undergraduate plan of study for the - german … of applied... · web viewundergraduate plan of...

School of Applied Medical SciencesUndergraduate Plan of Study for the Bachelor Degree in:

Pharmaceutical-Chemical Engineering

1. General:

Classification Credit HoursCompulsory Contact Hrs. Total

University Requirements 40 81School Requirements 28 36Program Requirements 87 109Technical Electives 18 18

Total = 173 244

2. University Requirements:

A. Compulsory Courses:

Course No. Course Title Cr. Hr. Lecture Lab. Prerequisiteor *Corequisite

ENGL098 English I 0 3 0ENGL099 English II 0 3 0 ENGL098ENGL101 English III 1 3 0 ENGL099ENGL102 English IV 1 3 0 ENGL101ENGL201 English V 2 3 0 ENGL102ENGL202 English VI 2 3 0 ENGL201NE101 National Education 3 3 0MILS100 Military Science 3 3 0CS111 Computing Fundamentals 4 3 0CS1110 Computing Fundamentals Lab 0 0 3ARB099 Arabic 99 0 3 0ARB100 Arabic 3 3 0 ARB099GERL101 German I 3 9 0GERL102 German II 3 9 0 GERL101GERL201 German III 3 6 0 GERL102GERL202 German IV 3 6 0 GERL201GERL301 German V 3 9 0 GERL202

Total = 34 72 3 Contact Hrs. = 75

Ψ Student's score on the English Placement Test will decide the course level

B. University Electives: 6 credit hours


DES 101 Arts’ Appreciation 3 3 0 IC 101 Intercultural Communications 3 3 0 SFTS 101 Soft Skills 3 3 0 SE 301 Social Entrepreneurship and

Enterprises3 3 0

1

EI 101 Leadership and Emotional Intelligence

3 3 0

2

3. School Requirements:


MATH 101 Calculus I 3 3 0

MATH 102 Calculus II 3 3 0 MATH 101MATH 201 Applied Mathematics for Engineers I 3 3 0 MATH 102MATH 231 Probability & Statistics for

Engineering3 3 0 MATH 102

PHYS 101 Physics I 4 3 3

PHYS 102 Physics II 4 3 3 PHYS 101CHEM 101 General Chemistry 4 3 3

IE 121 Workshop 1 0 3

IE 353 Engineering Economics 3 3 0 MATH 201Total = 28 24 12 Contact Hrs. = 36

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4. Program Requirements A minimum of 105 program credit hours are required for graduation divided into 87 credit hours as compulsory and 18 credit hours as technical electives.

A. Compulsory Courses A total of 87 credit hours of core chemical-pharmaceutical engineering coursework are required for graduation, as follows.


CPE 212 Microbiology 4 3 3 BIO 101CPE 221 Analytical Chemistry 4 3 3 CHEM 101CPE 226 Physical Chemistry for

Chemical/Pharmaceutical Engineers I3 3 0 CHEM 101 + MATH 102

CPE 228 Physical Chemistry for Chemical/Pharmaceutical Engineers II

4 3 3 CPE 226

CPE 225 Organic Chemistry 4 3 3 CHEM 101CPE 233 Introduction to Chemical/Pharmaceutical

Engineering1 1 0 CHEM 101

CPE 236 Principles of Chemical Engineering 3 3 0 CPE 233 + * γ CPE 228CPE 238 Fluid Mechanics for Chemical and

Medical Engineers3 3 0 MATH 201

CPE 324 Instrumental Analysis 4 3 3 CPE 221CPE 326 Biochemistry 4 3 3 BIO 101+ CPE 225CPE 331 Transport Phenomena 3 3 0 CPE 236 + CPE 238CPE 332 Chemical Reaction Engineering I 3 3 - CPE 236CPE 334 Chemical Reaction Engineering and

Heat Transfer Lab1 0 3 CPE 332 + CPE 331

CPE 336 Separation Processes I 3 3 - CPE 331CPE 391 Field Training Ψ 0 0 160 hCPE 435 Pharmaceutical Technology – Liquid

Forms4 3 3 CPE 228 + CPE 238

CPE 436 Pharmaceutical Technology – Solid Forms

4 3 3 CPE 331

CPE 437 Separation Processes II 3 3 - CPE 336CPE 439 Separation Processes Lab 1 0 3 CPE 336CPE 499 Practical Training 12 0 6

monthsDA

CPE 533 Pharmaceutical Packaging Engineering 3 3 0 CPE 435 + CPE 436CPE 536 Pharmaceutical Facility Design 3 3 0 CPE 435 + CPE 436CPE 595 Graduation Project I 3 0 9 * γ CPE 536CPE 596 Graduation Project II 3 0 9 CPE 595BIO 101 Biology 3 3 0 ME 343 Automatic Control Systems 4 3 3 MATH 201

87 58 5158 Contact Hrs. = 109

Ψ Students must complete 160 hours of field training in approved industries in Jordan by the end of their third academic year.

DA is Departmental Approval.

γ prerequisite or co-requisite

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B. Technical Electives A minimum of 18 credit hours of specialized chemical-pharmaceutical engineering coursework are required for graduation. The offered courses are:


CPE 441 Medicinal Chemistry 3 3 - CPE 212 + CPE 326CPE 451 Biotechnology 3 3 - CPE 332 + CPE 212CPE 511 Gene Technology 3 3 - CPE 326CPE 512 Antibiotics 3 3 - CPE 212CPE 513 Nutrition 3 3 - BIO 101CPE 524 Introduction to Polymer Science 3 3 CPE 225CPE 527 Pharmaceutical Organic Chemistry 3 3 - CPE 225CPE 526 Colloids and Surface Chemistry 3 3 - CPE 228 or DA

CPE 528 Pharmaceutical Physical Chemistry 3 3 - CPE 228CPE 550 Numerical Methods for Engineers 3 3 - MATH 231CPE 551 Corrosion Engineering 3 3 - CPE 228CPE 552 Nanotechnology 3 3 - CPE 436CPE 553 Particle Technology 3 3 - CPE 436CPE 554 Fluid Mixing Technology 3 3 - CPE 238CPE 555 Chemical Process Safety 3 3 - *CPE 536CPE 556 Chemical Reaction Engineering II 3 3 CPE 332CPE 557 Chemical & Physical Sensors 3 3 CPE 324 + CPE 326CPE 558 Environmental Engineering 3 3 CPE 221CPE 559 Membrane separation processes 3 3 CPE 336CPE 561 Experimental Design and Data

Analysis3 3 - MATH 231

CPE 562 Validation 3 3 - MATH 231CPE 563 Pharmacokinetics 3 3 - CPE 332 or DACPE 564 Toxicology 3 3 - CPE 326 or DACPE 565 Modern Drug Forms & Delivery

Systems3 3 - CPE 435

CPE 581 Special Topics in Chemical /Pharmaceutical Engineering I

3 3 - DA

CPE 582 Special Topics in Chemical /Pharmaceutical Engineering II

3 3 - DA

CPE 583 Special Topics in Chemical /Pharmaceutical Engineering III

3 3 - DA

CPE 584 Special Topics in Chemical /Pharmaceutical Engineering IV

3 3 - DA

CPE 585 Special Topics in Chemical /Pharmaceutical Engineering V

2 2 - DA

CPE 586 Special Topics in Chemical /Pharmaceutical Engineering VI

1 1 - DA

CPE 590 Special Field Projects 3 - 9 DAENRE 431 Renewable Energy Resources

Assessment3 3 - ENRE 331 or DA

ENRE 436 Energy Management 3 3 - IE 531 or DAIE 531 Project Management 3 3 - IE 353WEEM 453 Wastewater Engineering 3 3 - WEEM 351 or DAWEEM 473 Emission Control 3 3 - WEEM 271 or DAWEEM 522 Hazardous Waste Management 3 3 - WEEM 231 or DADA is Departmental Approval.

5

Number Code: CPE XYZ X: Course Level: “1” is year 1, “5” is year 5. Y: Subject of the course; defined as follows:

1 Biology2 Chemistry3 Chemical Engineering- Core course5 Chemical Engineering- Elective course4 Pharmaceutical Engineering- Core course6 Pharmaceutical Engineering- Elective course8 Special Topics9 Projects.

Z: “odd #” means first semester; “even #” means second semester.

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Guide Plan for Chemical/Pharmaceutical Engineering Program

Year 1 – Semester 1Course

I.D. Course Title Credit Hours

Contact Hours Prerequisite *Co-requisiteLecture Practical

GERL 101 German I 3 9 0 ENGL 101 English III 1 3 0 ENGL 099CHEM 101 General Chemistry 4 3 3 MATH 101 Calculus I 3 3 0 PHYS 101 Physics I 4 3 3 ARB 100 Arabic 3 3 0

Total 18 24 6 Contact Hrs. = 30Year 1 – Semester 2

Course I.D. Course Title Credit

HoursContact Hours Prerequisite

*Co-requisiteLecture PracticalGERL 102 German II 3 9 0 GERL 101ENGL 102 English IV 1 3 0 ENGL 101MATH 102 Calculus II 3 3 0 MATH 101PHYS 102 Physics II 4 3 3 PHYS 101BIO 101 Biology 3 3 0 CS 111 Computing Fundamentals 4 3 0 *CS 1110CS 1110 Computing Fundamentals Lab 0 0 3 *CS 111



HoursContact Hours Prerequisite *Co-

requisiteLecture PracticalGERL 201 German III 3 6 0 GERL 102ENGL 201 English V 2 3 0 ENGL 102MATH 201 Applied Mathematics for Engineers I 3 3 0 MATH 102

CPE 226 Physical Chemistry for Chemical/Pharmaceutical Engineers I 3 3 0 CHEM 101 +

MATH 102CPE 225 Organic Chemistry 4 3 3 CHEM 101

CPE 233 Introduction to Chemical/Pharma Eng 1 1 0 CHEM 101

IE 121 Workshop 1 0 3 Univ. ??? University Elective I 3 3 0



HoursContact Hours Prerequisite /

*Co-requisiteLecture PracticalGERL 202 German IV 3 6 0 GERL 201ENGL 202 English VI 2 3 0 ENGL 201CPE 212 Microbiology 4 3 3 BIO 101

CPE 228 Physical Chemistry for Chemical/Pharmaceutical Engineers II 4 3 3 CPE 226

CPE 236 Principles of Chemical Engineering 3 3 0 CPE 233 +*ϒCPE 228

CPE 238 Fluid Mechanics for Chemical and Medical Engineers 3 3 0 MATH 201

Total 19 21 6 Contact Hrs. = 27

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Contact Hours Prerequisite /*Co-requisiteLecture Practical

GERL 301 German V 3 9 0 GERL 202MATH 231 Probability & Statistics for Engineers 3 3 0 MATH 102CPE 221 Analytical Chemistry 4 3 3 CHEM 101CPE 331 Transport Phenomena 3 3 0 CPE 236 + CPE 238CPE 332 Chemical Reaction Engineering I 3 3 0 CPE 236CPE 391 Field Training 0 0 -

CPE 435 Pharmaceutical Technology Liquid Forms 4 3 3 CPE 228 + CPE 238


Students must complete 160 hours of field training in approved industries in Jordan by the end of third academic year.




CPE 324 Instrumental Analysis 4 3 3 CPE 221CPE 326 Biochemistry 4 3 3 BIO 101 + CPE 225

CPE 334 Chemical Reaction Eng. & Heat Transfer Lab 1 0 3 CPE 332 + CPE 331

CPE 336 Separation Processes I 3 3 0 CPE 331

CPE 436 Pharmaceutical Technology Solid Forms 4 3 3 CPE 331

IE 353 Engineering Economics 3 3 0 MATH 201Total 19 15 12 Contact Hrs. = 27

Year 4 – Semester 1 & 2Course



Technical Elective I 3 3 Technical Elective II 3 3 Technical Elective III 3 3 Technical Elective IV 3 3

CPE 499 Practical Training 12 6 monthsTotal 24 12 6 months Contact Hrs. = 12

8




CPE 439 Separation Processes Lab 1 0 3 CPE 336CPE 437 Separation Processes II 3 3 0 CPE 336CPE 533 Pharmaceutical Packaging Engineering 3 3 0 CPE 435 + CPE 436CPE 536 Pharmaceutical Facility Design 3 3 0 CPE 435 + CPE 436CPE 595 Graduation Project I 3 0 9 *CPE 536CPE ??? Technical Elective V 3 3 0Univ. ??? University Elective II 3 3 0





CPE 596 Graduation Project II 3 0 9 CPE 595CPE ??? Technical Elective VI 3 3 0ME 343 Automatic Control Systems 4 3 3 MATH 201NE 101 National Education 3 3 0 MILS 100 Military Science 3 3 0


9

CPE 228Physical Chem II

CPE 226Physical Chem I

CPE 331Transport

Phenomena

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Course Description for the Chemical-Pharmaceutical Engineering Program

ARB 100: Arabic (3 Cr. Hrs.)Grammar and structure. Rectifying weakness in linguistic application; training in sound reading. Dictation; use of language in a manner free from grammatical and linguistic errors; accurate expression of intended meaning. Study and analysis of literary texts through the discussion of linguistic, grammatical and writing skills therein

BIO 101. Biology. (3 Cr. Hrs.) Two lectures per week.Prerequisites: noneCell biology (construction, transport through membranes, metabolism), photosynthesis, genetics, proteins, enzymes, protein synthesis and finally dealing with the human systems including: Muscular system, bones-skeletal system-, digestive, respiratory, nervous, immunity, endocrine, circulatory-heart- and the urinary system.

CHEM 101. General Chemistry. (4 Cr. Hrs.) Two lectures per week and 3 hours of laboratory.Prerequisites: none.Stoichiometry of formulas and equations. Gases and the kinetic-molecular theory. Quantum theory and atomic structure. The components of matter. The major classes of chemical reactions (precipitation, acid-base, oxidation-reduction, and reversible reactions). Thermodynamics: energy flow and chemical change. Quantum theory and atomic structure. Electron configurations and chemical periodicity. Kinetics: rates and mechanisms of chemical reactions. Equilibrium: The extent of chemical reactions. Acid-base equilibria.

CPE 212. Microbiology. (4 Cr. Hrs.) Two lectures per week and 3 hours of laboratory.Prerequisites: Biology (BIO 101)Microbiological diagnostics, medical and clinical aspects of microbiology. The need for sterilization and disinfection in hospitals and laboratories. Taxonomy of bacteria. In addition to the importance of bacteria as causative agents of infections and their use in biotechnology.

CPE 221. Analytical Chemistry. (4 Cr. Hrs.) Two lectures per week and 3 hours of laboratory.Prerequisites: General Chemistry (CHEM 101).Acid-base equilibria. Redox equilibria. Complex-formation equilibria. Electrolytes, electrolytic dissociation – conductivity of aqueous solutions, conductometry, ionic mobility, Hittorf’s ion transference numbers, electrochemical potential (metals and non-metals, organic compounds), Nernst’s law, fundamentals of potentiometric instrumentation, fundamentals of voltametry (current-voltage curves), Karl-Fischer titration.

CPE 226. Physical Chemistry for Chemical/Pharmaceutical Engineers I. (3 Cr. Hrs.) Two lectures per week.Prerequisites: General Chemistry (CHEM 101,) and Calculus II (MATH 102).Behavior of gases. Equations of state and real gases. The first law of thermodynamics. The second and third laws of thermodynamics. Chemical equilibrium. Phases and solutions.

CPE 228. Physical Chemistry for Chemical/Pharmaceutical Engineers II. (4 Cr. Hrs) Two lectures per week and 3 hours of laboratory.Prerequisites: Physical Chemistry for Chemical/Pharmaceutical Engineers II (CPE 226).Phase equilibria. Solutions of electrolytes. Thermodynamics of ions. Electrochemical cells. The solid state: crystals forms and structures. Surface chemistry and colloids.

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CPE 225. Organic Chemistry. (4 Cr. Hrs.) Two lectures per week and 3 hours of laboratory.Prerequisites: General Chemistry (CHEM 101).Bonding models for CH, simple CC and multiple CC bonds. The possibilities for isomery of open-chained cyclic hydrocarbons including their dynamics (conformation). Electron structure of conjugated double bonds and aromatic π-systems. Polar single and multiple bonds and the resulting electronic substituent effects. The most important classes of organic compounds. Overview of various reaction types and initial mechanistic reaction observations.

CPE 233. Intr. to Chemical/Pharmaceutical Engineering. (1 Cr. Hr.) One lecture per week.Prerequisites: General Chemistry (CHEM 101)What chemical/pharmaceutical engineers do. Engineering calculations: units, dimensional homogeneity and dimensionless quantities. Process data presentation and analysis. Processes and process variables.

CPE 236. Principles of Chemical Engineering. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Introduction to Chemical/Pharmaceutical Engineering (CPE 233)Corequisite: Physical Chemistry for Chemical/Pharmaceutical Engineers II (CPE 228)Fundamentals of material and energy balances. Single and multiphase systems. Balances on nonreactive and reactive processes.

CPE 238. Fluid Mechanics for Chemical and Medical Engineers. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Applied Mathematics for Engineers I (MATH 201).Fluid mechanics in chemical engineering. Density, viscosity and surface tension. Mass, energy and momentum balances. Bernoulli’s equation. Fluid friction in pipes. Flow in engineering equipment: pumps and compressors. Forces on solid particles in fluids. Flow through packed beds, filtration, fluidization. Dimensional analysis. Differential equations of fluid mechanics. Turbulent flow.

CPE 324. Instrumental Analysis. (4 Cr. Hrs.) Two lecture per week and 3 hours of laboratory.Prerequisites: Analytical Chemistry (CPE 221).Electrical components and circuits. Signals and noise. Atomic Spectrometry: flame technology, graphite furnace technology, cold vapor and hydride technology, inductively coupled plasma. UV Spectroscopy. IR Spectroscopy. Raman Spectroscopy. Mass spectroscopy. Chromatographic Methods: Fundamentals of chromatographic analysis. High performance liquid chromatography. Gas chromatography. Capillary electrophoresis. Sample preparation techniques for chromatographic analyses. Thermogravimetric Analysis and DSC analyses. Eutectic systems. Glass transition temperature. Crystallography. X-ray diffractometry. Electrical, optical and magnetic properties of crystalline substances. Surface characterization by spectroscopy and microscopy: Basic introduction to scanning electron microscopy, scanning tunneling microscopy, atomic force microscopy and near-field optical microscopy, probe types and work methods.

CPE 326. Biochemistry. (4 Cr. Hrs.) Two lectures per week and 3 hours of laboratory.Prerequisites: Organic Chemistry (CPE 225), Biology (BIO 101).Amino acids and peptides; Proteins: structure and function. Enzymes, enzyme kinetics of carbohydrates. Lipids, biological membranes. Nucleic acids; replication, transcription, translation. Biosynthesis of protein. Bioenergetics. Primary metabolism and regulation.

CPE 331. Transport Phenomena. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Principles of Chemical Engineering (CPE 236), and Fluid Mechanics for Chemical Engineers (CPE 238).Introduction to mass transfer. Diffusion fluxes and Fick’s law. Transport properties of mixtures. The general problem of heat transfer. Modes of heat transfer. Heat conduction concepts. Heat

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exchanger design. Steady and transient heat conduction. Convective heat transfer in laminar and turbulent systems. Simultaneous heat and mass transfer.

CPE 332. Chemical Reaction Engineering I. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Principles of Chemical Engineering (CPE 231)Kinetics of homogeneous reactions. Prediction of rates of chemical conversion. Reactor design for single and multiple reactions. Michaelis-Menten kinetics. Retention time in chemical reactors. Design for heterogeneous reacting systems. Solid-catalyzed reactions.

CPE 334. Chemical Reaction Engineering and Heat Transfer Lab. (1 Cr. Hr). Three hours of laboratory per week.Prerequisites: Chemical Reaction Engineering I (CPE 332), and Transport Phenomena (CPE 331) Conduct experiments applying chemical engineering and heat transfer concepts.

CPE 336. Separation Processes I. (3 Cr. Hrs.) Two lectures per week and 3 hours of laboratory.Prerequisites: Transport Phenomena (CPE 331).Stage and continuous gas-liquid separation processes. Vapor-liquid separation processes: absorption and stripping, distillation. Drying of process materials.

CPE 435. Pharmaceutical Technology Liquid Forms. (4 Cr. Hrs.) Two lectures per week and 3 hours of laboratory.Prerequisites: Physical Chemistry for Chemical/Pharmaceutical Engineers II (CPE 228), and Fluid Mechanics for Chemical Engineers (CPE 238).Water systems and purification. Liquid dosage forms (solutions, suspensions, emulsions, sterile/parenteral dosage forms). Filling and Packaging. Microbiological contamination. Types of semisolid topical dosage forms (Gels, ointments, creams, pastes), suppositories and pessaries, suppositories and pessaries, transdermal patches, intrauterine and intravaginal therapeutic systems, therapeutic aerosols.

CPE 436. Pharmaceutical Technology Solid Forms. (4 Cr. Hrs.) Two lectures per week and 3 hours of laboratory.Prerequisite: Transport Phenomena (CPE 331).Particle size reduction, powder mixing, granulation and pellitization, drying, tableting, coating, hard and soft capsules, microparticles, implants; milling, sieving, sifting, mixing solid substances, granulating, tableting, film-coating. Testing of powders, granulates, tablets, capsules, microparticles and implants.

CPE 437. Separation Processes II. (3 Cr. Hrs.) Two lectures per week and 3 hours of laboratory.Prerequisites: Separation Processes I (CPE 336).Liquid-liquid extraction, adsorption, membrane separation, leaching, crystallization and evaporation.

CPE 439. Separation Processes Lab. (1 Cr. Hrs.) Three hours of laboratory per week.Prerequisites: Transport Phenomena (CPE 336).Conduct experiments applying separation processes concepts.

CPE 441. Medicinal Chemistry. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Microbiology (CPE 212), and Biochemistry (CPE 326).Pharmaceutical Chemistry: drugs and their interactions, principles of finding drugs, inorganic agents, organic agents - ordered according to therapy groups: nervous system, endocrine system, substances that affect the heart and circulatory system, respiratory tract, skin and vitamins and chemo-therapeutics. Pharmaceutical Biology: herbal substances, technology of herbal drugs, testing

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the intermediate products and the final drug in accordance with national and international pharmacopoeias. Pharmacology: Introduction to pharmacology: pharmacodynamics, pharmacokinetics. Effect of drugs on the human organism.

CPE 451. Biotechnology. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Chemical Reaction Engineering I (CPE 332),and Microbiology (CPE 212).The tasks of biotechnology in the pharmaceutical industry, agriculture, food industry. Biotechnological methods and processes. Fermentation process and reactors. Processing of biotechnological products for applications from intra and extra cellular products to packaging. What are enzymes, their biotechnological production, their applications in medicine, diagnostics, food production, pharmacy, agriculture and research. Biotechnological production of biomass, low molecular weight products and macromolecules and also biotransformations.

CPE 499. Practical Training. (12 Cr. Hrs.) Prerequisites: Departmental Approval.Practical training for 18 weeks after the completion of at least 90 credit hours (See Practical Training Regulations of the College of Applied Medical Sciences).

CPE 511. Gene Technology. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Biochemistry (CPE 326).Introduction; transfer of genetic information into proteins: transcription/ translation; tools of the genetic engineer; host organisms and properties; cloning; polymerase chain reaction; applications in genetic engineering.

CPE 512. Antibiotics. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Microbiology (CPE 212).Introduction to antibiotics and antibacterial chemotherapy. Classification and structure-activity relationship of antibiotics and antibacterial agents. Epidemiology of resistance to antibacterial agents. Development of an antibiotic. Inhibitors of ß-lactamases, DNA-gyrase. Codrugs. Coumarin antibiotics. Development of resistance and the use of multiple antibacterials during an infection. Drug interactions. Antibacterials and bioterrorism. Clinical quality assurance and the international development of new anti-infective agents.

CPE 513. Nutrition. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Biology (BIO 101)This Course is designed to make the student aware of their food environment in relation to nutrition and disease. The course also deals with the description of balanced diet and the influence of food habits on health and physical performance.

CPE 524. Introduction to Polymer Science. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Organic Chemistry (CPE 225).Definitions and classification, nomenclature, basic concepts on structure and on thermal and mechanical behavior. Polycondensation and polyaddition, radical, ionic and metal catalyzed polymerization. Copolymerisations. Chemical modification of polymers. Polymer blends and new developments. Equipment and additives, processing of plastics. Disposal and recycling. Natural macromolecular substances and their most important technical and pharmaceutical derivatives. The characterization of polymers.

CPE 527. Pharmaceutical Organic Chemistry. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Organic Chemistry (CPE 225).Substitution reactions on aromatics, electrophiles, nucleophiles and radical processes. Aromatics. CH acidity. Aldol addition and aldol condensation, ester condensation and related reactions.

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Reactivity of polar double and triple bonds. Organic metal compounds. The most important organic nitrogen compounds and their reactions. Organic phosphorus compounds. Organic sulphur compounds. π-bonds with the d-orbitals that are involved. Hetero-aromatics. Basic concepts on polymerisation, remarks on pericyclic reactions, thermal and photochemical cyclo-additions, rearrangements and fragmentations.

CPE 526. Colloids and Surface Chemistry. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Physical Chemistry for Chemical/Pharmaceutical Engineers II (CPE 228), or Departmental approval.Nature of colloidal dispersions. Thermodynamics of surfaces. Transport properties of suspensions. Particle size and shape. Adsorption onto solid surfaces. Electrically charged interfaces. Particle interaction and coagulation. Rheology of colloidal dispersions.

CPE 528. Pharmaceutical Physical Chemistry. (3 Cr. Hrs.) Two lectures per week Prerequisites: Physical Chemistry for Chemical Engineers II (CPE 228).Surface and interfacial phenomena, surface tension of liquids, contact angle to surfaces, washing process and tensides, adsorption models isotherms, colloidal systems, production and stabilisation of emulsions, dispersion colloids and gels, applications in chemical analysis (electrophoresis, gel permeation chromatography) and pharmaceutical engineering (micro-emulsions, hydrogels, nanoparticles). Transport properties in material systems. Properties of solids (lattice types, X-ray diffraction in solids).

CPE 533. Pharmaceutical Packaging Engineering. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Pharmaceutical Technology Liquid Forms (CPE 435), and Pharmaceutical Technology Solid Forms (CPE 436)Packaging technology, function of packaging, demands on packaging, packaging materials, aids, processes, machines, and systems. Packaging of both liquid and solid forms in various types of delivery containers: vials/ampoules, blister packs, individual packets, bottles, pouches, and syringes. Tableting capsule filling and form/fill/seal, and proper labeling of final drug forms.

CPE 536. Pharmaceutical Facility Design. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Pharmaceutical Technology Liquid Forms (CPE 435), and Pharmaceutical Technology Solid Forms (CPE 436)Project design and management. Site selection. Process flow. Pharmaceutical process utility systems. Considerations in the design of a pharmaceutical facility. Cleanrooms. Design of a sterile and aseptic manufacturing facility. Special production systems and automation. Packaging systems. Validation.

CPE 550. Numerical Methods for Engineers. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Probability and Statistics for Engineering (MATH 231), or Departmental approval.Introduction to MATLAB, systems of linear algebraic equations, interpolation and curve fitting, roots of equations, numerical differentiation, numerical integration, numerical solutions of ordinary differential equations (ODEs) and partial differential equations (PDEs).

CPE 551. Corrosion Engineering. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Physical Chemistry for Chemical/Pharmaceutical Engineers II (CPE 228).Electrochemical and metallurgical aspects of corrosion. Forms of corrosion. Modern theory of corrosion and its application. Iron and steel corrosion. Corrosion prevention. Case studies.

CPE 552. Nanotechnology. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Pharmaceutical Technology – Solid Forms (CPE 436), or Departmental approval.

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Basic Concepts; Molecular Structures; MacroMolecular Structures; Surfaces and Interfaces; Properties of Nanostructures; Nanofabrication; Characterization of Nanostructures and Nanomaterials; Nanomaterials and Applications; Thin Films; NanoParticles; NanoPorous Structures; NanoTubes and Fibers; Nanocomposites; Nanosystems

CPE 553. Particle Technology. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Pharmaceutical Technology – Solid Forms (CPE 436), or Departmental approval.Particle size analysis. Single particles in a fluid. Multiple particle systems. Fluid flow through a packed bed of particles. Fluidization. Pneumatic transport and standpipes. Separation of particles from a gas: gas cyclones. Storage and flow of powders. Mixing and segregation. Particle size reduction. Size enlargement. Fire and explosion hazards of fine powders.

CPE 554. Fluid Mixing Technology. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Fluid Mechanics for Chemical and Medical Engineers (CPE 238).Theory of mixing processes in laminar and turbulent flows. Practical aspects of mixing processes (equipment selection, design, scale-up). Mechanical design of fluid mixers. Heat transfer in agitated vessels.

CPE 555. Chemical Process Safety. (3 Cr. Hrs.) Two lectures per week.Prerequisite (or Co-requisite): Pharmaceutical Facility Design (CPE 536).This course will cover safety subjects that are considered core for process safety. Subjects include toxicology, industrial hygiene, sources of toxic releases, gas dispersion, fires and explosions, relief valves and their sizing, flaring, hazard identification and risk assessment.

CPE 556. Chemical Reaction Engineering II. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Chemical Reaction Engineering (CPE 332).Nonideal flow. Mixing of fluids. Fluid-particle reactions. Fluid-fluid reactions. Deactivating catalysts.

CPE 557. Chemical & Physical Sensors. (3 Cr. Hrs.) Three lectures per week.Prerequisites: Instrumental Analysis (CPE 324), Biochemistry (CPE 326).Definitions and basic concepts of chemical sensor technology, physico-chemical basics of sensor technology, dividing sensors into classes, properties and design of sensors, general fields of application, types of detection in sensors, sensor systems and applications, sensors as parts of Microsystems. Definition and basic concepts of physical sensor technology, general fields of application.

CPE 558. Environmental Engineering (3 Cr. Hrs.) Two lectures per week.Prerequisites: Analytical Chemistry (CPE 221).Legal framework in the fields of water, soil and air. Sampling techniques in the different environmental domains. Online analytical processes. Legal framework in the fields of water, soil and air. Sampling techniques in the different environmental domains. Online analytical processes.

CPE 559. Membrane Separation Processes. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Separation Processes I (CPE 336).Introduction; classification; definitions. Membranes: materials, preparation, modules, characterization, transport Mechanisms. Membrane Processes: microfiltration, ultrafiltration, nanofiltration, reverse osmosis, dialysis, electrodialysis, pervaporation, gas separation, liquid membranes, other techniques, membrane reactors.

CPE 561. Experimental Design and Data Analysis. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Probability & Statistics for Engineers (MATH 231).

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Review of Statistical distributions. Simple comparative experiments. Experiments with a single factor. Analysis of variance; randomized blocks, Latin squares, and related designs. Incomplete block designs, factorial designs, confounding in factorial designs, two-level fraction factorial designs, multi-factor experiment and nested designs.

CPE 562. Validation (3 Cr. Hrs.) Two lectures per week.Prerequisites: Probability and Statistics for Engineering (MATH 231), or Departmental approval.Regulatory Basis for Process Validation. Sterilization Validation. Validation of Solid Dosage Forms. Validation for Medical Devices. Validation of Biotechnology Processes. Process Validation of Pharmaceutical Ingredients. Qualification of Water and Air Handling Systems. Integrated Packaging Validation. Equipment and Facility Qualification.

CPE 563. Pharmacokinetics. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Chemical Reaction Engineering I (CPE 332), or Departmental approval.Introduction to Pharmacokinetics and Pharmacodynamics, Passage of Drug through Membranes, Drug Absorption, Drug Distribution, Drug Elimination.

CPE 564. Toxicology. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Biochemistry (CPE 326), or Departmental approval.Disposition of toxic compounds, metabolism of foreign compounds, types of exposure and response, drugs as toxic substances, industrial toxicology, food additives and contaminants, pesticides, environmental pollutants, natural products, household products, toxicity testing and risk assessment.

CPE 565. Modern Drug Forms & Delivery Systems. (3 Cr. Hrs) Two lectures per week.Prerequisites: Pharmaceutical Technology - Liquid Forms (CPE 435).Therapeutic systems, nanoparticles, nanosuspensions, microemulsions, Self-McroEmulsifying Delivery Systems (SMEDDS), multiple emulsions. Special Adsorbates. Biopharmaceutical in vitro models of drug release investigation of several drug delivery systems and in vitro absorption models, exploitation of drug release and absorption investigations, biopharmaceutical aspects of application sites and drug delivery systems, investigation of plasma concentration curve, bioavailability.

CPE 581. Special Topics in Chemical/Pharmaceutical Engineering I. (3 Cr. Hrs.)Prerequisites: Departmental approval.Title and course contents of the topic must be approved by the Department’s Council and pre-announced by the Department.

CPE 582. Special Topics in Chemical/Pharmaceutical Engineering II. (3 Cr. Hrs.)Prerequisites: Departmental approval.Title and course contents of the topic must be approved by the Department’s Council and pre-announced by the Department.

CPE 583. Special Topics in Chemical/Pharmaceutical Engineering III. (3 Cr. Hrs.)Prerequisites: Departmental approval.Title and course contents of the topic must be approved by the Department’s Council and pre-announced by the Department.

CPE 584. Special Topics in Chemical/Pharmaceutical Engineering IV. (3 Cr. Hrs.)Prerequisites: Departmental approval.Title and course contents of the topic must be approved by the Department’s Council and pre-announced by the Department.

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CPE 585. Special Topics in Chemical/Pharmaceutical Engineering V. (2 Cr. Hrs.)Prerequisites: Departmental approval.Title and course contents of the topic must be approved by the Department’s Council and pre-announced by the Department.CPE 586. Special Topics in Chemical/Pharmaceutical Engineering VI. (1 Cr. Hrs.)Prerequisites: Departmental approval.Title and course contents of the topic must be approved by the Department’s Council and pre-announced by the Department.

CPE 590. Special Field Projects. (3 Cr. Hrs.) Nine hours of filed project work per weekPrerequisites: Departmental approval.Title and course contents of the topic must be approved by the Department’s Council and pre-announced by the Department.

CPE 595. Graduation Project I. (3 Cr. Hrs.) Prerequisite (or Co-requisite): Pharmaceutical Facility Design (CPE 536).Theoretical and/or experimental investigation of a problem in chemical/pharmaceutical engineering, or design and development of a chemical process. A student or a group of students undertake an independent project under the supervision of a faculty member. The general objectives are to improve the student's skills and creativity, and to give him/her the experience of problem solving with integration of chemical/pharmaceutical engineering principles.

CPE 596. Graduation Project II. (3 Cr. Hrs.) Prerequisites: Graduation Project I (CPE 595).Completion of the same project started in CPE 595 with more details, theoretical and/or experimental work, design and calculations.

ENGL 098: English I (Elementary English) (0 Cr. Hrs.)Students will focus on English at an elementary level concentrating on the receptive skills of reading and listening, and the productive skills of writing and speaking. These will include such things as independent clauses, verb tenses, model verbs, adverbs, short dialogues, reading simple material and answering short questions, writing short meaningful sentences, listening to short conversations.

ENGL 099: English II (Pre-Intermediate English) (0 Cr. Hrs.)Students will focus on English at a pre-intermediate level concentrating on the receptive skills of reading and listening and the productive skills of writing and speaking. These will include such things as comparatives and superlatives, quantifiers, possessive adjectives and pronouns, vocabulary building, role play activities for speaking, reading comprehension and writing short descriptive paragraphs.

ENGL 101: English III (Intermediate English) (1 Cr. Hr.)Students will focus on English at an intermediate level concentrating on the receptive skills of reading and listening and the productive skills of writing and speaking. These will include collocations, tense review, affirmative, negative statements, synonyms and antonyms, time clauses, conditionals, active and passive forms, reported speech, phrasal verbs, reading comprehension with detailed questions, vocabulary and writing developed descriptive and opinion essays.

ENGL 102: English IV (Upper-Intermediate English) (1 Cr. Hr.) Students will focus on English at an upper-intermediate level concentrating on the receptive skills of reading and listening and the productive skills of writing and speaking. Model verb review, silent letters and proper pronunciation, jobs and careers, requests and offers, more phrasal verbs

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with vocabulary building, relative clauses and relative pronouns, narrative tenses for writing exercises, wishes and regrets, reading and comprehending longer passages with direct and inference questions of medium difficulty, hypothesizing, and writing fully developed descriptive, argumentative and analytical essays of 350 words.

ENGL 201: English V (Advanced English I) (2 Cr. Hrs.)Students will focus on English at an Advanced level. Students will analyze and produce 2 – 3 page essays with an emphasis on argumentation and persuasion working both independently and cooperatively to gather, evaluate, and synthesize necessary information. Class activities include interactive lectures, small group and class discussions, informal debates, peer feedback, individual presentations, focused listening exercises and focused viewing exercises as well as assorted reading, writing, and grammar assignments. There will be some poetry analysis together with reading and understanding a short story and a drama using basic literary terms and concepts.

ENGL 202: English VI (Advanced English II) (2 Cr. Hrs.)Students will continue to focus on English at an Advanced level. Students will analyze and produce 4 – 5 page essays emphasizing argumentative, persuasive and discursive styles of writing, working both independently and cooperatively to gather, evaluate, and synthesize necessary information. Students will integrate the practice of critical thinking and reading into the writing process. Class activities include interactive lectures, small group and class discussions, informal debates, mini-conferences, peer feedback, individual presentations, focused listening exercises and focused viewing exercises as well as assorted reading, writing, and grammar assignments. There will be some poetry analysis together with reading and understanding a short story and a drama using stronger and more intensive literary terms and concepts than in 201.

ENRE 431. Renewable Energy Resources Assessment. (3 Cr. Hrs.)Prerequisites: Fundamentals of Energy Systems (ENRE 331), or Departmental approval.A comprehensive overview of renewable energies. Assessment of the viability of a wind power, solar radiation, hydropower or biomass system for a given site. Measurement and data collection techniques. Analyzing and evaluation these renewable energy resources and calculate savings fractions, backup energy needs, financing options, and economic analyses. The principles of solar home design, solar hot water, pool and space heating, and solar cooling for both new and existing construction. The impact of government regulations on the use of renewable energies. Investigation of the potentials of renewable energy technologies to help solve environmental and economic problems within society.

ENRE 436. Energy Management. (3 Cr. Hrs.) Two lectures per week.Prerequisites: Project Management (IE 531), or Departmental approval.Energy management principles; energy conservation; energy auditing; analysis; formulation of energy management options; economic evaluation, implementation & control; energy conservation techniques – conservation in energy intensive industries; steam generation, distribution systems, and electrical systems; integrated resource planning; demand-side management; cogeneration; total energy schemes; thermal insulation; energy storage; economic evaluation of conservation technologies; analysis of typical applications.

GER 101: German I (3Cr. Hrs.)Can understand and use familiar, everyday expressions and very simple sentences, which aim at the satisfaction of specific needs. Can introduce oneself, and others, and ask others questions to themselves - e.g. where they live, which people they know or what kind of things they have - and can give answers on questions of this kind. Can communicate on a basic level if those involved with him/ her in a conversation speak slowly and clearly and are willing to help.

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GER 102: German II (3 Cr. Hrs.)Can understand sentences and frequently used expressions if those are connected with things of immediate meaning (e.g. information to the person and to the family, buying, work, closer environment). Can communicate in simple, routine situations, with the purpose of a simple and direct exchange of information about familiar and common things. Can describe with simple means their own origin and training, direct environment and things that are in connection with direct needs.

GER 201: German III (3 Cr. Hrs.)Can understand the main points if no dialect is used and if it concerns familiar things about work, school, spare time etc. Can master most situations which one encounters on journeys in a German speaking area. Can express oneself simply and coherently about familiar topics and areas of personal interest. Can report experiences and events, describe dreams, hopes and goals and give short reasons or explanations about plans and opinions.

GER 202: German IV (3 Cr. Hrs.)Can understand the main contents of complex texts, as well as concrete and abstract topics; even discussions between specialists in his/ her own special field. Can communicate spontaneously and fluidly a normal discussion with native speakers, without larger effort on both sides. Can express oneself clearly and in detail in a broad spectrum of topics, describe a point of view to a current question and indicate the pro and cons of different possibilities.

GER 301: German V (3 Cr. Hrs.)Can understand and also seize implicit meanings of a broad spectrum of demanding, longer texts. Can express oneself spontaneously and fluidly, recognizing words without having to search for words frequently. Can use the language effectively and flexibly in social and vocational life or in training and study. Can express oneself clearly, structured and detailed, to complex subjects and use appropriate different means for linkage of texts.

IC 101: Intercultural Communication (3 Cr. Hrs.) Two lectures per weekThis course is designed to provide prospective students (whose majors have an international flavor) with tools that offer powerful possibilities for improving the communication process. We will examine the process of sending and receiving messages between people whose cultural background could lead them to interpret verbal and nonverbal signs differently. We will learn about the diversity of these cultural differences and at the same time learn how we might overcome them. Our efforts to recognize and surmount cultural differences will hopefully open up business opportunities throughout the world and maximize the contribution of all the employees in a diverse workforce.

IE 121 Engineering Workshop (1 Cr.) Three hours of laboratory per week.General safety, materials and their classifications, measuring devices and their accuracy, basic household plumbing and electricity, fits and tolerances, theoretical background for the practical exercises including fitting, forging, carpentry, casting, welding, mechanical saws, shearers, drills, lathes, milling machines, shapers and grinders.

IE 353 Engineering Economics (3 Cr.) Two lectures per weekPrerequisites: MATH 201Time value of money, interest formula, depreciation models, tax effects, rate of return, cash flow. project evaluation methods, replacement analysis, break even analysis, economic studies for decision making under risk.

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IE 531 Project Management (3 Cr.) Two lectures per weekPrerequisites: IE 353Examines the organization, planning, and controlling of projects and provides practical knowledge on managing project scope, schedule and resources. Topics include project life cycle, work breakdown structure and Gantt charts, network diagrams, scheduling techniques (CPM and PERT), and resource allocation decisions. Concepts are applied through team projects using project management software.

MATH 101 Calculus I (3 Cr. Hrs.) Two lectures per weekThis course introduces the student to the calculus of single-valued functions. Topics include: limits, continuity, rates of change, rules for differentiating, differentials and local linear approximations, maxima and minima problems, L’Hôpital’s rule, related rates, logarithmic and implicit differentiation, inverse trigonometric and hyperbolic functions, Rolle’s theorem, the mean-value theorem, and applications of derivatives and integrals.

MATH 102 Calculus II (3 Cr. Hrs.) Two lectures per weekThis is a course in multivariate calculus as a continuation of Calculus I. The course focuses on power series, polar coordinates and polar functions, sequences and infinite series, vectors, functions of several variables and their limits, partial differentiation and their applications. The course views multiple integrals: double and triple, line integrals, surface integrals, Green’s theorem, Gauss's divergence theorem, and Stoke’s theorem.

MATH 201 Applied Mathematics for Engineers I (3 Cr. Hrs.) Two lectures per weekThis course begins with an overview of vector analysis, linear algebra concentrating on using matrices to solve systems of equations, and the diagonalization of matrices, and complex numbers. It then moves into a study of differential equations, shedding light on the solutions of differential equations (first order, second and higher orders) with applications. The course will discuss Laplace transforms and Fourier Series and Fourier Transforms with applications in solving initial value problems.

MATH 231: Probability and Statistics for Engineers (3 Cr. Hrs.) Two lectures per week.This course familiarizes students with descriptive statistics, probability basics, random variables, special discrete random variables, and various distributions: normal, Student's t, Chi-square, and Fisher's F. It includes a discussion of inference about one mean, one proportion, difference between two means and difference between two proportions and the ratio of two variances, large and small samples, paired and independent samples. The MINITAB statistical software package will be used; there will also be an introduction to the use of SPSS.

ME 343 Automatic Control Systems: (4 Cr.) Two lectures per weekPrerequisites: MATH 201Modeling of electrical, pneumatic, hydraulic and mechanical systems, Transfer functions, block diagrams, and signal flow graph. Time domain analysis, test signals, transient response, steady state error and stability. Root locus, bode plots, PID control, phase-lead, phase lag. Software application such as Matlab and Simulink.

MILS 100: Military Sciences (3 Cr. Hrs.)History of the Jordanian Arab Army. United Nations Peace Keeping Forces. Preparation of the nation for defense and liberation. History of the Hashemite Kingdom of Jordan and its development.

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NE 101: National Education (3 Cr. Hrs.)In a context of striving towards democracy like the one Jordan enjoys today, the meaning and practice of active and responsible citizenship becomes more crucial. It is often argued that democracy requires “democrats” to flourish, and become well established. Democrats are those women and men who recognize pluralism, inclusion, positive engagement, and participation as the main values that govern their interaction with the state as citizens and with each other as diverse people of different interests. In this course you will be able to understand your rights and responsibilities as Jordanian citizen, expand your knowledge about the frameworks, and processes that regulates citizen-state relationships as will as the basic necessary skills for you to practice your citizenship rights in a civic manner.

PHYS 101 Physics I (Mechanics): (4 Cr. Hrs.)Physics and measurement. Motion in one dimension. Vectors . Motion in two dimensions. Force and motion. Kinetic energy and work. Potential energy and conservation of energy. Linear momentum and collisions. Rotation. Rolling and angular momentum.

PHYS 102 Physics II(Electricity and Magnetism): (4 Cr. Hrs.) Electric Fields. Gauss's Law. Electric Potential. Capacitance and Dielectrics. Current and Resistance. Direct Current Circuits. Magnetic Fields. Sources of Magnetic Field. Faraday's Law.

SE 301: Social Entrepreneurship and Enterprises (3 Cr. Hrs.)This course will serve as an introduction to the field of social entrepreneurship and social enterprises. Through lectures, field visits, analyses of relevant literature, case studies and exercises, this course will explore social entrepreneurship’s potentials, opportunities and limitations.The topics will cover: Defining Social Entrepreneurship. Contextualizing Social Entrepreneurship (need, motives, forms, criteria). Role of Leadership, Creativity and Innovation. Locating SE on the profit/non-profit continuum. SE in the larger fields of development, social change, community activism. Social Enterprises (Missions, Markets, Finances). Ethical business and Corporate social responsibility.

SFTS 101: SOFT SKILLS (3 Cr. Hrs.)This course is designed to help develop strong oral and written communication skills. The student will be given opportunities to practice writing and editing professional correspondence and technical reports. Additionally, the student will compose and deliver oral presentations. Assignments will include the use of inductive and deductive approaches to conveying a variety of messages. The course emphasis the use of software tools to prepare presentations, stress management, confidence, and sensitivity to others. It also stresses on resume writing and conducting interviews.

WEEM 453. Wastewater Engineering. (3 Cr. Hrs.)Prerequisites: Water and Wastewater Treatment (WEEM 351), or Departmental approval.Engineering Hydraulics; Process Science and Engineering; Pumps and Pumping Systems; Water and Wastewater Treatment Principles; Biological Processes; Chemical Processes; Physical Processes. Conservation and Re-Use; Project, Financial and Contract Management; Risk Management and Reliability Engineering for the Utility Sector. Wastewater characterization, collection, and pumping. Physical, chemical and biological treatment unit process design including screening, sedimentation, filtration, activated sludge, disinfection, sludge digestion, and sludge disposal.

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WEEM 473. Emission Control. (3 Cr. Hrs.)Prerequisites: Environmental Quality Control (WEEM 271), or Departmental approval.Air pollution system, Effects of pollutants; engine fundamentals, engine emissions; emissions control techniques; instrumentation and techniques for measuring emissions. This course is an introduction to the fundamental operating characteristics of particulate and gaseous pollutant emission control systems. The course reviews physical, chemical, and engineering principles of control devices and the application of control systems to several types of industrial processes. Also cover principles of gaseous emission control equipment, including scrubbers, afterburners, condensers, and adsorbers. Principles of particulate emission control equipment, including cyclones, fabric filters, electrostatic precipitators, and scrubbers. Application of control equipment to selected industries such as power plants, incinerators, asphalt batch plants, cement plants, and foundries. Methods of hydrocarbon, NOx and Sulfur Oxides (SOx) control.

WEEM 522. Hazardous Waste Management: (3 Cr. Hrs)Prerequisites: Environmental and Water Geology (WEEM 231), or Departmental approval.Types of hazardous waste: medical and industrial hazardous wastes; protocols for handling and disposing of hazardous waste. Siting and design of hazardous waste treatment and disposal facilities. Protection of water resources and the local environment. Social issues related to the siting of hazardous waste facilities.

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