Teaching:
ME 305 L Manufacturing and Workshop Training Lab (Teaching from AY 2011-12 onwards, Multiple sections with both genders, Multi-nationality students)
ME 308 L Advanced Manufacturing Processes Lab (Teaching from AY 2017-18 onwards, Multiple sections with both genders, Multi-nationality students)
ME 201 L Strength of Material Lab (Taught in Summer 2018, 2024)
ME 208 L Mechanics of Material Lab (Taught in Summer 2022)
IE 390 Summer Internship (Worked as Supervising Faculty- Industrial Engineering Internship, 2018,2019,2020,2021,2022, at least 200+ students, both gender)
Research Assistant: With Dr. Hassan: 1- MODIFIED DRAG BASED WIND TURBINE DESIGN WITH SAILS
With Dr. Zuruzi: 1- Design fabrication and testing of a aqueous ozone generator
2- Battery embedded into carbon-fiber composites.
Team member: https://aiam.alfaisal.edu/aiam-team (Alfaisal Initiative on Advanced Manufacturing- AIAM)
Training Advisor:
DMG 310, DMC 635, DMU 50, Boxford lathe and Mill, Tool pre-setter - CNC Machines, Mastercam Software (for CAM)
3D Printers: Form labs (SLA), Zortrax (LPD/FFF/FDM), CubePro (FDM), Snapmaker (FDM), 3DPrint (ZCorporation, BJ), Ultimaker (FDM), Sense Scanner..
Manual Lathe, Drilling, Milling, Band saw, TIG, SPOT, MMA, Oxy-Acetylene gas Welding, Engine test bed, Nova gas tester..
Tensile testing Equipment, Hardness testing Machine, High temperature furnace, Strain Gauge strainer, Polishing and grinding Machine, Precision saw (Cutting Machine), Metallurgical Microscope, Energy absorbed at Fracture, Creep testing machine, Torsion testing machine 20Nm, Rotating fatigue machine, Strength of Materials Lab, Forces in various single plane trusses, Mounting frame, accessories for SE 110.21, Multi-channel measuring amplifier - FL 152, Corrosion of metals - CE 105, Buckling Equipment.
Introduction to Computer Science (CSC101)
This course provides an introduction to a disciplined approach to computer programming and problem solving, utilizing a block-structured high level language, with an emphasis on procedural abstraction and good programming style. Students will apply programming skills in solving a variety of problems. Algorithmic concepts are also introduced. This course also provides a survey study of data structures and data abstraction, and an introduction to complexity considerations and program verification. There will also be an overview of general and introductory computer science concepts.
Course Topics:
The student is expected to understand the basic concepts on the following topics that are covered in the course:
1. Computer basics
2. History of computers
3. Computer hardware
4. Developing a program
5. Algorithms and programming languages
6. Input, processing, and output of programs
7. Program modules
8. Decision structures and Boolean logic
9. Repetition structures
10. Functions
11. Input validation
12. Arrays
13. Files
14. Menu-Driven Programs
Preparatory Algebra 2 [Business] (PAB112)
Course Description:
This course will focus on rational expressions, complex numbers, complex fractions, roots and radicals. There will also be a focus on quadratic equations and functions, exponential and logarithmic functions and systems of nonlinear equations All topics include applications and problem solving techniques.
Students will be provided with clear and logical presentations on techniques to evaluate problems both analytically and graphically, apply theorems and solve problems.
List of Topics:
Preparatory Precalculus 2 [Engineering] (PPC112)
Course Description:
This course reviews and develops intermediate and advanced Algebra skills. The primary
general education learning outcome for this course is quantitative reasoning, which will require
students to read and analyze data, develop mathematical models, draw inferences and support
conclusions based on mathematical reasoning. A graphical approach will be utilized throughout
the course with an emphasis on solving application problems.
List of Topics:
This course is an introduction to Calculus and its applications mainly to business and economics related problems. The course covers an introduction to the fundamentals of single variable calculus. Topics covered include an introduction to limits, continuity, derivative, differentiation rules, derivative tests, graphing functions, Riemann sums, integral, the Fundamental Theorem of Calculus, some integration techniques, and applications to problems.
The objectives of the course are to provide the student with analytical skills and expose him/her to the basic theory and applications of the calculus of a single variable. Upon successful completion of this course, the student will develop the skills required to employ calculus on elementary problems in business and economics.
College Math - Precaluclus (MAT100)
This course builds sound and strong basic mathematics that are required for studying undergrad mathematics. This course is particularly important to students, whose mathematical skills are not sufficiently developed at high school levels. This course covers materials that include algebraic operations, radical and rational expression, equalities and in-equalities, functions and analytic geometry, special types of functions (linear, quadratic, inverse, polynomial, rational, exponential, logarithmic, and trigonometric), solution to equations, and identities involving some types of functions.
The student is expected to understand the basic concepts on the following topics that are covered in the course:
1. Exponents and Rational Exponents 2. Polynomials 3. Rational Expressions 4. Equations (Linear, Rational, Radical, Quadratic) 5. Functions and Their Graphs 6. Linear Functions and Slope 7. Composite and Inverse Functions 8. Quadratic Functions and Their Graphs 9. Rational Functions and Their Graphs 10. Polynomial and Rational Inequalities 11. Exponential and Logarithmic Functions 12. Exponential and Logarithmic Equations 13. Exponential Growth and Decay 14. Trigonometric Functions 15. Systems of Linear Equations in Two and Three Variables 16. Systems of Nonlinear Equations in Two Variables
Semester Schedule:
The schedule is subject to change according to the need of the class and the instructor, as determined by the instructor.
date |
chapter # |
topic |
Sept 1 |
|
Introduction |
Sept 3 |
chapter 1 |
The foundations of biochemistry (introduction, 1.1 cellular foundations) |
Sept 8 |
chapter 1 |
The foundations of biochemistry (1.2 chemical foundations) |
Sept 10 |
chapter 1 |
The foundations of biochemistry (1.3 physical , 1.4 genetic, 1.5 evolutionary) |
Sept 12 |
Lab 0 |
Basics of safe techniques |
Sept 15 |
chapter 2 |
Water (2.1 Weak Interactions in aqueous systems) |
Sept 17 |
chapter 2 |
Water (2.2 Ionization of water, weak acids and weak bases) |
Sept 19 |
Lab 1 |
Titration curves of amino acids |
Sept 22 |
chapter 2 |
Water (2.3 Buffering; 2.4 Water as reactant; 2.5 The fitness of water for living) |
Sept 24 |
chapter 3 |
Amino acids, peptides and proteins (3.1 Amino acids) |
Sept 26 |
Lab 2 |
The absorbance curves of two colored compounds |
Sept 29 |
chapter 3 |
Amino acids, peptides and proteins (3.2 Peptide and proteins; 3.3 Working with proteins) |
Oct 1 |
chapter 3 |
Amino acids, peptides and proteins (4.3 Primary structure) |
Oct 3 |
Lab 3 |
General properties of amino acid |
Oct 6 |
chapter 4 |
Protein tertiary and quaternary structures |
Oct 8 |
|
Midterm examination I |
|
|
Eid Aladha Holiday (Oct 11-Oct 22) |
Oct 22 |
chapter 5 |
Protein function (5.1 Reversible binding of a protein to a ligand) |
Oct 24 |
Lab 4 |
Separation of amino acid by paper chromatography |
Oct 27 |
chapter 5 |
Protein function (5.3 Protein interactions modulated by chemical energy) |
Oct 29 |
chapter 6 |
Enzymes (6.1 Introduction to enzymes; 6.2 How enzymes work) |
Oct 31 |
Lab 5 |
General properties of protein |
Nov 3 |
chapter 6 |
Enzymes (6.3 Enzyme kinetics as an approach to understanding mechanism) |
Nov 5 |
chapter 6 |
Enzymes (6.4 Examples of enzymatic reactions; 6.5 Regulatory enzymes) |
Nov 7 |
Lab 6 |
Quantitation of proteins |
Nov 10 |
chapter 8 |
Nucleotides and nucleic acids (8.1 Some basics; 8.2 Nucleic acid structure) |
Nov 12 |
chapter 8 |
Nucleotides and nucleic acids (8.3 Nucleic acid chemistry; 8. 4 Other functions) |
Nov 14 |
Lab 7 |
Preparation of an enzyme extraction |
Nov 17 |
chapter 0 |
Lipids. (10.1 Storage Lipids; 10.2 Structural lipids in membranes) |
Nov 19 |
chapter 10 |
Lipids (10.3 Lilpids as signals, cofactors and pigments; 10.4 Working with lipids) |
Nov 21 |
Lab 8 |
General properties of lipids |
Nov 24 |
|
Midterm examination II |
Nov 26 |
chapter 11 |
Biological membranes and transport (11.1 Composition and architecture of membranes) |
Nov 28 |
Lab 9 |
General test for carbohydrate |
Dec 1 |
chapter 11 |
Biological membranes and transport (1.3 Solute transport across membranes) |
Dec 3 |
chapter 12 |
Biosignaling (12.1 General features of signal transduction ) |
Dec 8 |
chapter 12 |
Biosignaling (12.2 G Protein-Coupled Receptors and second messengers) |
Dec 10 |
chapter 12 |
Biosignaling (12.3 Receptor Tyrosine Kinases) |
Dec 15 |
chapter 13 |
Bioenergetics and biochemical reaction types (Introduction; 13.1 Bioenergetics and thermodynamics ) |
Dec 17 |
chapter 13 |
Bioenergetics and biochemical reaction types (13.2 Biochemical logic and common biochemical reactions ) |
Dec 22 |
chapter 13 |
Bioenergetics and biochemical reaction types (13.3 Phosphoryl group transfers and ATP) |
Dec 24 |
|
Midterm Examination III |
Organic Chemistry II, (CHM 212)
CHM 212 Continuation of CHM 211. Nomenclature, properties, reactions and synthesis of conjugated dienes, aromatics, organometallics, alcohols, phenols, ethers, aldehydes and ketones, carboxylic acids and derivatives, and amines. Mechanisms include electrophilic aromatic substitution and nucleophilic addition. Carbohydrates, amino acids, proteins and nucleic acids. Laboratory stresses single and multi-step syntheses along with mass spectrometry, ultraviolet, and carbon-13 nuclear magnetic resonance spectroscopy and integrated spectral analysis.