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Faculty of Engineering Proposed Calendar Changes Version: November 12, 2015

FACULTY OF ENGINEERING CALENDAR CHANGES 2016-17 84.3 Required Courses and Suggested Course Sequence for Traditional Programs [ … ] Engineering Chart 1 Required Courses and Suggested Course Sequence for Traditional Programs

Current Proposed

[…] Mechanical Traditional: Year 2 Term 3 MATH 209 (3-0-1) STAT 235 (3-0-1.5) CIV E 270 (3-0-3) Course Group 2A CH E 243 (3-1s-0) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0) or Course Group 2B MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) Term 4 ECE 209 (3-0-3/2) MATH 201 (3-0-1) MAT E 202 (3-0-3/2) Course Group 2A CH E 243 (3-1s-0) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0) or Course Group 2B MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3)

[…] Mechanical: Traditional Year 2 Fall Term 3 CIV E 270 (3-0-3) MATH 209 (3-0-1) STAT 235 (3-0-1.5) Course Group 2A CH E 243 (3-1s-0) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0) or Course Group 2B MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) Winter Term 4 ECE 209 (3-0-3/2) MAT E 202 (3-0-3/2) MATH 201 (3-0-1) Course Group 2A CH E 243 (3-1s-0) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0) or Course Group 2B MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3)

Year 3 Term 5 Course Group 3A MATH 300 (3-0-0)

Year 3 Fall Term 5 Course Group 3A MATH 300 (3-0-0)

MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Term 6 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1)

MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Winter Term 6 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1)

Year 4 Term 7 Program Elective (3-0-0) Program Elective (3-0-0) Course Group 4A MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) ENGG 404 (3-3s/2-0) or Course Group 4B MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4)

Year 4 Fall Term 7 Program Elective (3-0-0) Program Elective (3-0-0) Course Group 4A ENGG 404 (3-3s/2-0) MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) or Course Group 4B ITS Elective (3-0-0) MEC E 403 (1-0-3) MEC E 451 (3-0-1)

ITS Elective (3-0-0) Term 8 CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) ENGG 400 (1-0-0) Program Elective (3-0-0) Course Group 4A MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) ENGG 404 (3-3s/2-0) or Course Group 4B MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4) ITS Elective (3-0-0)

MEC E 460 (2-1s-4) Winter Term 8 CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) ENGG 400 (1-0-0) Program Elective (3-0-0) Course Group 4A ENGG 404 (3-3s/2-0) MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) or Course Group 4B ITS Elective (3-0-0) MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4)

Notes [...]

Notes [...]

Current Proposed

[…] Mechanical: Alternate Format Year 2 Fall Term 3 ENG M 310 (3-0-0) or 401 (3-0-0) MATH 209 (3-0-1) MATH 201 (3-0-1) English Elective (3-0-0) ENGG 404 (3-3s/2-0) ITS Elective (3-0-0) Winter Term 4 CIV E 270 (3-0-3) STAT 235 (3-0-1.5) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) Summer Term 5 ECE 209 (3-0-3/2) MAT E 202 (3-0-3/2) CH E 243 (3-1s-0) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0)

[…] Mechanical: Alternate Format Year 2 Fall Term 3 ENG M 310 (3-0-0) or 401 (3-0-0) ENGG 404 (3-3s/2-0) English Elective (3-0-0) ITS Elective (3-0-0) MATH 201 (3-0-1) MATH 209 (3-0-1) Winter Term 4 CIV E 270 (3-0-3) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) STAT 235 (3-0-1.5) Summer Term 5 CH E 243 (3-1s-0) ECE 209 (3-0-3/2) MAT E 202 (3-0-3/2) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0)

Year 3 Fall Term 6 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Program Elective (3-0-0) Winter Term 7 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Program Elective (3-0-0) Summer Term 8 Program Elective (3-0-0) Program Elective (3-0-0) Course Group 4A MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) or Course Group 4B MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4)

Year 3 Fall Term 6 Course Group 3A-alt MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B-alt MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Program Elective (3-0-0) Winter Term 7 Course Group 3A-alt MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B-alt MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Program Elective (3-0-0) Summer Term 8 Program Elective (3-0-0) Program Elective (3-0-0) Course Group 4A-alt MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) or Course Group 4B-alt MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4)

Year 4 Year 4

Fall Term 9 CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) ENGG 400 (1-0-0) Course Group 4A MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) or Course Group 4B MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4)

Fall Term 9 CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) ENGG 400 (1-0-0) Course Group 4A-alt MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) or Course Group 4B-alt MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4)

Notes […] (3) In each term, students take either Group A or Group B then Group B or Group A to complete a year' sequences.

Notes […] (3) In each term of years 3 and 4, students take either Group A-alt then Group B-alt, or Group B-alt then Group A-alt.

84.4 Required Courses and Suggested Course Sequence for Co-op Programs [ … ] Engineering Chart 2 Required Courses and Suggested Course Sequence for Co-op Programs

Current Proposed

[…] Mechanical Plan I Year 2 Fall Term 3 MATH 209 (3-0-1) STAT 235 (3-0-1.5) CIV E 270 (3-0-3) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) Winter Term 4 CH E 243 (3-1s-0) ECE 209 (3-0-3/2) ENGG 299 (1-1s-0) MAT E 202 (3-0-3/2) MATH 201 (3-0-1) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0)

[…] Mechanical Plan I Year 2 Fall Term 3 CIV E 270 (3-0-3) ENGG 299 (1-1s-0) MATH 209 (3-0-1) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) STAT 235 (3-0-1.5) Winter Term 4 CH E 243 (3-1s-0) ECE 209 (3-0-3/2) MAT E 202 (3-0-3/2) MATH 201 (3-0-1) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0)

Summer WKEXP 901

Summer WKEXP 901

Year 3 Fall WKEXP 902 Winter Term 5 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) English Elective (3-0-0) Summer WKEXP 903

Year 3 Fall WKEXP 902 Winter Term 5 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Summer WKEXP 903

Year 4 Fall WKEXP 904 Winter Term 6 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) English Elective (3-0-0) Summer Term 7

Year 4 Fall WKEXP 904 Winter Term 5 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Summer Term 7

Program Elective (3-0-0) Program Elective (3-0-0) MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) ENGG 404 (3-3s/2-0)

ENGG 404 (3-3s/2-0) Program Elective (3-0-0) Program Elective (3-0-0) MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0)

Year 5 Fall WKEXP 905 Winter Term 8 ENGG 400 (1-0-0) CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4) Program Elective (3-0-0) ITS Elective (3-0-0)

Year 5 Fall WKEXP 905 Winter Term 8 CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) ENGG 400 (1-0-0) ITS Elective (3-0-0) MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4) Program Elective (3-0-0)

Notes [...]

Notes [...]

Current Proposed

[…] Mechanical Plan II Year 2 Fall Term 3 CH E 243 (3-1s-0) CIV E 270 (3-0-3) ENGG 299 (1-1s-0) MATH 209 (3-0-1) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0) STAT 235 (3-0-1.5) Winter WKEXP 901 Summer Term 4 ECE 209 (3-0-3/2) MATH 201 (3-0-1) MAT E 202 (3-0-3/2) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3)

[…] Mechanical Plan II Year 2 Fall Term 3 CH E 243 (3-1s-0) CIV E 270 (3-0-3) ENGG 299 (1-1s-0) MATH 209 (3-0-1) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0) STAT 235 (3-0-1.5) Winter WKEXP 901 Summer Term 4 ECE 209 (3-0-3/2) MAT E 202 (3-0-3/2) MATH 201 (3-0-1) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3)

Year 3 Fall Term 5 Course Group 3B

Year 3 Fall Term 5 Course Group 3B

ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Winter WKEXP 902 Summer WKEXP 903

ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Winter WKEXP 902 Summer WKEXP 903

Year 4 Fall Term 6 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-0-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-0-0) Winter WKEXP 904 Summer Term 7 Program Elective (3-0-0) Program Elective (3-0-0) MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4) ITS Elective (3-0-0)

Year 4 Fall Term 6 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) Winter WKEXP 904 Summer Term 7 Program Elective (3-0-0) Program Elective (3-0-0) ITS Elective (3-0-0) MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4)

Year 5 Fall WKEXP 905 Winter Term 8 ENGG 400 (1-0-0) CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) Program Elective (3-0-0) MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) ENGG 404 (3-3s/2-0)

Year 5 Fall WKEXP 905 Winter Term 8 CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) ENGG 400 (1-0-0) ENGG 404 (3-3s/2-0) Program Elective (3-0-0) MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0)

Notes [...]

Notes [...]

Current Proposed

[…] Mechanical Plan III: Biomedical Option Year 2 Fall Term 3 CIV E 270 (3-0-3) MATH 209 (3-0-1) STAT 235 (3-0-1.5) ENGG 299 (1-1s-0) CH E 243 (3-1s-0) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0) Winter Term 4 ECE 209 (3-0-3/2) MATH 201 (3-0-1) MAT E 202 (3-0-3/2) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) Summer WKEXP 902

[…] Mechanical Plan III: Biomedical Option Year 2 Fall Term 3 CIV E 270 (3-0-3) ENGG 299 (1-1s-0) MATH 209 (3-0-1) STAT 235 (3-0-1.5) CH E 243 (3-1s-0) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0) Winter Term 4 ECE 209 (3-0-3/2) MAT E 202 (3-0-3/2) MATH 201 (3-0-1) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) Summer WKEXP 902

Year 3 Fall Term 5 BME 320 (3-0-0) ENG M 310 or 401 (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Winter WKEXP 903 Summer Term 6 MATH 300 (3-0-0) MEC E 300 (3-0-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-0-0)

Year 3 Fall Term 5 BME 320 (3-0-0) ENG M 310 (3-0-0) or 401 (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) Winter WKEXP 903 Summer Term 6 MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0)

Year 4 Fall Term 7 ENGG 404 (3-3s/2-0) English Elective (3-0-0) BME 321 (3-0-0) MEC E 563 (3-0-3) Program Elective (3-0-0)

Year 4 Fall Term 7 BME 321 (3-0-0) ENGG 404 (3-3s/2-0) English Elective (3-0-0) MEC E 563 (3-0-3) Program Elective (3-0-0)

STAT 337 (3-0-2) Winter WKEXP 906 Summer WKEXP 904

STAT 337 (3-0-2) Winter WKEXP 906 Summer WKEXP 904

Year 5 Fall Term 8 ITS Elective (3-0-0) MEC E 430 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) Program Elective (3-0-0) Winter Term 9 CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) ENGG 400 (1-0-0) MEC E 485 (3-0-0) PHIL 386 (3-0-0) MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4)

Year 5 Fall Term 8 ITS Elective (3-0-0) MEC E 430 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) Program Elective (3-0-0) Winter Term 9 CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) ENGG 400 (1-0-0) MEC E 485 (3-0-0) MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4) PHIL 386 (3-0-0)

Notes [...]

Notes [...]

Current Proposed

[…] Mechanical Plan IV Year 2 Fall Term 3 ENGG 299 (1-1s-0) CIV E 270 (3-0-3) MATH 209 (3-0-1) STAT 235 (3-0-1.5) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) Winter ECE 209 (3-0-3/2) CH E 243 (3-1s-0) MATH 201 (3-0-1) MAT E 202 (3-0-3/2) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0)

[…] Mechanical Plan IV Year 2 Fall Term 3 CIV E 270 (3-0-3) ENGG 299 (1-1s-0) MATH 209 (3-0-1) STAT 235 (3-0-1.5) MEC E 230 (3-1s-0) MEC E 260 (2-0-3) MEC E 265 (2-0-3) Winter Term 4 ECE 209 (3-0-3/2) MAT E 202 (3-0-3/2) MATH 201 (3-0-1) CH E 243 (3-1s-0) MEC E 200 (1-2s-0) MEC E 250 (3-1s-0)

Summer Term 4 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) English Elective (3-0-0)

Summer Term 5 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1)

Year 3 Fall WKEXP 901 Winter WKEXP 902 Summer Term 5 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1) English Elective (3-0-0)

Year 3 Fall WKEXP 901 Winter WKEXP 902 Summer Term 6 Course Group 3A MATH 300 (3-0-0) MEC E 300 (3-1s-0) MEC E 301 (1-0-3) MEC E 331 (3-0-1) MEC E 371 (3-1s-0) MEC E 380 (3-1s-0) or Course Group 3B ENG M 310 (3-0-0) or 401 (3-0-0) English Elective (3-0-0) MEC E 340 (3-0-0) MEC E 360 (3-0-3/2) MEC E 362 (3-0-3/2) MEC E 390 (3-0-1)

Year 4 Fall WKEXP 903 Winter WKEXP 904

Year 4 Fall WKEXP 903 Winter WKEXP 904

Summer Term 6 WKEXP 905

Summer WKEXP 905

Year 5 Fall Term 7 Program Elective (3-0-0) Program Elective (3-0-0) MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) ENGG 404 (3-3s/2-0) Winter Term 8 ENGG 400 (1-0-0) CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) Program Elective (3-0-0) MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4) ITS Elective (3-0-0)

Year 5 Fall Term 7 Program Elective (3-0-0) Program Elective (3-0-0) ENGG 404 (3-3s/2-0) MEC E 430 (3-0-0) or 480 (3-0-0) MEC E 463 (3-0-2) Program Elective (3-0-0) Winter Term 8 CH E 448 (3-1s-3/3) or ECE 362 (3-0-3/2) or MEC E 420 (3-0-3/2) ENGG 400 (1-0-0) ITS Elective (3-0-0) MEC E 403 (1-0-3) MEC E 451 (3-0-1) MEC E 460 (2-1s-4) Program Elective (3-0-0)

Notes [...]

Notes [...]

Current Proposed 84.5 Program and Technical Electives […] 84.5.6 Materials […] MAT E 390, 466, 470, 471, 473, 474, 490, 491, 494, 495 […]

84.5 Program and Technical Electives […] 84.5.6 Materials […] MAT E 390, 466, 470, 471, 473, 474, 476, 490, 491, 494, 495 […]

Section 84.6 Complementary Studies Electives

Current

Proposed

List 2 (Second and higher years)

ACCTG 300, 311 ANTHR 230 AREC 365 B LAW 301, 422, 428**, 432 CHRTC 350

List 2 (Second and higher years)

ACCTG 300, 311 ANTHR 230 AREC 365 B LAW 301**, 422, 428***, 432 CHRTC 350

CLASS 254, 255, 294, 376 ECON 204, 281, 282, 355 ENGG 420 ENG M 402, 406 HECOL 211 HIST 260, 261, 396, 397, 398 INT D 257, 303 LA ST 210 LING 204, 205 MARK 301 OM 352 PHIL 205, 220, 250, 265, 325, 366, 375, 380 POL S 220, 221, 223, 266 PSYCO 258, 275 R SOC 355, 365 SMO 200, 301 SOC 212, 224, 225, 241, 242, 251, 301 WGS 201 **Not available to Civil (Environmental Engineering Option) students.

CLASS 254, 255, 294, 376 ECON 204, 281, 282, 355 ENGG 420 ENG M 402, 406 HECOL 211 HIST 260, 261, 396, 397, 398 INT D 257, 303 LA ST 210 LING 204, 205 MARK 301 OM 352 PHIL 205, 220, 250, 265, 325, 366, 375, 380 POL S 220, 221, 223, 266 PSYCO 258, 275 R SOC 355, 365 SMO 200, 301 SOC 212, 224, 225, 241, 242, 251, 301 WGS 201 **Not available to Civil students ***Not available to Civil (Environmental Engineering Option) students.

Courses

231.75 Chemical Engineering, CH E Current Proposed CH E 446 Process Dynamics and Control 4 (fi 8) (either term, 3-1s-3/3). Introduction to process modeling and transient response analysis; design and analysis of feedback systems; stability analysis; process control applications; process control using digital computers. Prerequisites: MATH 201 and 209. Corequisite: CH E 312.

CH E 446 Process Dynamics and Control 4 (fi 8) (either term, 3-1s-3/3). Introduction to process modeling and transient response analysis; design and analysis of feedback systems; stability analysis; process control applications; process control using digital computers. Prerequisites: CME 265, MATH 201 and 209. Corequisite: CH E 312.

CH E 420 Mixing in the Process Industries 3.5 (fi 8) (either term, 3-1s-0). Design and operation of mixing equipment in the process industries. Process results ranging from blending, solids suspension, and gas dispersion to reactor design and heat transfer will be covered. Emphasis is on application of the fundamentals of chemical engineering. Laminar and turbulent regimes, stirred tanks and static mixers, and other specialized applications will be discussed. Credit cannot be obtained in this course if credit has already been obtained in CH E 520. Corequisite: CH E 464.

CH E 420 Mixing in the Process Industries 3.5 (fi 8) (either term or Spring/Summer, 3-1s-0). Design and operation of mixing equipment in the process industries. Process results ranging from blending, solids suspension, and gas dispersion to reactor design and heat transfer will be covered. Emphasis is on application of the fundamentals of chemical engineering. Laminar and turbulent regimes, stirred tanks and static mixers, and other specialized applications will be discussed. Credit cannot be obtained in this course if credit has already been obtained in CH E 520. Corequisite: CH E 464.

CH E 484 Introduction to Biochemical Engineering 3.5 (fi 8) (either term, 3-0-1). Physical and chemical

CH E 484 Introduction to Biochemical Engineering 3.5 (fi 8) (either term or Spring/Summer, 3-0-1).

properties of cells, tissues, and biological fluids, engineering analysis or processes such as cell growth and fermentation, purification of products. Prerequisites: CME 265 or BIOL 107, Credit may not be obtained in this course if previous credit has been obtained for CH E 390.

Physical and chemical properties of cells, tissues, and biological fluids, engineering analysis or processes such as cell growth and fermentation, purification of products. Prerequisites: CME 265 or BIOL 107, Credit may not be obtained in this course if previous credit has been obtained for CH E 390.

CH E 485 Fuel Cells and Their Applications 3 (fi 8) (either term, 3-0-0). Introduction to principles of operation of fuel cells and their applications; historical and environmental perspectives; elementary electrochemistry, types of fuel cell - fuels, membranes and liquid ion conductors, operating conditions; factors affecting performance; applications as standing engines and mobile power sources. Limited to 3rd/4th year undergraduate students in engineering. Prerequisites: CH E 343, MAT E 202 or equivalent and MATH 201 or consent of Instructor.

CH E 485 Fuel Cells and Their Applications 3 (fi 8) (either term or Spring/Summer, 3-0-0). Introduction to principles of operation of fuel cells and their applications; historical and environmental perspectives; elementary electrochemistry, types of fuel cell - fuels, membranes and liquid ion conductors, operating conditions; factors affecting performance; applications as standing engines and mobile power sources. Limited to 3rd/4th year undergraduate students in engineering. Prerequisites: CH E 343, MAT E 202 or equivalent and MATH 201 or consent of Instructor.

CH E 584 Molecular Sieve Technology 3.5 (fi 6) (either term, 3-1s-0). Structures and properties of molecular sieves and related materials. Applications of molecular sieves in separation processes based on molecular size differences as well as thermodynamic interactions between active surfaces and adsorbates. Molecular sieves in purification processes based on cationic exchange reactions and selective adsorption. Molecular sieves as catalysts. Prerequisites: CHEM 105 and CH E 243.

CH E 584 Molecular Sieve Technology 3.5 (fi 6) (either term or Spring/Summer, 3-1s-0). Structures and properties of molecular sieves and related materials. Applications of molecular sieves in separation processes based on molecular size differences as well as thermodynamic interactions between active surfaces and adsorbates. Molecular sieves in purification processes based on cationic exchange reactions and selective adsorption. Molecular sieves as catalysts. Prerequisites: CHEM 105 and CH E 243.

CH E 610 Computational Transport Phenomena 3 (fi 6) (either term, 3-0-0). Solutions of the transport equations of momentum, mass and energy. Transport processes are reviewed but emphasis is placed on the numerical solution of the governing differential equations. Different solution methodologies and software are presented.

CH E 610 Computational Transport Phenomena 3 (fi 6) (either term or Spring/Summer, 3-0-0). Solutions of the transport equations of momentum, mass and energy. Transport processes are reviewed but emphasis is placed on the numerical solution of the governing differential equations. Different solution methodologies and software are presented.

CH E 611 Advanced Transport Phenomena 3 (fi 6) (either term, 3-0-0). Transport expressions for physical properties are combined with conservation laws to yield generalized equations used to solve a variety of engineering problems in fluid mechanics, and heat and mass transfer; steady-state and transient cases; special topics in non-Newtonian flow and forced diffusion.

CH E 611 Advanced Transport Phenomena 3 (fi 6) (either term or Spring/Summer, 3-0-0). Transport expressions for physical properties are combined with conservation laws to yield generalized equations used to solve a variety of engineering problems in fluid mechanics, and heat and mass transfer; steady-state and transient cases; special topics in non-Newtonian flow and forced diffusion.

CH E 612 Advanced Fluid Mechanics 3 (fi 6) (either term, 3-0-0). Potential, boundary layer, viscometrics, and secondary flows; application to multiphase phenomena.

CH E 612 Advanced Fluid Mechanics 3 (fi 6) (either term or Spring/Summer, 3-0-0). Potential, boundary layer, viscometrics, and secondary flows; application to multiphase phenomena.

CH E 617 Colloids and Interfaces 3 (fi 6) (either term, 3-0-0). Emphasis is on the basics of colloid and interfacial phenomena. Aimed at

CH E 617 Colloids and Interfaces 3 (fi 6) (either term or Spring/Summer, 3-0-0). Emphasis is on the basics of colloid and interfacial

upper level and graduate students in chemical and mineral engineering, chemistry and geochemistry with an interest in application to the energy sector, mineral processing, materials handling, and chemical industry.

phenomena. Aimed at upper level and graduate students in chemical and mineral engineering, chemistry and geochemistry with an interest in application to the energy sector, mineral processing, materials handling, and chemical industry.

CH E 620 Mixing in the Process Industries 3.5 (fi 6) (either term, 3-1s-0). Design and operation of mixing equipment in the process industries. Process results ranging from blending, solids suspension, and gas dispersion to reactor design and heat transfer will be covered. Laminar and turbulent regimes, stirred tanks and static mixers, and other specialized applications will be discussed. The course integrates fundamental chemical engineering concepts with equipment design, mixing theory, and turbulence theory. Credit cannot be obtained in this course if credit was previously obtained in CH E 420 or CH E 520.

CH E 620 Mixing in the Process Industries 3.5 (fi 6) (either term or Spring/Summer, 3-1s-0). Design and operation of mixing equipment in the process industries. Process results ranging from blending, solids suspension, and gas dispersion to reactor design and heat transfer will be covered. Laminar and turbulent regimes, stirred tanks and static mixers, and other specialized applications will be discussed. The course integrates fundamental chemical engineering concepts with equipment design, mixing theory, and turbulence theory. Credit cannot be obtained in this course if credit was previously obtained in CH E 420 or CH E 520.

CH E 624 Advanced Thermodynamics 3 (fi 6) (first term, 3-0-0). Principles of thermodynamics; properties of homogeneous fluid phases; phase and chemical equilibria; application to industrial problems.

CH E 624 Advanced Thermodynamics 3 (fi 6) (either term or Spring/Summer, 3-0-0). Principles of thermodynamics; properties of homogeneous fluid phases; phase and chemical equilibria; application to industrial problems.

CH E 625 Advanced Macroscopic and Statistical Thermodynamics 3 (fi 6) (either term, 3-0-0). Advanced topics in macroscopic thermodynamics and fundamentals of statistical thermodynamics. Thermodynamics of composite systems including surface thermodynamics and thermodynamics in fields. Introduction to quantum mechanics. Principles of statistical thermodynamics. Construction of partition functions and calculations of basic thermodynamic properties for several fundamental systems. Applications will include properties of ideal gases, ideal solids and adsorbed gases.

CH E 625 Advanced Macroscopic and Statistical Thermodynamics 3 (fi 6) (either term or Spring/Summer, 3-0-0). Advanced topics in macroscopic thermodynamics and fundamentals of statistical thermodynamics. Thermodynamics of composite systems including surface thermodynamics and thermodynamics in fields. Introduction to quantum mechanics. Principles of statistical thermodynamics. Construction of partition functions and calculations of basic thermodynamic properties for several fundamental systems. Applications will include properties of ideal gases, ideal solids and adsorbed gases.

CH E 634 Advanced Chemical Reactor Design 3 (fi 6) (either term, 3-0-0). Design of homogeneous and heterogeneous reactors for isothermal and non-isothermal operation; analysis of rate data; transport processes in heterogeneous catalytic systems.

CH E 634 Advanced Chemical Reactor Design 3 (fi 6) (either term or Spring/Summer, 3-0-0). Design of homogeneous and heterogeneous reactors for isothermal and non-isothermal operation; analysis of rate data; transport processes in heterogeneous catalytic systems.

CH E 645 Heterogeneous Catalysis and Reactor Analysis 3 (fi 6) (either term, 3-0-0). Principles of heterogeneous catalysis and reactor analysis with emphasis on industrial catalytic reactions; characterization of heterogeneous catalysts.

CH E 645 Heterogeneous Catalysis and Reactor Analysis 3 (fi 6) (either term or Spring/Summer, 3-0-0). Principles of heterogeneous catalysis and reactor analysis with emphasis on industrial catalytic reactions; characterization of heterogeneous catalysts.

CH E 655 Advanced Biomaterials Science 3 (fi 6) (either term, 3-0-0). Intended for graduate students who are familiar with basic biomaterials

CH E 655 Advanced Biomaterials Science 3 (fi 6) (either term or Spring/Summer, 3-0-0). Intended for graduate students who are familiar with

science. Focuses on: molecular design of biomaterial and biomaterial surfaces in order to modulate specific biological events; techniques to modulate biomaterial properties; assessment techniques for modifications. The biological events will be studied at the cellular and molecular level.

basic biomaterials science. Focuses on: molecular design of biomaterial and biomaterial surfaces in order to modulate specific biological events; techniques to modulate biomaterial properties; assessment techniques for modifications. The biological events will be studied at the cellular and molecular level.

CH E 662 Process Identification 3.8 (fi 6) (either term, 3-0-3/2). Selected topics related to empirical modelling of process systems are undertaken. Emphasis on time-series based modelling theory and techniques, (e.g., nonparametric, parametric, spectrum analysis, nonlinear, and closed-loop identification methods), model validation, experimental design, and applications in forecasting, analysis, and control.

CH E 662 Process Identification 3.8 (fi 6) (either term or Spring/Summer, 3-0-3/2). Selected topics related to empirical modelling of process systems are undertaken. Emphasis on time-series based modelling theory and techniques, (e.g., nonparametric, parametric, spectrum analysis, nonlinear, and closed-loop identification methods), model validation, experimental design, and applications in forecasting, analysis, and control.

CH E 689 Polymer Properties 3 (fi 6) (either term, 3-0-0). Polymerization, molar mass distributions, polymer analytical techniques, solution and blend thermodynamics, physical and chemical properties of polymers, lattice models, rubber thermodynamics, polymer processing, fluid flow and heat transfer in melt processing, special polymer project. Prerequisite: consent of Instructor. Not open to students with credit in MAT E 467 or CH E 539.

CH E 689 Polymer Properties 3 (fi 6) (either term or Spring/Summer, 3-0-0). Polymerization, molar mass distributions, polymer analytical techniques, solution and blend thermodynamics, physical and chemical properties of polymers, lattice models, rubber thermodynamics, polymer processing, fluid flow and heat transfer in melt processing, special polymer project. Prerequisite: consent of Instructor. Not open to students with credit in MAT E 467 or CH E 539.

CH E 694 Advanced Topics in Chemical Engineering 3 (fi 6) (either term, 3-0-0). An advanced treatment of selected chemical engineering topics of current interest to staff and students.

CH E 694 Advanced Topics in Chemical Engineering 3 (fi 6) (either term or Spring/Summer, 3-0-0). An advanced treatment of selected chemical engineering topics of current interest to staff and students.

CH E 696 Special Topics in Process Dynamics and Control 3 (fi 6) (either term, 3-0-0). Advanced treatment of selected topics in process dynamics and/or computer process control of current interest to staff and students.

CH E 696 Special Topics in Process Dynamics and Control 3 (fi 6) (either term or Spring/Summer, 3-0-0). Advanced treatment of selected topics in process dynamics and/or computer process control of current interest to staff and students.

231.119 Engineering, General, ENGG Current Proposed ENGG 400 The Practice of the Engineering Profession (fi 3) (second term, 1-0-0). The technical and professional duties and responsibilities of the engineer; the ethics of the engineering profession; technical and professional organizations. The role of the engineer in the social environment including elements of equity, concepts of sustainable development and environmental stewardship, public and worker safety and health considerations

ENGG 400 The Practice of the Engineering Profession (fi 3) (Either term, 1-0-0). The technical and professional duties and responsibilities of the engineer; the ethics of the engineering profession; technical and professional organizations. The role of the engineer in the social environment including elements of equity, concepts of sustainable development and environmental stewardship, public and worker safety and health considerations

including the context of the Alberta Occupational Health and Safety Act. Note: Restricted to fourth-year traditional and fifth-year co-op engineering students.

including the context of the Alberta Occupational Health and Safety Act. Note: Restricted to fourth-year traditional and fifth-year co-op engineering students. Must be taken in last term of program.

231.175 Materials Engineering, MAT E Current Proposed MAT E 466 Special Topics in Materials Engineering 3 (fi 8) (either term, 3-0-0). An advanced treatment of selected Materials Engineering topics of current interest. Prerequisite: Consent of Department.

MAT E 466 Special Topics in Materials Engineering 3 (fi 8) (either term or Spring/Summer, 3-0-0). An advanced treatment of selected Materials Engineering topics of current interest. Prerequisite: Consent of Department.

MAT E 470 Process Dynamics 3.5 (fi 8) (either term, 3-1s-0). The study of diffusion, mass transfer and reaction kinetics in materials process engineering. The fundamental equations governing mass transfer are applied to study the rate of metallurgical processes. The use of dimensional analysis in scale-up of reactors and mixing in batch and continuous processes is also presented. Credit may not be obtained in this course if previous credit has been obtained in MAT E 440. Prerequisites: MAT E 301 and CH E 312. Corequisite: CH E 314.

MAT E 470 Process Dynamics 3.5 (fi 8) (either term or Spring/Summer, 3-1s-0). The study of diffusion, mass transfer and reaction kinetics in materials process engineering. The fundamental equations governing mass transfer are applied to study the rate of metallurgical processes. The use of dimensional analysis in scale-up of reactors and mixing in batch and continuous processes is also presented. Credit may not be obtained in this course if previous credit has been obtained in MAT E 440. Prerequisites: MAT E 301 and CH E 312. Corequisite: CH E 314.

MAT E 471 Ceramics 3 (fi 8) (first term, 3-0-0). Structure, processing, characterization, properties and application of ceramic materials and glass. Ceramic raw materials. Crystal chemistry and physics. Glassy state. Crystal defects, nonstoichiometry, diffusion, phase diagrams. Powder preparation, ceramic fabrication. Characterization of ceramic powders and components. Thermal, mechanical and electrical properties. Traditional and recent applications. Credit may not be obtained in this course if previous credit has been obtained in MAT E 480. Prerequisites: MAT E 221, 341 or consent of Instructor.

MAT E 471 Ceramics 3 (fi 8) (either term or Spring/Summer, 3-0-0). Structure, processing, characterization, properties and application of ceramic materials and glass. Ceramic raw materials. Crystal chemistry and physics. Glassy state. Crystal defects, nonstoichiometry, diffusion, phase diagrams. Powder preparation, ceramic fabrication. Characterization of ceramic powders and components. Thermal, mechanical and electrical properties. Traditional and recent applications. Credit may not be obtained in this course if previous credit has been obtained in MAT E 480. Prerequisites: MAT E 221, 341 or consent of Instructor.

MAT E 474 Performance of Materials 3.5 (fi 8) (either term, 3-1s-0). Behaviour of materials in service, such as corrosion and oxidation, wear and tribology, failure analysis and surface engineering. Case studies will be used to illustrate principles. Prerequisites: MAT E 336 and 341.

MAT E 474 Performance of Materials 3.5 (fi 8) (either term or Spring/Summer, 3-1s-0). Behaviour of materials in service, such as corrosion and oxidation, wear and tribology, failure analysis and surface engineering. Case studies will be used to illustrate principles. Prerequisites: MAT E 336 and 341.

MAT E 476 Microalloyed Steels 3 (fi 8) (second term, 3-0-0). The physical metallurgy and processing of microalloyed steels and the associated microstructure/processing/property

MAT E 476 Microalloyed Steels 3 (fi 8) (either term or Spring/Summer, 3-0-0). The physical metallurgy and processing of microalloyed steels and the associated

relationship. Usage of microalloyed steels in pipelines including design, forming and welding. Credit cannot be obtained in this course if previous credit has been obtained in MAT E 489. Prerequisite: consent of Instructor.

microstructure/processing/property relationship. Usage of microalloyed steels in pipelines including design, forming and welding. Credit cannot be obtained in this course if previous credit has been obtained in MAT E 489. Prerequisite: consent of Instructor.

MAT E 491 Functional Properties 3.5 (fi 8) (either term, 3-1s-0). Semiconductors and dielectric materials, piezoelectrics and thermoelectrics, magnetic and superconducting materials. Semiconductors, doping, p-n junctions, solar cells. Low and high Tc superconducting materials, processing and properties. Thermoelectric materials and Seebeck, Thomson, and Peltier effects. Prerequisite: MAT E 390 or MAT E 490.

MAT E 491 Functional Properties 3.5 (fi 8) (either term or Spring/Summer, 3-1s-0). Semiconductors and dielectric materials, piezoelectrics and thermoelectrics, magnetic and superconducting materials. Semiconductors, doping, p-n junctions, solar cells. Low and high Tc superconducting materials, processing and properties. Thermoelectric materials and Seebeck, Thomson, and Peltier effects. Prerequisite: MAT E 390 or MAT E 490.

MAT E 494 Nanostructured Materials 3.8 (fi 8) (second term, 3-0-3/2). Fabrication and application of 1D, 2D, and 3D nanostructured materials. Nanoparticles, carbon nanotubes, graphene, thin films, and nanocomposites. Optical, electrical, and mechanical properties and characterization techniques. Co-requisite: MAT E 390 or 490.

MAT E 494 Nanostructured Materials 3.8 (fi 8) (either term or Spring/Summer, 3-0-3/2). Fabrication and application of 1D, 2D, and 3D nanostructured materials. Nanoparticles, carbon nanotubes, graphene, thin films, and nanocomposites. Optical, electrical, and mechanical properties and characterization techniques. Co-requisite: MAT E 390 or 490.

MAT E 495 Nanomaterials and Biomedical Applications 3.5 (fi 8) (either term, 3-1s-0). Survey of nanostructured materials, including processing techniques, properties (mechanical, physical and chemical), characterization, and characterization tools. Introduction to biomedical applications of nanomaterials for diagnosis, therapy and medical implants. Credit may not be obtained in this course if previous credit has been obtained in MAT E 458. Prerequisite: CH E 243 or equivalent, or consent of instructor

MAT E 495 Nanomaterials and Biomedical Applications 3.5 (fi 8) (either term or Spring/Summer, 3-1s-0). Survey of nanostructured materials, including processing techniques, properties (mechanical, physical and chemical), characterization, and characterization tools. Introduction to biomedical applications of nanomaterials for diagnosis, therapy and medical implants. Credit may not be obtained in this course if previous credit has been obtained in MAT E 458. Prerequisite: CH E 243 or equivalent, or consent of instructor

MAT E 630 Special Topics in Process Metallurgy 3 (fi 6) (either term, 3-0-0). Topics of current interest related to process metallurgy, such as welding, process analysis, mathematical modelling and simulation, metal extraction from secondary sources, iron and steel making, physical chemistry of molten systems and production of industrial minerals.

MAT E 630 Special Topics in Process Metallurgy 3 (fi 6) (either term or Spring/Summer, 3-0-0). Topics of current interest related to process metallurgy, such as welding, process analysis, mathematical modelling and simulation, metal extraction from secondary sources, iron and steel making, physical chemistry of molten systems and production of industrial minerals.

MAT E 633 Surface Chemistry in Minerals and Materials Processing 5 (fi 6) (either term, 3-1s-3). Fundamentals of surface and interfacial phenomena; physical chemistry of surfaces and interfaces; surface and interface energy and their origin; wetting, adhesion and surface forces in material processing; role and mechanisms of surfactant adsorption and self-

MAT E 633 Surface Chemistry in Minerals and Materials Processing 5 (fi 6) (either term or Spring/Summer, 3-1s-3). Fundamentals of surface and interfacial phenomena; physical chemistry of surfaces and interfaces; surface and interface energy and their origin; wetting, adhesion and surface forces in material processing; role and mechanisms of surfactant adsorption and

assembly in materials engineering; techniques for surfacant adsorption and self-assembly in materials engineering; techniques for surface characterization. The course includes an experimental research project of 3 hours per week.

self-assembly in materials engineering; techniques for surfacant adsorption and self-assembly in materials engineering; techniques for surface characterization. The course includes an experimental research project of 3 hours per week.

MAT E 640 Advanced Materials Thermodynamics 3 (fi 6) (either term, 3-0-0). Advanced topics in core fundamentals of materials thermodynamics. Thermodynamic laws, statistical thermodynamics, reaction equilibria, phase diagrams, solutions, changing standard states, electrochemistry, and thermodynamics of surfaces. Prerequisite: MAT E 301 or consent of Instructor.

MAT E 640 Advanced Materials Thermodynamics 3 (fi 6) (either term or Spring/Summer, 3-0-0). Advanced topics in core fundamentals of materials thermodynamics. Thermodynamic laws, statistical thermodynamics, reaction equilibria, phase diagrams, solutions, changing standard states, electrochemistry, and thermodynamics of surfaces. Prerequisite: MAT E 301 or consent of Instructor.

MAT E 645 Electrochemical Processes 3 (fi 6) (either term, 3-0-0). Aqueous, molten and solid electrolytes: thermodynamics, structure, transport properties. Applications of conductivity measurements. Electrodes: types, reactions, potential. Electrochemical cells. Applications of EMF measurements. Electrical double layer, electrode kinetics, overpotential. Chlor-alkali industry, electrometallurgy, electrolysis of water, electroplating. Electrochemical energy conversion: primary and secondary batteries, fuel cells. High temperature applications. Prerequisite: Consent of Instructor.

MAT E 645 Electrochemical Processes 3 (fi 6) (either term or Spring/Summer, 3-0-0). Aqueous, molten and solid electrolytes: thermodynamics, structure, transport properties. Applications of conductivity measurements. Electrodes: types, reactions, potential. Electrochemical cells. Applications of EMF measurements. Electrical double layer, electrode kinetics, overpotential. Chlor-alkali industry, electrometallurgy, electrolysis of water, electroplating. Electrochemical energy conversion: primary and secondary batteries, fuel cells. High temperature applications. Prerequisite: Consent of Instructor.

MAT E 653 Stress Corrosion Cracking 3 (fi 6) (either term, 3-0-0). The role of corrodents, stresses and microstructure in the phenomena of stress corrosion cracking; dissolution models and mechanical models proposed as mechanisms. Stress corrosion of high-strength steels, stainless steels and the principal nonferrous metals. Stress corrosion testing and methods of preventing stress corrosion cracking. Prerequisite: MAT E 345 or consent of instructor.

MAT E 653 Stress Corrosion Cracking 3 (fi 6) (either term or Spring/Summer, 3-0-0). The role of corrodents, stresses and microstructure in the phenomena of stress corrosion cracking; dissolution models and mechanical models proposed as mechanisms. Stress corrosion of high-strength steels, stainless steels and the principal nonferrous metals. Stress corrosion testing and methods of preventing stress corrosion cracking. Prerequisite: MAT E 345 or consent of instructor.

MAT E 654 Electrochemical Theory of Corrosion 3 (fi 6) (either term, 3-0-0). Principles and applications of electrochemical corrosion theory in basic and applied research. Equilibrium thermodynamics and electrode kinetics. Passivation and breakdown of passivity. The study of galvanic corrosion; alloy evaluation. Corrosion testing methods and electrochemical measurement of corrosion rates. Prerequisite: MAT E 345 or consent of Instructor.

MAT E 654 Electrochemical Theory of Corrosion 3 (fi 6) (either term or Spring/Summer, 3-0-0). Principles and applications of electrochemical corrosion theory in basic and applied research. Equilibrium thermodynamics and electrode kinetics. Passivation and breakdown of passivity. The study of galvanic corrosion; alloy evaluation. Corrosion testing methods and electrochemical measurement of corrosion rates. Prerequisite: MAT E 345 or consent of Instructor.

MAT E 662 Fracture of Materials 3 (fi 6) (either term, 3-0-0). Theoretical strength of solids, Griffith crack theory, mechanisms of brittle and ductile fracture, the ductile to brittle transition, fatigue and creep fracture, environmental effects on

MAT E 662 Fracture of Materials 3 (fi 6) (either term or Spring/Summer, 3-0-0). Theoretical strength of solids, Griffith crack theory, mechanisms of brittle and ductile fracture, the ductile to brittle transition, fatigue and creep fracture,

fracture. Prerequisites: MAT E 358 or consent of Instructor. Credit cannot be obtained in this course if credit has already been obtained in MAT E 462.

environmental effects on fracture. Prerequisites: MAT E 358 or consent of Instructor. Credit cannot be obtained in this course if credit has already been obtained in MAT E 462.

MAT E 664 Diffusion and Diffusion-Controlled Processes in Metallurgy and Materials 3 (fi 6) (either term, 3-0-0). Fundamentals of diffusion, diffusion in dilute alloys, diffusion in a concentration gradient, diffusion in non-metals, high diffusivity paths, thermal diffusion. Applications to materials: sintering, superplasticity, creep, metal oxides and non-stoichiometry.

MAT E 664 Diffusion and Diffusion-Controlled Processes in Metallurgy and Materials 3 (fi 6) (either term or Spring/Summer, 3-0-0). Fundamentals of diffusion, diffusion in dilute alloys, diffusion in a concentration gradient, diffusion in non-metals, high diffusivity paths, thermal diffusion. Applications to materials: sintering, superplasticity, creep, metal oxides and non-stoichiometry.

MAT E 665 Materials Applications of Transmission Electron Microscopy 4.5 (fi 6) (either term, 3-0-3). Fundamental principles of electron scattering and of the transmission electron microscope, space group theory and application to crystal structure determination, electron diffraction theory, crystallography of precipitation and of defects, TEM imaging theory and application to materials analysis, analytical electron spectrometry. Prerequisite: Graduate student standing or consent of Instructor.

MAT E 665 Materials Applications of Transmission Electron Microscopy 4.5 (fi 6) (either term or Spring/Summer, 3-0-3). Fundamental principles of electron scattering and of the transmission electron microscope, space group theory and application to crystal structure determination, electron diffraction theory, crystallography of precipitation and of defects, TEM imaging theory and application to materials analysis, analytical electron spectrometry. Prerequisite: Graduate student standing or consent of Instructor.

MAT E 666 Materials Applications of Scanning Electron Microscopy 3 (fi 6) (either term, 3-0-0). Principles and design of the scanning electron microscope, electron beam-specimen interactions, image formation, x-ray microanalysis in the scanning electron microscope, specimen preparation, application to materials analysis. Prerequisite: Consent of Instructor.

MAT E 666 Materials Applications of Scanning Electron Microscopy 3 (fi 6) (either term or Spring/Summer, 3-0-0). Principles and design of the scanning electron microscope, electron beam-specimen interactions, image formation, x-ray microanalysis in the scanning electron microscope, specimen preparation, application to materials analysis. Prerequisite: Consent of Instructor.

MAT E 669 Nano Functional Materials 3 (fi 6) (either term, 3-0-0). Band theory and solid state properties. Thin film growth at the nanoscale. Semiconductors and dielectric materials, piezlectrics and thermoelectrics. Semiconductors, doping, p-n junctions, solar cells. Thermoelectric materials and the Seebeck, Thomson, and Peltier Effects. Optical and electrical property measurement.

MAT E 669 Nano Functional Materials 3 (fi 6) (either term or Spring/Summer, 3-0-0). Band theory and solid state properties. Thin film growth at the nanoscale. Semiconductors and dielectric materials, piezlectrics and thermoelectrics. Semiconductors, doping, p-n junctions, solar cells. Thermoelectric materials and the Seebeck, Thomson, and Peltier Effects. Optical and electrical property measurement.

MAT E 673 Welding Metallurgy 3 (fi 6) (either term, 3-0-0). Weld thermal cycles; fusion zone solidification; phase transformations, heat affected zone phenomena; cracking during welding; ferrous and non-ferrous weldments.

MAT E 673 Welding Metallurgy 3 (fi 6) (either term or Spring/Summer, 3-0-0). Weld thermal cycles; fusion zone solidification; phase transformations, heat affected zone phenomena; cracking during welding; ferrous and non-ferrous weldments.

MAT E 680 Advanced Ceramics 3 (fi 6) (either term, 3-0-0). Important ceramic materials and products, processing, typical properties. Structure: binary and ternary compounds, crystalline silicates, glass. Point defects,

MAT E 680 Advanced Ceramics 3 (fi 6) (either term or Spring/Summer, 3-0-0). Important ceramic materials and products, processing, typical properties. Structure: binary and ternary compounds, crystalline silicates, glass. Point

nonstoichiometry, defect reactions, dislocations. Diffusion electrochemical transport, examples. Thermal and mechanical properties, thermal shock resistance, electrical conduction. Applications: solid electrolytes, energy conversion systems, refractories, electronics. Prerequisites: Consent of Instructor. Credit cannot be obtained in this course if credit has already been obtained in MAT E 471.

defects, nonstoichiometry, defect reactions, dislocations. Diffusion electrochemical transport, examples. Thermal and mechanical properties, thermal shock resistance, electrical conduction. Applications: solid electrolytes, energy conversion systems, refractories, electronics. Prerequisites: Consent of Instructor. Credit cannot be obtained in this course if credit has already been obtained in MAT E 471.

MAT E 689 Advanced Processing of Microalloyed Steels 3.5 (fi 6) (either term, 3-1s-0). Advanced processing and metallurgy of microalloyed steels for pipelines. Steelmaking, casting, microstructural development during thermomechanical processing, pipe fabrication, mechanical and chemical properties and in service performance. Prerequisites: Consent of Instructor.

MAT E 689 Advanced Processing of Microalloyed Steels 3.5 (fi 6) (either term or Spring/Summer, 3-1s-0). Advanced processing and metallurgy of microalloyed steels for pipelines. Steelmaking, casting, microstructural development during thermomechanical processing, pipe fabrication, mechanical and chemical properties and in service performance. Prerequisites: Consent of Instructor.

MAT E 694 Advanced Topics in Materials Engineering 3 (fi 6) (either term, 3-0-0). An advanced treatment of materials engineering topics of current interest to staff and students.

MAT E 694 Advanced Topics in Materials Engineering 3 (fi 6) (either term or Spring/Summer, 3-0-0). An advanced treatment of materials engineering topics of current interest to staff and students.

MAT E 738 Process Metallurgy 3 (fi 6) (either term, 3-0-0).

MAT E 738 Process Metallurgy 3 (fi 6) (either term or Spring/Summer, 3-0-0).

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