1 Physical properties
12.2 Alloys
Learning Outcomes:
Candidates should be able to:
(a) describe the general physical properties of metals
(b) explain why metals are often used in the form of alloys
(c) identify representations of metals and alloys from diagrams of structures
13. Reactivity Series
Content
13.1 Order of reactivity
Learning Outcomes:
Candidates should be able to:
(a) place in order of reactivity calcium, copper, (hydrogen), iron, magnesium, potassium,
sodium and zinc by reference to the reactions, if any, of the metals with water (or steam)
and dilute hydrochloric acid
(b) account for the apparent unreactivity of aluminium in terms of the presence of an oxide
layer which adheres to the metal
(c) deduce an order of reactivity from a given set of experimental results
14. Extraction and Uses of Metals
Content
14.1 Metal ores
14.2 The blast furnace
14.3 Iron and steel
14.4 Aluminium
14.5 Zinc
14.6 Copper
Learning Outcomes:
Candidates should be able to:
(a) describe the ease in obtaining metals from their ores by relating the elements to the
reactivity series
COMBINED SCIENCES O LEVEL 2009
15
(b) describe the essential reactions in the extraction of iron from haematite
(c) describe the idea of changing the properties of iron by the controlled use of additives to form
alloys called steels
(d) state the uses of mild steel (car bodies and machinery) and stainless steel (chemical plant
and cutlery)
(e) state the uses of aluminium (e.g. in the manufacture of aircraft parts because of its strength
and low density and in food containers because of its resistance to corrosion)
(f) state the uses of zinc for galvanising and for making brass (with copper)
(g) state the uses of copper related to its properties (e.g. electrical wiring)
15. Atmosphere and Environment
Content
15.1 Air
15.2 Corrosion
15.3 Pollution
15.4 Water
Learning Outcomes:
Candidates should be able to:
(a) describe the volume composition of clean air in terms of 79% nitrogen, 20% oxygen, with the
remainder being noble gases (with argon as the main constituent) carbon dioxide and variable
amounts of water vapour
(b) name the uses of oxygen in making steel, oxygen tents in hospitals, and with acetylene
(a hydrocarbon) in welding
(c) describe, in simple terms, the ideas of respiration, combustion and rusting
(d) describe methods of rust prevention by painting and other coatings (including galvanising)
(e) name common pollutants of air (carbon monoxide, sulfur dioxide, oxides of nitrogen and lead
compounds)
(f) state the source of each of these pollutants
(i) carbon monoxide from the incomplete combustion of carbon-containing substances
(ii) sulfur dioxide from the combustion of fossil fuels which contain sulfur compounds
(leading to acid rain)
(iii) oxides of nitrogen and lead compounds from car exhausts
(g) state the adverse effect of acidic pollutants on buildings and plants, and of carbon monoxide
and lead compounds on health
(h) describe, in outline, the purification of the water supply in terms of filtration and chlorination
(i) state some of the uses of water in industry and in the home
16. Hydrogen
Learning Outcomes:
Candidates should be able to:
(a) describe the formation of hydrogen as a product of the reaction between
(i) reactive metals and water
(ii) metals and acids
(b) name the uses of hydrogen in the manufacture of ammonia and margarine, and as a fuel in
rockets
17. Nitrogen
Content
17.1 Ammonia and the Haber process
17.2 Fertiliser manufacture
Learning Outcomes:
Candidates should be able to:
(a) describe the need for nitrogen, phosphorus and potassium compounds in plant life
(b) name the use of nitrogen in the manufacture of ammonia
(c) describe the essential conditions for the manufacture of ammonia by the Haber process
(d) name the uses of ammonia in the manufacture of fertilisers such as ammonium sulfate and
nitrate
COMBINED SCIENCES O LEVEL 2009
16
18. Carbon and Carbonates
Content
18.1 Allotropes of carbon
18.2 Manufacture and uses of lime
18.3 Uses of calcium carbonate
Learning Outcomes:
Candidates should be able to:
(a) name the allotropes of carbon as graphite and diamond
(b) relate their structures to the use of graphite as a lubricant and diamond in cutting
(c) describe the manufacture of lime (calcium oxide) from calcium carbonate (limestone) in terms
of the chemical reaction involved
(d) state some uses of lime and slaked lime as in treating acidic soil and neutralising acidic
industrial waste products
(e) state the uses of calcium carbonate in the manufacture of iron, glass and cement
19. Organic Chemistry
Content
19.1 Names of compounds
19.2 Structures of compounds
19.3 Homologous series
Learning Outcomes:
Candidates should be able to:
(a) name, and draw the structure of, the unbranched alkanes, alkenes (not cis-trans), alcohols
and acids containing up to four carbon atoms per molecule and the products of the reactions
stated in topics 21 to 24.
(b) state the type of compound present given a chemical name, ending in -ane, -ene, -ol, or -oic
acid, or given a molecular structure
(c) describe the general characteristics of a homologous series
20. Fuels
Content
20.1 Natural gas and petroleum as energy sources
20.2 Fractional distillation
20.3 Uses of fractions
Learning Outcomes:
Candidates should be able to:
(a) name natural gas and petroleum as sources of fuels
(b) name methane as the main constituent of natural gas
(c) describe petroleum as a mixture of hydrocarbons and its separation into useful fractions by
fractional distillation
(d) name the uses of petroleum fractions: petrol (gasoline), as fuel in cars; paraffin (kerosene), for
oil stoves and aircraft fuel; diesel, for fuel in diesel engines; oils, for lubricants and making
waxes and polishes; bitumen, for making roads
21. Alkanes
Content
21.1 Properties of alkanes
Learning Outcomes:
Candidates should be able to:
(a) describe the properties of alkanes (exemplified by methane) as being generally unreactive,
except in terms of burning
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22. Alkenes
Content
22.1 Cracking
22.2 Unsaturated hydrocarbons
22.3 Polymerisation
Learning Outcomes:
Candidates should be able to:
(a) describe the manufacture of alkenes and of hydrogen by cracking
(b) describe the properties of alkenes in terms of burning and addition reactions with hydrogen
and steam
(c) distinguish between saturated and unsaturated hydrocarbons
(i) from molecular structures
(ii) by using aqueous bromine
(d) describe the formation of poly(ethene) as an example of addition polymerisation of monomer
units
(e) name some uses of poly(ethene) as a typical plastic (e.g. plastic bags)
23. Alcohols
Content
23.1 Formation of ethanol
23.2 Combustion and oxidation
23.3 Uses of ethanol
Learning Outcomes:
Candidates should be able to:
(a) describe the formation of ethanol by fermentation and by the catalytic addition of steam to
ethene
(b) describe the properties of ethanol in terms of combustion and of oxidation
(c) name the uses of ethanol (e.g. as a solvent, as a fuel and as a constituent of wine and beer)
24. Acids
Content
24.1 Ethanoic acid
Learning Outcomes:
Candidates should be able to:
(a) describe the formation of ethanoic acid as the oxidation of ethanol by the action of
atmospheric oxygen
(b) describe the reaction of ethanoic acid with ethanol to give an ester (ethyl ethanoate)
25. Macromolecules
Content
25.1 Monomers and polymers
25.2 Man-made fibres
25.3 Pollution
25.4 Natural macromolecules
Learning Outcomes:
Candidates should be able to:
(a) describe macromolecules in terms of large molecules built up from small units, different
macromolecules having different units and/or different linkages
(b) deduce the structure of the polymer product from a given alkene and vice versa
(c) describe the formation of nylon (a polyamide) and Terylene (a polyester) by condensation
polymerisation, the structure of nylon represented as
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and the structure of Terylene as
(Details of manufacture and mechanisms of these polymerisations are not required.)
(d) name some typical uses of man-made fibres such as nylon and Terylene (e.g. clothing)
(e) describe the pollution problems caused by non-biodegradable plastics
(f) name proteins, fats and carbohydrates as the main constituents of foods
(g) describe proteins as possessing the same (amide) linkages as nylon but with different units
(h) describe the hydrolysis of proteins to amino acids (structures and names not required)
(i) describe fats as esters possessing the same linkages as Terylene but with different units
(j) describe soap as a product of the hydrolysis of fats
(k) describe the carbohydrate starch as a macromolecule represented as
being formed by the condensation polymerisation of smaller carbohydrate units called sugars,
represented as
(l) describe the acid hydrolysis of carbohydrates such as starch to give simple sugars
(m) describe the fermentation of simple sugars to produce ethanol (and carbon dioxide) and its
importance to brewing and wine-making (Candidates will not be expected to give the
molecular formulae of sugars.)