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Transport Cheme 530 Homework 3 Solution

UW Bothell Course Descriptions UW Tacoma Course Descriptions  | Glossary

COLLEGE OF ENGINEERING
CHEMICAL ENGINEERING

Detailed course offerings (Time Schedule) are available for

  • Autumn Quarter 2021
  • Winter Quarter 2022

CHEM E 299 Undergraduate Research (1-3, max. 9)
Research or special topics under the supervision of a faculty member. Offered: AWSpS.
View course details in MyPlan: CHEM E 299

CHEM E 301 Leadership Seminar (1) Schwartz
Forum for industrial, academic, and government leaders to share their experiences and insights with students. Includes topics related to leadership in the chemical engineering profession including career planning, management skills, interpersonal skills, effective planning, entrepreneurship, ethics, and strategic decisions. Credit/no-credit only. Offered: A.
View course details in MyPlan: CHEM E 301

CHEM E 309 Creativity and Innovation (2) VLPA G. ALLAN
Understanding creativity and creative thinking; its challenges and dynamics through knowledge, judgment, planning, and observation. Techniques of creative thinking. Design and development of creative games. Computer-aided creative thinking. Creation, protection, and exploitation of a useful idea, including bargaining and negotiations. Offered: jointly with BSE 309; Sp.
View course details in MyPlan: CHEM E 309

CHEM E 310 Material and Energy Balances (4)
Chemical and physical process calculations: steady- and unsteady-state material and energy balances with specific examples in vapor-liquid contact operations and multiphase extraction, and introductory thermochemistry. Prerequisite: either PHYS 122 or PHYS 142; and MATH 207. Offered: Sp.
View course details in MyPlan: CHEM E 310

CHEM E 325 Energy and Entropy (4)
Introduction to the basic principles of thermodynamics from both microscopic and macroscopic points of view. Emphasis on equilibrium phenomena, and the trade-off of energy and disorder in determining structure and properties. Applications of thermodynamics in process design and analysis. Prerequisite: CHEM E 310. Offered: A.
View course details in MyPlan: CHEM E 325

CHEM E 326 Chemical Engineering Thermodynamics (4)
Phase equilibria and chemical equilibria in multicomponent systems; theories of solution; chemical reaction analysis. Prerequisite: CHEM E 325. Offered: W.
View course details in MyPlan: CHEM E 326

CHEM E 330 Transport Processes I (5)
Diffusive transport of momentum, heat, and mass; general aspects of fluid flow; the Navier-Stokes equations; one-dimensional flow with engineering applications. Prerequisite: CHEM E 310; and either MATH 136 or MATH 207. Offered: A.
View course details in MyPlan: CHEM E 330

CHEM E 340 Transport Processes II (4)
Heat transfer, basic principles, and applications. Conduction, convection, and radiation. Prerequisite: CHEM E 330. Offered: W.
View course details in MyPlan: CHEM E 340

CHEM E 341 Energy and Environment (3) NW
Energy use. Fossil energy conversion. Oil, gas, coal resources. Air impacts. Nuclear energy principles, reactors, fuel cycle. Prerequisite: either MATH 112, MATH 124, MATH 134, or Q SCI 291; either CHEM 120, CHEM 142, CHEM 143, CHEM 145, PHYS 114, PHYS 121, or PHYS 141. Offered: jointly with ENVIR 341/M E 341; A.
View course details in MyPlan: CHEM E 341

CHEM E 355 Biological Frameworks for Engineers (3)
For engineers with no prior experience in the biological sciences. Hands-on, project-based course covers fundamental concepts and language of biology, from an engineering perspective. Topics include functions of life, information processing, proteins, DNA, genetic variability, control loops, energetics, tissues, organisms, ecosystems. Prerequisite: either CHEM 142 or CHEM 145; and either MATH 124 or MATH 134. Offered: W.
View course details in MyPlan: CHEM E 355

CHEM E 375 Chemical Enginering Computer Skills (2) Pfaendtner
Use Excell, Matlab, and AspenPlus to solve typical chemical engineering problems. Solve realistic problems and explore alternatives that would be inaccessible for hand calculations. Includes equations of state, chemical equilibrium of simultaneous reactions, phase equilibria, plug flow reactors, heat transfer in 1-D, and time-dependent heat transfer. Offered: W.
View course details in MyPlan: CHEM E 375

CHEM E 434 Physiological Processes in Engineering Nanomedicine (3) Elizabeth Nance
Provides an understanding of the physiological principles that influence the use of nanoscale systems in the human body. Prerequisite: CHEM E 330; recommended: BIOEN 490/CHEME 490; NME 221; NME 321; and NME 421. Offered: Sp.
View course details in MyPlan: CHEM E 434

CHEM E 435 Transport Processes III (4)
Mass transfer, basic principles, and applications to equipment design. Physical separation processes. Prerequisite: CHEM E 326; CHEM E 340. Offered: A.
View course details in MyPlan: CHEM E 435

CHEM E 436 Chemical Engineering Laboratory I (3)
Lectures on statistics, experimental design, instrumentation, laboratory safety, and report writing; laboratory experiments on fluid mechanics and heat transfer. Emphasis on teaming, experimental planning, procedures, report writing, and oral presentations. Prerequisite: CHEM E 326; CHEM E 340 which may be taken concurrently; HCDE 231. Offered: ASp.
View course details in MyPlan: CHEM E 436

CHEM E 437 Chemical Engineering Laboratory II (3)
Continuation of CHEM E 436. Laboratory investigation of chemical engineering principles applied to equipment design with emphasis on mass transfer operations and chemical reactors. Prerequisite: CHEM E 435; CHEM E 436; CHEM E 465. Offered: W.
View course details in MyPlan: CHEM E 437

CHEM E 440 Energy Materials, Devices, and Systems (3)
Provides project based training for synthesis & characterization of new energy materials, for generation and storage, and the integration of renewables into energy systems using instruments at the Clean Energy Research Training Testbed. Topics include nanoparticle synthesis, solar cells, impedance analysis, characterization with solar simulator, coin cell battery assembly & testing, photochemistry, semiconductor w/ 2D materials, grid simulation Prerequisite: either PHYS 431, E E 421, MSE 311, MSE 312, MSE 313, MSE 351, MSE 352, CHEM E 456, CHEM 455, or CHEM 475, any of which may be taken concurrently. Offered: jointly with CHEM 466/MSE 466; A.
View course details in MyPlan: CHEM E 440

CHEM E 442 Renewable Energy (4) NW Philip C Malte
Introduction to renewable energy. Principles and practices: solar, wind, water, and biomass energy conversion. Prerequisite: either M E 323, CHEM E 325, A A 260, or E E 351. Offered: jointly with M E 442; W.
View course details in MyPlan: CHEM E 442

CHEM E 445 Fuel Cell Engineering (3)
Introduction to electrochemical fuel cells for use in transportation and stationary power applications. Topics covered include types of fuel cells, single cell operation, stack engineering, overall system design, and safety, with emphasis on proton exchange membrane and solid oxide fuel cells. Prerequisite: CHEM E 330. Instructors: Stuve
View course details in MyPlan: CHEM E 445

CHEM E 455 Surface and Colloid Science Laboratory (3) Berg, Pozzo
Laboratory techniques, equipment, and underlying fundamentals in surface and colloid science. Experiments in the measurement of surface tension, adsorption, wetting and spreading, colloid properties, emulsion preparation and stability, electrophoresis, and interfacial hydrodynamics. Offered: ASp.
View course details in MyPlan: CHEM E 455

CHEM E 457 Principles of Molecular Engineering (3)
Covers the basic aspects of statistical mechanics, focusing primarily on the canonical ensemble. Develops and applies a set of tools to regular liquid solutions, phase formation, spinodal decomposition, adsorption, polymer thermodynamics, chemical kinetics, and physical kinetics. Prerequisite: CHEM E 310; CHEM E 325; CHEM 455. Instructors: Hillhouse Offered: Sp.
View course details in MyPlan: CHEM E 457

CHEM E 458 Surface Analysis (3)
Understanding of solid surfaces for research and development in microelectronics, catalysis, adhesion, biomaterials, science wear, and corrosion science. Newer methods available to study surfaces of materials. Electron emission spectroscopies (ESCA, Auger): ion scattering, ion spectroscopic, photon spectroscopic, and thermodynamic methods. Offered: jointly with BIOEN 492; Sp.
View course details in MyPlan: CHEM E 458

CHEM E 460 Polymer chemistry Laboratory (3) C. DEFOREST
Laboratory techniques, equipment, and underlying fundamentals in polymer chemistry, synthesis, and design. Quantitative understanding of polymerization reaction engineering will be developed through careful examination of kinetics and structure-property relationships. Selection of laboratory polymerization and characterization techniques, as well as recent innovations in polymer research, will be highlighted. Prerequisite: CHEM 238. Offered: Sp.
View course details in MyPlan: CHEM E 460

CHEM E 461 Electrochemical Engineering (3) Schwartz
Explores role of thermodynamics, charge transfer kinetics, and mass transfer on behavior of electrochemical systems. Includes cell thermodynamics, faradaic and non-faradaic rate processes, ionic transport, nucleation and growth theories. Applications to chemical sensors, batteries, corrosion, thin film deposition. In-class demonstrations to illustrate concepts.
View course details in MyPlan: CHEM E 461

CHEM E 465 Reactor Design (4)
Application of chemical kinetics and transport phenomena to the design of chemical reactors; characterization of batch and continuous-flow reactors in homogeneous and heterogeneous systems. Prerequisite: CHEM E 326; CHEM E 340. Offered: A.
View course details in MyPlan: CHEM E 465

CHEM E 467 Biochemical Engineering (3) F. BANEYX
Application of basic chemical engineering principles to biochemical and biological process industries such as fermentation, enzyme technology, and biological waste treatment. Rapid overview of relevant microbiology, biochemistry, and molecular genetics. Design and analysis of biological reactors and product recovery operations. Prerequisite: CHEM E 340; either CHEM 223, CHEM 237, or CHEM 335. Offered: jointly with BIOEN 467; W.
View course details in MyPlan: CHEM E 467

CHEM E 480 Process Dynamics and Control (4)
Dynamics of process units and systems; instrumentation and control system design and analysis. Includes weekly laboratory. Prerequisite: CHEM E 435; CHEM E 465. Offered: W.
View course details in MyPlan: CHEM E 480

CHEM E 481 Process Optimization (3) Holt
Concepts and techniques of optimizing chemical engineering processes and systems, including classical and direct methods of search, linear and nonlinear programming, dynamic programming, statistical experimental design, and evolutionary operation. Offered: A.
View course details in MyPlan: CHEM E 481

CHEM E 482 Advanced Topics in Process Control (3)
Current topics in process control design and analysis. Possible topics include robustness analysis and design, time delay compensation, modern frequency response techniques, discrete control, adaptive control, model-based control, and nonlinear control. Prerequisite: CHEM E 480. Instructors: Holt, Ricker
View course details in MyPlan: CHEM E 482

CHEM E 484 Electronic and Optoelectronic Polymers (3)
Covers the chemistry, physics, materials science, and engineering applications of semiconducting and metallic conjugated polymers. Examines the structural origins of the diverse electronic and optoelectronic properties of conjugated polymers. Exemplifies applications by light-emitting diodes, lasers, solar cells, thin film transistors, electrochromic devices, biosensors, and batteries. Prerequisite: either CHEM 237, CHEM 455, CHEM E 340, or MSE 310. Instructors: Jenekhe Offered: A.
View course details in MyPlan: CHEM E 484

CHEM E 485 Process Design I (4)
Applied economics in chemical engineering design and operations; measures of profitability; capital and operating cost estimates; introduction to design and design strategies. Prerequisite: CHEM E 480 which may be taken concurrently. Offered: W.
View course details in MyPlan: CHEM E 485

CHEM E 486 Process Design II (5)
Comprehensive design of a specific process or product, including economic feasibility studies, utilization of market survey and plant location studies, process equipment design and optimization, and overall plant integration and layout. Prerequisite: CHEM E 485. Offered: Sp.
View course details in MyPlan: CHEM E 486

CHEM E 490 Engineering Materials for Biomedical Applications (3) J. Bryers
Combined application of principles of physical chemistry and biochemistry, materials engineering, to biomedical problems and products. Applications include implants and medical devices, drug delivery systems, cell culture processes, diagnostics, and bioseparations. Offered: jointly with BIOEN 490; A.
View course details in MyPlan: CHEM E 490

CHEM E 491 Controlled-Release Systems (3) S. PUN
Mechanisms for controlled release of active agents and the development of useful drug delivery systems for this purpose. Release mechanisms considered include diffusive, convective, and erosive driving forces. Delivery routes include topical, oral, and in vivo. Some special case studies covered in detail. Offered: jointly with BIOEN 491; W.
View course details in MyPlan: CHEM E 491

CHEM E 493 Advanced Surface Analysis (3)
Covers the latest advanced in surface analysis instrumentation and methodology, including advanced methods of biorecognition AFM, surface Plasmon resonance, x-ray photoelectron spectroscopy, sum frequency generation spectroscopy, time-of-flight secondary ion mass spectrometry, and multivariate analysis. Prerequisite: either CHEM E 458 or BIOEN 492. Offered: jointly with BIOEN 493; W.
View course details in MyPlan: CHEM E 493

CHEM E 497 Special Projects in Chemical Engineering Design ([1-6]-, max. 12)
Chemical engineering design instruction and experience in special projects, such as industrially motivated, timely, or interdisciplinary projects. Project subject and content varies. Majors only. Prerequisite: CHEM E 340.
View course details in MyPlan: CHEM E 497

CHEM E 498 Special Topics in Chemical Engineering (1-4, max. 12)
Topics of current interest in the field. Subject matter changes from quarter to quarter.
View course details in MyPlan: CHEM E 498

CHEM E 499 Undergraduate Research ([1-6]-, max. 12)
Independent research projects in chemical engineering. Offered: AWSpS.
View course details in MyPlan: CHEM E 499

CHEM E 510 Mathematical Foundations of Systems Theory (4)
Mathematical foundations for system theory presented from an engineering viewpoint. Includes set theory; functions, inverse functions; metric spaces; finite dimensional linear spaces; linear operators on finite dimensional spaces; projections on Hilbert spaces. Applications to engineering systems stressed. Offered: jointly with A A 510/E E 510/M E 510.
View course details in MyPlan: CHEM E 510

CHEM E 511 Biomaterials Seminar (1, max. 18) Lara J. Gamble
Presentation of student research results. Prerequisite: permission of instructor. Credit/no-credit only. Offered: jointly with BIOEN 511.
View course details in MyPlan: CHEM E 511

CHEM E 512 Methods of Engineering Analysis (3)
Applications of mathematics to problems in chemical engineering; vector calculus; properties and methods of solution of first and second order partial differential equations; similarity transforms, separation of variables, Laplace and Fourier transforms. Prerequisite: MATH 208; either MATH 207 or AMATH 351; and MATH 224, or permission of instructor. Offered: A.
View course details in MyPlan: CHEM E 512

CHEM E 514 Advanced Chemical Engineering Laboratory (3) Q. YU
Instrumentation and laboratory techniques for chemical, biological, clean energy, and nano technologies. Experiments include surface modification, this film formation, nanoparticle synthesis, micro/nanoscale fabrication, protein adsorption, microorganism identification, and photovoltaic device fabrication/evaluation using advanced instrumentation. Offered: W.
View course details in MyPlan: CHEM E 514

CHEM E 515 Experimental Methods in Chemical Engineering Research (3) Baneyx, Berg, Jiang
Lecture and laboratory studies in current research methods of chemical engineering. Includes surface science, biochemical engineering, collodial chemistry, light scattering, and nanoscience techniques. Offered: A.
View course details in MyPlan: CHEM E 515

CHEM E 523 Seminar in Chemical Engineering (0-1, max. 30)
Topics of current interest in chemical engineering. Credit/no-credit only. Offered: AWSp.
View course details in MyPlan: CHEM E 523

CHEM E 525 Chemical Engineering Thermodynamics (4)
Review of principles of thermodynamics. Applications to problems in multiphase and multicomponent systems; theories of solutions. Prerequisite: undergraduate thermodynamics. Offered: A.
View course details in MyPlan: CHEM E 525

CHEM E 530 Momentum, Heat, and Mass Transfer I (4)
Derivation of the differential equations for mass, energy, and momentum transport. Principles of fluid mechanics; creeping flow, turbulence, boundary-layer theory. Offered: A.
View course details in MyPlan: CHEM E 530

CHEM E 531 Momentum, Heat, and Mass Transfer II (3)
Continuation of CHEM E 530. Flows of fluid-particle systems; convective heat transfer, natural convection. Prerequisite: CHEM E 530.
View course details in MyPlan: CHEM E 531

CHEM E 534 Physiological Processes in Engineering Nanomedicine (3) Elizabeth Nance
Provides an understanding of the physiological principles that influence the use of nanoscale systems in the human body. Prerequisite: either CHEM E 330, or related fluid mechanics course; and introductory biology course. ; recommended: BIOEN 490/CHEME 490; NME 221; NME 321; and NME 421. Offered: Sp.
View course details in MyPlan: CHEM E 534

CHEM E 535 Nanomaterials Chemistry and Engineering (3) Vincent C Holmberg
Rigorous overview of fundamental chemical and physical concepts important to nanomaterials science and engineering. Focus on luminescent, plasmonic, magnetic nanomaterials. Students will learn basic concepts prevalent in the nanomaterials literature, and develop rigorous mathematical understanding of fundamental principles that govern many of the advanced materials that are currently under development in the field. Prerequisite: CHEM 455; MATH 207; and CHEM E 326; recommended: classical physics, quantum mechanics, thermodynamics, and ordinary and partial differential equations Offered: jointly with CHEM 587; Sp.
View course details in MyPlan: CHEM E 535

CHEM E 540 Energy Materials, Devices, and Systems (3)
Provides project based training for synthesis & characterization of new energy materials, for generation and storage, and the integration of renewables into energy systems using instruments at the Clean Energy Research Training Testbed. Topics include nanoparticle synthesis, solar cells, impedance analysis, characterization with solar simulator, coin cell battery assembly & testing, photochemistry, semiconductor w/ 2D materials, grid simulation Offered: jointly with CHEM 566/MSE 566; A.
View course details in MyPlan: CHEM E 540

CHEM E 545 Data Science Methods for Clean Energy Research (3) Jim Pfaendtner
Survey of modern data science methods taught in the context of materials for clean energy (e.g., batteries and solar energy). Covers data visualization, statistics, machine learning and data management. Instruction, homework and term project are implemented using Python. Offered: jointly with CHEM 545/MSE 545; W.
View course details in MyPlan: CHEM E 545

CHEM E 546 Software Engineering for Molecular Data Scientists (3) Jim Pfaendtner
Introduces basic principles of scientific software development in the Python in the context of Molecular Data Science. The course covers command line tools, Python from the perspective of molecular data science methods, software development and collaboration principles, e.g. version control. Grades are based on homework and group projects. Offered: jointly with CHEM 546/MSE 546; W.
View course details in MyPlan: CHEM E 546

CHEM E 547 Data Science Capstone Project (3) David A. C. Beck
Involves teams of graduate students from molecular, materials or clean energy focused disciplines working on Data Science oriented research and engineering projects solicited from internal and external partners. Employ modern team-based software engineering principles and cutting edge Data Science methods, including but not limited to machine learning, statistics, visualization and data management. Prerequisite: CHEM E 545 and CHEM E 546; recommended: prior exposure to data science fundamentals and software development. Offered: jointly with CHEM 547/MSE 547; Sp.
View course details in MyPlan: CHEM E 547

CHEM E 554 Nanoscale Science I: Contact Mechanics and Rheology on the Nanoscale (3) Overney
Introductory nanoscale science with emphasis on contact mechanics, principle and concept of forces, scanning force microscopy, tribology (friction, wear, lubrication), rheology, ultrathin organic films, physical properties of polymers, and computer simulation. Offered: W.
View course details in MyPlan: CHEM E 554

CHEM E 556 Colloidal Systems (3) Berg, Pozzo
Examines the unique properties and application of colloidal materials, i.e., dispersions of micro- or nano-sized particles in various media are described. Explores their inherent instability, and their kinetic, phoretic, electric, optical, and rheological properties. Offered: W.
View course details in MyPlan: CHEM E 556

CHEM E 558 Surface Analysis (3)
Understanding of solid surfaces for research and development in microelectronics, catalysis, adhesion, biomaterials science, wear and corrosion science. Newer methods available to study surfaces of materials. Electron emission spectroscopies (ESCA, Auger); ion scattering, ion spectroscopic, photon spectroscopic, and thermodynamic methods. Offered: jointly with BIOEN 592.
View course details in MyPlan: CHEM E 558

CHEM E 560 Reactions at Solid Surfaces (3)
Fundamental studies of adsorption and reactions on metallic and non-metallic surfaces with emphasis on heterogeneous catalysis and electrochemistry, including fuel cells. Topics include gas phase and liquid phase surface reactions, analyzed both experimentally and computationally. Prerequisite: undergraduate level course in kinetics or catalysis. Instructors: Stuve
View course details in MyPlan: CHEM E 560

CHEM E 565 Kinetics and Catalysis (3)
Homogeneous and heterogeneous systems with emphasis on chemical engineering principles applied to industrial reactor design. Prerequisite: CHEM E 525. Instructors: Stuve
View course details in MyPlan: CHEM E 565

CHEM E 580 Topics in Chemical Engineering Design (3, max. 9)
Lectures and seminars on current design methods in chemical engineering, including technical and economic feasibility of processes, design and optimization of process equipment, and environmental and social constraints. Prerequisite: undergraduate chemical engineering design, admission to chemical engineering master's program, or permission of instructor.
View course details in MyPlan: CHEM E 580

CHEM E 584 Electronic and Optoelectronic Polymers (3)
Covers the chemistry, physics, materials science, and engineering applications of semiconducting and metallic conjugated polymers. Examines the structural origins of the diverse electronic and optoelectronic properties of conjugated polymers. Exemplifies applications by light-emitting diodes, lasers, solar cells, thin film transistors, electrochromic devices, biosensors, and batteries. Prerequisite: either CHEM 237, CHEM 455, CHEM E 340, or MSE 310. Instructors: Jenekhe Offered: A.
View course details in MyPlan: CHEM E 584

CHEM E 588 Research in Applied Microbiology (1, max. 30)
Weekly research seminar and discussion of scientific literature pertaining to applied microbiology. Prerequisite: permission of instructor. Instructors: Lidstrom Credit/no-credit only. Offered: jointly with MICROM 588; AWSpS.
View course details in MyPlan: CHEM E 588

CHEM E 590 Advanced Topics in Biomaterials (3)
Major, controversial issues in application of synthetic materials to medical problems. Blood compatibility, bioadhesion, intraocular lenses, contact lenses, polyurethanes, biodegradation, protein adsorption, corrosion, bone fixation, new materials, artificial heart, medical device regulation. Prerequisite: BIOEN 490 or CHEM E 490. Offered: jointly with BIOEN 590.
View course details in MyPlan: CHEM E 590

CHEM E 591 Robotics and Control Systems Colloquium (1, max. 30)
Colloquium on current topics in robotics and control systems analysis and design. Topics presented by invited speakers as well as on-campus speakers. Emphasis on the cross-disciplinary nature of robotics and control systems. Credit/no-credit only. Offered: jointly with A A 591/E E 591/M E 591.
View course details in MyPlan: CHEM E 591

CHEM E 593 Advanced Surface Analysis (3)
Covers the latest advanced in surface analysis instrumentation and methodology, including advanced methods of biorecognition AFM, surface Plasmon resonance, x-ray photoelectron spectroscopy, sum frequency generation spectroscopy, time-of-flight secondary ion mass spectrometry, and multivariate analysis. Prerequisite: either CHEM E 558 or BIOEN 592. Offered: jointly with BIOEN 593; W.
View course details in MyPlan: CHEM E 593

CHEM E 599 Current Topics in Chemical Engineering (1-5, max. 12)
Readings or lectures and discussions of topics of current interest in the field of chemical engineering. Subject matter changes from year to year. Prerequisite: permission of instructor.
View course details in MyPlan: CHEM E 599

CHEM E 600 Independent Study or Research (*-)
Offered: AWSpS.
View course details in MyPlan: CHEM E 600

CHEM E 700 Master's Thesis (*-)
Offered: AWSpS.
View course details in MyPlan: CHEM E 700

CHEM E 800 Doctoral Dissertation (*-)
Offered: AWSpS.
View course details in MyPlan: CHEM E 800

Transport Cheme 530 Homework 3 Solution

Source: https://www.washington.edu/students/crscat/cheng.html