JAMB Syllabus For Physics 2023/2024 (Download PDF)
This syllabus is aimed at guiding candidates who will be taking the JAMB Physics examination, and it provides a detailed outline of the topics and concepts they will be tested on.
The JAMB Physics syllabus is designed to cover all aspects of the subject, from fundamental principles to more advanced topics. Candidates are advised to study the syllabus carefully and use it as a guide for their preparation for the JAMB Physics examination.
The JAMB (Joint Admissions and Matriculation Board) syllabus for Physics 2023/2024 is a comprehensive outline of the topics that candidates should cover when preparing for the Physics section of the JAMB UTME (Unified Tertiary Matriculation Examination) for the academic session 2023/2024. The syllabus is an essential resource for students who are planning to write the JAMB Physics examination, as it provides a detailed breakdown of the topics that will be covered in the exam.
The JAMB Physics syllabus for the 2023/2024 academic session is divided into six sections, namely: Mechanics, Waves and Oscillations, Modern Physics, Electricity and Magnetism, Heat and Thermodynamics, and Optics. Each of these sections contains several sub-topics that candidates are expected to study in preparation for the JAMB Physics examination.
The Mechanics section covers topics such as measurement, motion in one and two dimensions, Newton’s laws of motion, work, energy and power, impulse and momentum, and rotational motion. The Waves and Oscillations section covers topics such as types of waves, wave properties, superposition of waves, wave interference, and resonance.
The Modern Physics section covers topics such as the dual nature of matter and radiation, atomic structure, nuclear physics, and elementary particle physics. The Electricity and Magnetism section covers topics such as electric fields, capacitance, electric current, magnetic fields, electromagnetic induction, and AC circuits.
The Heat and Thermodynamics section covers topics such as temperature and heat transfer, laws of thermodynamics, and thermodynamic processes. The Optics section covers topics such as reflection and refraction, lenses and mirrors, diffraction and interference, and polarization.
the JAMB Physics syllabus for the 2023/2024 academic session provides a comprehensive guide for candidates preparing for the JAMB UTME Physics examination. It is important that candidates study the syllabus thoroughly and cover all the necessary topics to increase their chances of success in the exam.
Jamb Physics Syllabus 2023/2024
The aim of the JAMB Physics Syllabus is to provide a comprehensive and detailed outline of the topics and concepts that candidates are expected to cover in preparation for the Physics section of the JAMB examination. It serves as a guide to help candidates and teachers understand the objectives of the examination, as well as the level of knowledge and understanding required to succeed.
The syllabus is designed to cover all the necessary topics in Physics and to ensure that candidates have a broad and deep understanding of the subject. It also includes information on the format of the examination, including the types of questions that may be asked, the duration of the examination, and the marking scheme used by JAMB. By providing a clear and detailed syllabus, JAMB aims to ensure that candidates are adequately prepared to succeed in the Physics section of the JAMB examination.
- Maintain students’ enthusiasm for physics;
- Cultivate an approach toward physics that values accuracy, precision, and objectivity;
- Understand and interpret physical phenomena, laws, definitions, concepts, and other theories;
- Exhibit proficiency in solving physics problems using appropriate theories and concepts.
Jamb Syllabus for Physics 2023/2024
Measurement & Unit
(a) Length area and volume: Metre rule, Venier calipers Micrometer Screw-guage
(i) unit of mass
(ii) use of simple beam balance
(i) unit of time
(ii) time-measuring devices
(d) Fundamental physical quantities
(e) Derived physical quantities and their units
(i) Combinations of fundamental quantities and determination of their units
(i) definition of dimensions
(ii) simple examples.
(g) Limitations of experimental measurements
(i) accuracy of measuring instruments
(ii) simple estimation of errors.
(iii) significant figures.
(iv) standard form.
Scalars and Vectors
(i) definition of scalar and vector quantities
(ii) examples of scalar and vector quantities
(iii) relative velocity
(iv) resolution of vectors into two perpendicular directions including graphical methods of solution.
(a) Types of motion: translational, oscillatory, rotational, spin, and random
(b) linear motion
(i) speed, velocity, and acceleration
(ii) equations of uniformly accelerated motion
(iii) motion under gravity
(iv) distance-time graph and velocity-time graph
(v) instantaneous velocity and acceleration.
(i) calculation of range, maximum height, and time of the fight
(ii) applications of projectile motion
(d) Newton’s laws of motion:
(i) inertia, mass, and force
(ii) relationship between mass and acceleration
(iii) impulse and momentum
(iv) conservation of linear momentum
(Coefficient of restitution not necessary)
(e) Motion in a circle:
(i) angular velocity and angular acceleration
(ii) centripetal and centrifugal forces.
(f) Simple Harmonic Motion (S.H.M):
(i) definition and explanation of simple harmonic motion
(ii) examples of systems that execute S.H.M
(iii) period frequency and amplitude of S.H.M
(iv) velocity and acceleration of S.H.M
(v) energy change in S.H.M
(i) Newton’s law of universal gravitation
(ii) gravitational potential
(iii) conservative and non-conservative fields
(iv) acceleration due to gravity [g=GM / R]
(iv) variation of g on the earth’s surface
(v) distinction between mass and weight
(vi) escape velocity
(vii) parking orbit and weightlessness
Equilibrium of Forces
(a) equilibrium of particles:
(i) equilibrium of coplanar forces
(ii) triangles and polygon of forces
(iii) Lami’s theorem
(b) principles of moments
(i) moment of a force
(ii) simple treatment and moment of a couple (torque)
(c) conditions for equilibrium of rigid bodies under the action of parallel and non-parallel forces:
(i) resolution and composition of forces in two perpendicular directions,
(ii) resultant and equilibrant
(d) center of gravity and stability
(i) stable, unstable, and neutral equilibrium
Work Energy and Power
(i) definition of work, energy and power
(ii) forms of energy
(iii) conservation of energy
(iv) qualitative treatment between different forms of energy
(v) interpretation of area under the force-distance curve
(i) static and dynamic friction
(ii) coefficient of limiting friction and its determination.
(iii) advantages and disadvantages of friction
(iv) reduction of friction
(v) qualitative treatment of viscosity and terminal viscosity.
(vi) stoke’s law.
(i) definition of machine
(ii) types of machines
(iii) mechanical advantage, velocity ratio, and efficiency of machines
(i) elastic limit, yield point, breaking point, Hooke’s law, and Young’s modulus
(ii) the spring balance as a device for measuring force
(iii) work done in springs and elastic strings
(a) Atmospheric Pressure:
(i) definition of atmospheric pressure
(ii) units of pressure (S.I) units
(iii) measurement of pressure
(iv) simple mercury barometer, aneroid barometer, and manometer.
(v) variation of pressure with height
(vi) the use of a barometer as an altimeter.
(b) Pressure in liquids:
(i) the relationship between pressure, depth, and density (P = ρgh)
(ii) transmission of pressure in liquids (Pascal’s Principle)
Liquids at Rest
(i) determination of density of solid and liquids
(ii) definition of relative density
(iii) upthrust on a body immersed in a liquid
(iv) Archimede’s principle and law of flotation and applications, e.g. ships and hydrometers.
Temperature and Its Measurement
(i) concept of temperature
(ii) thermometric properties
(iii) calibration of thermometers
(iv) temperature scales –Celsius and Kelvin.
(v) types of thermometers
(vi) conversion from one scale of temperature to another
(i) definition and determination of linear, volume, and area expansivities
(ii) effects and applications, e.g. expansion in building strips and railway lines
(iii) relationship between different expansivities
(i) volume expansivity
(ii) real and apparent expansivities
(iii) determination of volume expansivity
(iv) anomalous expansion of water
(i) Boyle’s law (PV = constant)
(ii) Charle’s law ( V/P = constant)
(iii) Pressure law ( P/T = constant )
(iv) absolute zero of temperature
(v) general gas equation ( PV/T = constant )
(vi) ideal gas equation (Pv = NRT)
Quantity of Heat
(i) heat as a form of energy
(ii) definition of heat capacity and specific heat capacity of solids and liquids
(iii) determination of heat capacity and specific heat capacity of substances by simple methods e.g method of mixtures and electrical method
Change of State
(i) latent heat
(ii) specific latent heats of fusion and vaporization;
(iii) melting, evaporation, and boiling
(iv) the influence of pressure and of dissolved substances on boiling and melting points.
(v) application in appliances
(i) unsaturated and saturated vapors
(ii) relationship between saturated vapor pressure (S.V.P) and boiling
(iii) determination of S.V.P by barometer tube method
(iv) formation of dew, mist, fog, and rain
(v) study of dew point, humidity, and relative humidity
(vi) hygrometry; estimation of the humidity of the atmosphere using wet and dry bulb hygrometers.
Structure of Matter and Kinetic Theory
(a) Molecular nature of matter
(i) atoms and molecules
(ii) molecular theory: explanation of Brownian motion, diffusion, surface tension, capillarity, adhesion, cohesion, and angles of contact
(iii) examples and applications.
(b) Kinetic Theory
(i) assumptions of the kinetic theory
(ii) using the theory to explain the pressure exerted by gas, Boyle’s law, Charles’ law,
melting, boiling, vapourization, change in temperature evaporation, etc.
(i) conduction, convection, and radiation as modes of heat transfer
(ii) temperature gradient, thermal conductivity, and heat flux
(iii) effect of the nature of the surface on the energy radiated and absorbed by it.
(iv) the conductivities of common materials.
(v) the thermos flask
(vii) the land and sea breeze
(a) Production and Propagation:
(i) wave motion,
(ii) vibrating systems as a source of waves
(iii) waves as a mode of energy transfer
(iv) distinction between particle motion and wave motion
(v) relationship between frequency, wavelength and wave velocity (V=f λ)
(vi) phase difference
(vii) progressive wave equation e.g y = A sin 2π/λ (vt + x)
(i) types of waves; mechanical and electromagnetic waves
(ii) longitudinal and transverse waves
(iii) stationary and progressive waves
(iv) examples of waves from springs, ropes, stretched strings, and the ripple tank.
(c) Characteristics / Properties:
(i) reflection, refraction, diffraction, and plane Polarization
(ii) superposition of waves e.g interference
Propagation of Sound Waves
(i) the necessity for a material medium
(ii) speed of sound in solids, liquids, and air;
(iii) reflection of sound; echoes, reverberation, and their applications
(iv) disadvantages of echoes and reverberations
Characteristics of Sound Waves
(i) noise and musical notes
(ii) quality, pitch, intensity, and loudness and their application to musical instruments;
(iii) simple treatment of overtones produced by vibrating strings and their columns
Fo= 1/2L Square root T/M
(iv) acoustic examples of resonance
(v) frequency of a note emitted by air columns in closed and open pipes in relation to their lengths.
(a) Source of Light:
(i) natural and artificial sources of light
(ii) luminous and non-luminous objects
(b) Propagation of light:
(i) speed, frequency, and wavelength of light
(ii) formation of shadows and eclipse
(iii) the pin-hole camera.
Reflection of Light at Plane and Curved Surfaces
(i) laws of reflection.
(ii) application of reflection of light
(iii) formation of images by plane, concave, and convex mirrors and ray diagrams
(iv) use of the mirror formula
l/F = I/U + I/V
(v) linear magnification
25. Refraction of Light Through
(a) Plane and Curved Surface:
(i) explanation of refraction in terms of velocity of light in the media.
(ii) laws of refraction
(iii) definition of the refractive index of a medium
(iv) determination of the refractive index of glass and liquid using Snell’s law
(v) real and apparent depth and lateral displacement
(vi) critical angle and total internal reflection
(b) Glass Prism:
(i) use of the minimum deviation formula u=sin A+D/2 / A/2.
(ii) type of lenses
(iii) use of lens formula
l = l + l
f u v
(i) the principles of microscopes, telescopes, projectors, cameras, and the human eye (physiological details of the eye are not required)
(ii) power of a lens
(iii) angular magnification
(iv) near and far points
(v) sight defects and their corrections
Dispersion of light and colors
(i) dispersion of white light by a triangular prism
(ii) production of pure spectrum
(iii) color mixing by addition and subtraction
(iv) color of objects and color filters
(b) electgro magnetic spectrum
(i) description of sources and uses of various types of radiation.
(i) existence of positive and negative charges in a matter
(ii) charging a body by friction, contact, and induction
(iv) coulomb’s inverse square law electric field and potential
(v) electric field and potential
(vi) electric discharge and lightning
(i) functions of capacitors
(ii) parallel plate capacitors
(iii) capacitance of a capacitor
(iv) the relationship between capacitance, area separation of plates, and medium between the plates. C = 3A/d
(v) capacitors in series and parallel
(vi) energy stored in a capacitor
(i) simple voltaic cell and its defects;
(ii) Daniel cell, Leclanche cell (wet and dry)
(iii) lead-acid accumulator and Nickel-Iron (Nife) Lithium lon and Mercury cadmium
(iv) maintenance of cells and batteries (detailed treatment of the chemistry of a cell is not required
(v) arrangement of cells
(i) electromagnetic force (emf), potential difference (p.d.), the current, internal resistance of a cell and lost Volt
(ii) Ohm’s law
(iii) measurement of resistance
(iv) meter bridge
(v) resistance in series and in parallel and their combination
(vi) the potentiometer method of measuring emf, the current and internal resistance of a
Electrical Energy and Power
(i) concepts of electrical energy and power
(ii) commercial unit of electric energy and power
(iii) electric power transmission
(iv) heating effects of electric current.
Magnets and Magnetic Fields
(i) natural and artificial magnets
(ii) magnetic properties of soft iron and steel
(iii) methods of making magnets and demagnetization
(iv) concept of magnetic field
(v) magnetic field of a permanent magnet
(vi) magnetic field around a straight current-carrying conductor, circular wire, and solenoid
(vii) properties of the earth’s magnetic field; north and south poles, magnetic meridian, and angle of dip and declination
(viii) flux and flux density
(ix) variation of magnetic field intensity over the earth’s surface
(x) applications: earth’s magnetic field in navigation and mineral exploration.
Force on a Current-Carrying Conductor in
a) Magnetic Field:
(i) quantitative treatment of force between two parallel current-carrying conductors
(ii) force on a charge moving in a magnetic field;
(iii) the d. c. motor
(v) carbon microphone
(vi) moving coil and moving iron instruments
(vii) conversion of galvanometers to ammeters and voltmeters using shunts and multipliers
35. (a) Electromagnetic Induction
(i) Faraday’s laws of electromagnetic induction
(ii) factors affecting induced emf
(iii) Lenz’s law as an illustration of the principle of conservation of energy
(iv) a.c. and d.c generators
(vi) the induction coil
(i) explanation of inductance
(ii) unit of inductance
(iii) energy stored in an inductor
(iv) application/uses of inductors
(c) Eddy Current:
(i) reduction of eddy current
(ii) applications of eddy current
Simple A. C. Circuits
(i) explanation of a.c. current and voltage
(ii) peak and r.m.s. values
(iii) a.c. a source connected to a resistor;
(iv) a.c source connected to a capacitor capacitive reactance
(v) a.c source connected to an inductor-inductive reactance
(vi) series R-L-C circuits
(vii) vector diagram
(viii) reactance and impedance of alternative quantities
(ix) effective voltage in an R-L-C circuits
(x) resonance and resonance frequency
Conduction of Electricity Through
(i) electrolytes and non-electrolyte
(ii) concept of electrolysis
(iii) Faraday’s law of electrolysis
(iv) application of electrolysis, e.g electroplating, calibration of ammeter, etc.
(i) discharge through gases (quantitative treatment only)
(ii) application of conduction of electricity through gases
38. Elementary Modern Physics
(i) models of the atom and their limitations
(ii) elementary structure of the atom;
(iii) energy levels and spectra
(iv) thermionic and photoelectric emissions;
(v) Einstein’s equation and stopping potential
(vi) applications of thermionic emissions and photoelectric effects
(vii) simple method of production of x-rays
(viii) properties and applications of alpha, beta and gamma rays
(xiii) half-life and decay constant
(xiv) simple ideas of the production of energy by fusion and fission
(xv) binding energy, mass defect, and Einsterin’s Energy equation
(xvi) wave-particle paradox (duality of matter)
(xvii) electron diffraction
(xviii) the uncertainty principle
(i) distinction between metals, semiconductors, and insulators (elementary knowledge of band gap is required)
(ii) intrinsic and extrinsic semi-conductors;
(iii) uses of semiconductors and diodes in rectification and transistors in amplification
(iv) n-type and p-type semiconductors
(v) elementary knowledge of diodes and transistors
(vi) use of semiconductors and diodes in rectification and transistors in amplification.
Jamb Physics Syllabus 2023 Recommended Textbook
|Nelkon, M||Fundamentals of Physics|
|Nelkon, M and Parker||Advanced Level Physics (Sixth Edition)|
|Okeke, P. N and Anyakoha, M. W||Senior Secondary School Physics|
|Olumuyionwa A. and Ogunkoya O. O||Comprehensive Certificate Physics|
|Ike, E. E||Essential Principles of Physics|
|Ike, E. E||Numerical Problems and Solutions in Physic|
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