CCOG for MT 228 archive revision 202501

You are viewing an old version of the CCOG. View current version »

Effective Term:
Winter 2025

Course Number:
MT 228
Course Title:
Process Equipment III
Credit Hours:
4
Lecture Hours:
20
Lecture/Lab Hours:
0
Lab Hours:
60

Course Description

Covers a semiconductor processing system. Includes vacuum, gas delivery, robotic and control systems. Focuses on maintenance and troubleshooting.

Addendum to Course Description

MT227 and MT228 cover process equipment as a whole system. The LAM Rainbow etcher system is used as a typical example of a fab process system. Students will learn operations, theory of how various subsystems of the system function, maintenance procedures, and trouble shooting of the etcher. 

Students in this course are expected to be able to carry out independent research in order to discover the components and functions of the etcher system. They are also expected to be able to integrate their knowledge gained in previous courses to gain insights into the etcher system.

Intended Outcomes for the course

Upon completion of the course students should be able to:

  • Apply an understanding of industrial equipment to analyze the functions of highly automated industrial equipment used in semiconductor or other industries. 
  • Troubleshoot basic problems of certain subsystems of highly automated industrial equipment used in semiconductor or other industries following a systematic methodology.

Course Activities and Design

The course will include instructor delivered lectures and demonstrations stressing key topics in the course. Students will perform independent research, preventative maintenance, and trouble-shooting in class. Students may be required to come to the lab after school to work in groups on equipment as a part of homework.

Outcome Assessment Strategies

Assessment of student performance in this course will be in the form of written and/or practice-based questions. Some formal reports and presentations are required also.

Course Content (Themes, Concepts, Issues and Skills)

REQUIRED STUDENT COMPETENCIES:
1.0 Wafer Transfer System Alignment (week1, 2)
1.1 Understand the degrees of freedom a rigid body can have in 3 dimensional space, i.e. displacement freedom along x, y, z axis and rotation around x, y, z axis. Understand the alternative polar coordinate system of r, theta, and height.
1.2 Be able to read and understand conceptually a typical alignment procedure between two components of the wafer transfer system—the sender and the receiver (example: transfer of wafer from cassette indexer to the shuttle arm of the Lam etcher) following the methodology below:
Step1: Identify degrees of freedom the system has.
Step2: Identify in which degrees of freedom, adjustment is necessary.
Step3: Identify what mechanism the equipment uses to adjust alignment in each degree of freedom.
Step4: Find out the order of alignment—which degree of freedom of the system needs to be aligned first, second, …etc.
1.3 Upon reading Lam alignment procedure, be able to organize individual steps into groups to better organize and understand the steps of the procedures. (i.e. step 1-4 may all describe adjustment of height and leveling)
1.4 By reading schematics and by observing the operations of an actual piece of equipment, be able to develop an alignment procedure for the equipment following the methodology above.
1.5 Be able to perform alignment procedures described in the Lam etcher manual.
1.6 While performing the alignment procedure, be able to use observation of relevant indicators as a feed-back to judge whether the alignment is off in certain dimensions.


2.0 Process Chamber (week 3-5)
2.1 Understanding of the components of the process chamber and its subsystems—upper electrodes, lower electrodes*, and the gap drive. (*lower electrode is optional this year)
2.1.3 Describe the function that each component performs.
2.1.4 Describe the major functions of the process chamber. Be able to discover and then describe how the functions of the process chamber as a whole are achieved by the functions of the individual components. The major functions of the process chamber should include: RF delivery, gas delivery, pressure control, temperature control including He cooling and wafer clamping, gap distance control and end point detection.
2.2 Understand how process parameters affect processes which occur during etch, and in turn etch properties (such as etch rate).


3.0 Vacuum System (week 5-6)
3.1 Understanding of the components of the vacuum system
3.1.1 Be able to identify the various components of a subsystem and discern their functions by inspecting and observing the subsystem by eye. Subsystems should include: process chamber, ELL, and XLL.
3.1.2 Be able to draw a schematic of how the various components are linked with each other in a subsystem.
3.1.3 Describe the major functions of a subsystem. Be able to discover and then describe how the functions of the vacuum system as a whole are achieved by the functions of the components. The major functions of the vacuum system should include: venting, purging, pump down, and pressure control.
3.2 Be able to read a flow diagram of the process gas delivery system and discern how gases are flown into the chamber
3.3 Given a diagram, show the valving sequence to get a process gas to flow into the chamber.
3.4 Be able to design the right sequence of events to achieve certain task of the etcher (example, vent ELL manually)


4.0 Trouble-shooting (week 7, 8, 9, 10)
4.1 Be able to form an objective problem statement
4.2 Be able to form a clear mental picture of the entire system involved in the problem
4.3 Be able to design and then carry out quick and definitive tests to isolate the problem to a subsystem.
4.4 Be able to make a list of all possible causes of the problem in this sub-system.
4.5 Be able to design quick and definitive tests to verify whether a possible cause is the true cause or not.
4.6 Be able to prioritize to see which possible causes to check first based on the ease of the check and the probability of the cause
4.7 Be able to gather and use clues to judge which path to follow. (Given the clues, what is the likely cause? Training of this judgment)