The course aims to introduce the student to vectors, scalar quantities, vector quantities, and addition, subtraction, and multiplication of vectors in physics 1- Motion in one dimension: speed, acceleration, free fall 2- Dynamics: Newton’s first law, Newton’s second law, Newton’s third law Weight and mass, applications of Newton's laws, force of friction

The aim of the material is to define the student: Elasticity: elasticity in length - volume - shape (stress and strain) 1- Pressure: pressure resulting from force, pressure in fluids, Pascal’s rule, Archimedes’ rule, surface tension: surface tension, surface tension and the difference in pressure in a bubble, Capillary property 2-Hydrodynamics: Viscosity - Fluids in motion - Continuity equation - Bernoul-Ley equation - Applications to the Bruno-Lely equation - Poise's law - Stock's law

The goal is to introduce the student to the basics of the laboratory, including the use of a rotating foot, the use of a micrometer, the simple pendulum experiment, and measuring the velocity of fluids (Stoke’s theory).

It aims to introduce the student to equivalence relations, functions, algebraic functions, inverse functions, countable and uncountable sets, derivatives of algebraic functions.

The goal is to introduce the student to the basics of the Arabic language and the basic component of the Arabic sentence. Types of nouns in terms of type, number, definiteness, indefinite, masculine, and feminine - Identifying the types of acquaintances and original and secondary grammatical signs - Understanding how to weight verbs and nouns according to the morphological scale.

A general course that aims to teach the student the concepts and rules of the English language, enable the student to understand and comprehend the English language and use it correctly, and hone the student’s skills in correct pronunciation and correct writing of the English language

The course aims to introduce the student to electric charges and their types: 1- The electric field: the electric force and the electric field, polarity in the electric field, Gauss’s law: electric flux and the electric field, Gauss’s law and Coulomb’s law, applications to Gauss’s law. Electric potential: electric potential and electric field, the voltage resulting from a point charge, a group of point charges, polarity 2- Electric current and resistance: electric current, current density, resistance and specific resistance, Ohm's law

The course aims to introduce the student to waves, their types, longitudinal and transverse, and simple, non-mechanical harmonic motion. 1- Sound: the nature of sound waves, audio spectrum, the speed of sound waves in a solid medium and in a gas. Pressure amplitude, intensity of sound waves, intensity level, waves in pipes, strikes, resonance, Doppler effect. 2- Reflection and refraction: reflection from a flat surface, the principle of rays, reflection from a spherical surface, refraction through plane and spherical surfaces, thin lenses, lens equation

The goal of this course is to introduce the student to several experiments, including: 1- Finding the speed of sound using a resonance tube 2- Finding the refractive index of a liquid 3- Finding the surface tension coefficient of water .using a capillary tube

This course explains and presents concepts, including: vector calculus: vector function. Derived from vector function. Gradient of a scalar function. Divergence and curl of vector functions. Directional derivative and pressure calculation, kinetic interpretation of energy. Linear algebra: integral of matrices. Addition and multiplication of matrices. Inverse of the square matrix. Orthogonal, racial and unit matrices. Properties of determinants and expansion of determinants. Solving non-homogeneous linear equations using Cramer's rule. Primary operations. Echoes and attenuated shapes. . Matrix rank. Equivalent matrices

In this course, the student studies: 1- Rules of declension: the subject and deputy subject, exception, distinction, number, caveat and specialization. 2- Rules of morphology: derivatives, their origin and types, diminution, its symptoms, conditions and method. 3- Rules of rhetoric: metaphor and its types, mursal metaphor, metaphor by metaphor, al-Badi’ 4- Diction: open ta’ and marbuta ta’, alif al-fariqa, soft alif. 5- Texts: The professor selects texts from the Holy Qur’an and .classical Arabic poetry, and they are taught in an applied study, taking into account the rules that have been studied

A general course that aims to teach the student the concepts and rules of the English language, enable the student to understand and comprehend the English language and use it correctly, and hone the student’s skills in correct .pronunciation and correct writing of the English language

This course aims to introduce the student to the following: 1- Rotational kinematics: rotational motion with a constant angular acceleration, the relationship between the linear and angular kinematics of a body. Rotational dynamics: torque, angular momentum, kinetic energy of inertia, translational and rotational motion of a dead body, angular momentum and angular velocity 2- Simple harmonic motion: simple harmonic motion, applications to simple harmonic motion, oscillation force, resonance. Constant law of gravity

The objective of the course is to introduce the student to the following: 1- Ampere’s law: Ampere’s law, flux density near a long wire, two parallel conductors, Bout and Svart’s law. Faraday's law: Faraday's law, change of magnetic field with .time, alternating current. Induction: self-induction, mutual induction, R-L-C circuit, energy and magnetic field

It aims to introduce the student to several experiments, including: 1- Standardizing ammeter and voltmeter using a .potentiometer 2- Determining resistance 3- Determining high resistance using the leakage method

The course aims to introduce the student to the basics of the course, including basic definitions, forms, and classifications of differential equations, first-order differential equations and their various forms, linear differential equations, Wronski's principle for the linear superposition equation with constant coefficients, solutions by changing .terms

The course aims to introduce the student to the basics of chemistry, including the laws and structure of atoms with their details, chemical bonds, the periodic table, and the most important chemical elements in it

A course that aims to expand the abilities and understandings to deal with abstract concepts, and to motivate the student to think scientifically, by first imposing the problem, then trying to build the complete structure to solve it. Course content: matrices and operations defined on them, algebraic properties of operations on matrices, matrix pivots, special types of symmetric and convoluted matrices, elementary operations on the rows of the matrix, equivalent, prime, scalar, reduced matrices, order of the matrix, inverse of the matrix and its properties, use of operations Elementary in calculating a matrix inverse, determinants (general definitions and concepts), properties of determinants, using determinants in calculating the inverse of a non-anomalous square matrix, linear equations (general definitions and concepts), methods for solving homogeneous and inhomogeneous linear systems

The course aims to introduce the student to the basic concepts, which are vector and numerical product - vector differentiation and integration - components of velocity and acceleration 1 - kinematics: mass and dynamic force, Newton's laws of motion, laws of motion in one dimension, free fall. Simple harmonic oscillator, linear differential .equations with constant coefficients

Introducing the student to conductors, insulators, and semiconductors - P-type semiconductor - N-type conductor 1- Uses of the crystal diode: rectification - voltage multiplier - cutting and clamping circuits. Special crystal diodes: Zener diode - tunnel diode - photodiode - light diode 2- Transistor: its types - methods of connecting it - characteristics of the transistor - common-emitter transistor circuits - stability of the transistor and operating point - field-effect transistor JFET - characteristics of the JFET transistor - MOSFET transistor - Field-effect transistor circuits - Operating point of the MOSFET, JFET transistor - Snapdragon transistor - Equivalent circuits for the BJT transistor

It aims to introduce the student to the following: Diodes - Zener diodes - Single wave amplification - Voltage, current and frequency amplification

It aims to introduce the student to the basic concepts, which are temperature - thermal equilibrium - the equation of state 1-The first law of thermodynamics, some results of the first law, entropy, the second law, Helmholtz function, Gibbs function, Maxwell’s equations, the third law of thermodynamics.

The course aims to introduce the student to linear, non-linear and semi-linear partial differential equations, arrangement of the partial differential equation, formations of the partial differential equation, first-order semi-linear partial differential equations: methods of solutions.

Through this course, the student will be familiar with the concepts of computer input, processing, and output units, computer systems exercises, and how to solve and deal with them. Teaching computer basics - computer components (physical and moral). Getting to know computer applications (text editor, Word, Excel, PowerPoint). Getting to know computer numerical systems.

This course aims to introduce the student to the following: Motion of a system of particles, law of conservation of momentum, center of mass, angular momentum, law of conservation of energy, collision. Rigid bodies, gravity, moving axes, Larmor's theory, introduction to the mechanical medium, Lagrange's equation.

It aims to introduce the student to the nature of light and its sources - and the nature of radiation - linear and nonlinear optics 1 - the phenomenon of interference, conditions for interference, Newton’s rings, deflection, deflection of a single slit, conditions for deflection, polarization, types of polarization, Mallo’s law, conditions for polarization. Lasers, Einstein .coefficients, laser elements, laser properties, laser applications

The course aims to give an introduction to electromagnetic theory - electric potential - Maxwell's equations - boundary conditions in the electric field - capacitor charge - Poynting's theory - Biosvar's law - polarization of light - Ampere's law . distribution of low charges

The course aims to introduce the student to the following experiments: 1- Determining the wavelength of sodium light using Newton’s rings. 2- Determine the wavelength of sodium light using a Fresnel prism. 3-Michelson interference of .sodium light. 4- Determine the wavelength of single-wave light using Fabry-Peyrot interference

The course aims to introduce the student to the following: Complex numbers: definition. Algebra operations with complex numbers. Geometric representation, functions of the complex variable, elementary functions of the complex variable, integration in the complex plane, properties of the integration line, Taylor and Lorent series

Introducing the student to the Dirac function in one dimension, the threshold function and the sign function, the wave packet, the time-independent Schordinger equation, Borniers’ assumptions for the wave function, conservation of probability, expected values ​​of dynamic variables, Heisenberg’s uncertainty principle, Ehrenfest theory in one dimension, linear effects and the equation Eigenvalue, definition and properties of the Hermit and Hermit coefficients, infinite .voltage well, voltage threshold, barrier

It aims to introduce the student to energy levels, probability of thermodynamics, Bose and Einstein, and the Fermi-Dirac distribution. Statistical applications on gas, mathematical gas, molecular velocity distribution, heat capacity density, Einstein's theory of heat density in solid bodies, Debye's theory, black body radiation

The course aims to introduce the student to the basics of the course, including: Linear, surface and volumetric integration - energy momentum of the electric field - Poynting's theory - reflection and transmission in waves - Coulomb scale - Coulomb scale and electric potential - one-dimensional and three-dimensional waves - Lorentz oscillator model for atomic scattering and absorption - Helmholtz theory

It aims to give an introduction to mathematical physics - divergence and rotation of the vector - calculation of linear integration on the path - continuity equation - Bernoulli's equation - Hersmith's generative function - Debye's theory - Legendre's equation - thermal conduction equation - Bessel's equation.

The course aims to introduce the student to the basics of the laboratory, including: 1-Gieger molar counter. 2- Investigating the inverse square law in nuclear 3- Determine the absorption coefficient of an aluminum slice. 4-Finding the absolute efficiency of the Geiger counter.

This course aims to introduce the student to the following: Special relativity: ether, the Michelson and Morley experiment, Newton's relativity, postulates of special relativity, Lorentz transformations, time deceleration, length contraction, simultaneity and setting of clocks, speed transformations, relative energy, motion under the influence of gravity, the Doppler effect, the twin problem, manifestations of moving bodies. The apparent contradiction in the spread of light balls. Motion theory of matter: distribution functions, electric charge, measuring the amount of charge, black body radiation, the photoelectric effect, Compton effect, energy quantization of matter.

It aims to introduce the student to the basic concepts of the nucleus, its properties and structure, nuclear models, natural and artificial radioactivity, various radiation detectors, the decay of alpha and beta particles and gamma rays, the interaction (dealing) of radiation with matter, nuclear reactions, nuclear forces and nuclear structure. Neutron physics, nuclear fission, chain reaction, nuclear reactors, nuclear fusion and fusion reactors.

The student's introduction to the central potential, the hydrogen atom, Dirac symbols, and solving algebraic methods for the harmonic oscillator. Simple harmonic oscillator in three dimensions of spherical coordinates

It aims to introduce the student to the crystal and the crystal system, the lattice, types of lattice, Croning and Penny's model, area theory. Insulators, polarization, magnetism and magnetic properties of materials, superconductivity, Meissner effect, types of superconductors, BCS theory.

Introducing the student to the basics of the computer, how to operate it and analyze errors, knowledge of evaluating countries using Taylor series, numerical calculus, knowledge of Monte Carlo simulation, dynamic simulation and molecular simulation.

The objective of the course is to provide experiments in the course, including: 1- Magnetic susceptibility. 2- Energy gap and saturation current 3- Hysteresis loop 4- X-ray refraction and crystal structure

It aims to introduce the student to ionic bonds, van der Waals forces, potential energy, states of matter and their phases, molecular theory, expansion of solids, binding energy, structure of solids, ionic solids, stoichiometric solids, metallic solids, molecular solids, Ionic and electronic conductivity, theory of energy bands in solids, valence bands and conduction. Electrical conductivity of metals and semiconductors.

Introducing the student to the applications of nuclear physics, nuclear magnetic resonance and magnetic resonance imaging, radiation damage, uses of radiation, nuclear bonding energy, fundamental forces in nature, introduction to elementary particles, laws of quantum conservation, fermions, positrons and antiparticles, mesons and the beginning of particle physics. Classification of particles, making particles and measuring their properties, quarks, multi-colored quarks, the standard model.

It aims to introduce the student to the concept of lasers, their composition, types, and applications in various fields Holographic imaging, hologram production, holographic image formation, holographic theory, technical applications, practical applications of holography.

It aims to introduce the student to the concept of plasma and its composition, production and preservation of plasma, plasma and magnetic fields, waves in plasma, thermonuclear fusion, confinement of plasma, movement of a single particle, plasma as a fluid, stability in plasma, sources of ions, tokamak, nuclear fusion reaction as an energy source.

It is a subject concerned with physics that is chosen among the students, in consultation with the supervising professor, on the condition that laboratory equipment and tools are available, if possible, and that books and references familiar with the research are available.