Semiconductors Technology

Course 857 Optical Lithography

Dr. Uzodinma Okoroanyanwu is teaching this 4-day course on Optical Lithography. Optical lithography, also called photolithography, can be described as a printing technology that eminently illustrates the perfect marriage between chemistry and optics. This is a technology that uses photons to induce chemical reactions in photoresist films (the image recording medium) and results in the transformation of the exposed part of the photoresist film relative to the unexposed part. Light/photoresist interactions lead to photochemical reactions and photophysical processes that underlie the contrast between the exposed and unexposed region of the film, and this is manifested as the latent image. This lithographic image contrast forms the basis of the printed image and underlies the usage of optical lithographic printing in transferring to the photoresist-coated wafer surface geometric patterns representing integrated circuit (IC) design information on a photomask. Other interesting attributes of optical lithography include the potential for image reduction using projection optics, use of transmission or reflective photomasks, and extremely high capacity for image information transfer on the order of terapixels per exposure shot for the latest advanced exposure tools, which makes for high throughput and high patterning fidelity. This course examines at both introductory and advanced levels the physical and chemical basis of optical lithography.

Available course dates

This course has no planned course dates.

If you are interested in this course, contact us at cei@cei.se

TECHNOLOGY FOCUS

The IC design imperatives for high performance, low power consumption, and small form factors mandate increasing the number of metallization layers in IC devices. Some advanced IC chips today have more than 11 metallization levels that are fabricated in over 300 sequenced processing steps. At the heart of these processing steps lies semiconductor lithography (of which optical lithography is the most dominant form), for it determines and sets the design rule for each technology node. Each layer is defined by a geometric pattern representing circuit design information that must be transferred to the wafer surface to realize the integrated circuit. Semiconductor lithography is the process that transfers to the wafer surface the mask information for each layer of the IC. The optical lithographic exposure wavelengths span the range from 436 nm, 405 nm, 365 nm, 248 nm, 193 nm, to 13.5 nm (EUV). EUV lithography is the most advanced lithographic technology and is in production today at the 3 nm technology node in leading edge Fabs.

Instructor

Dr. Uzodinma Okoroanyanwu

COURSE CONTENT

This course is divided into two main sections: fundamentals of optical lithography and advanced topics in optical lithography. The fundamentals of optical lithography section is divided into six modules, including optical lithography and its role in IC manufacturing, optical lithographic image formation, optical lithographic resist materials chemistry, practical optical lithographic resist processing, reflectivity and control, and lift-off resist pattern transfer. The advanced topics of optical lithography section is in two modules and covers materials on aberrations, low-k₁ lithography, polarization and high numerical aperture effects, as well as EUV lithography. On a practical level, the course will cover exposure systems, operational principles and theories that underpin the various optical lithographic technologies; strategies, processes, and materials used in their operations; their unique features, strengths, and limitations; and specific applications to which they are targeted. Additionally, status, technical challenges, scaling, and future trends of optical lithographic technologies in general will be covered.

WHO SHOULD ATTEND

This course is intended for scientists, engineers, and technicians who wish to expand their knowledge of optical lithography.

Daily Schedule

DAY 1 – Fundamentals of optical lithography
Module 1 Optical lithography and its role in integrated circuit device manufacturing

Principles of optical projection lithography
Elements of optical lithography – exposure tools and systems (design considerations & properties), masks, resists
Optical lithography in IC device manufacture
Optical lithography roadmap and state-of-the-art today

Module 2 – Optical lithographic image formation

Definitions – resolution, depth of focus, numerical aperture (NA)
Diffraction & Huygen’s principle
Image formation in a projection system
The aerial image & its quality metrics

DAY 2 – Fundamentals of optical lithography, cont’d.
Module 3. Optical lithographic resist materials chemistry

Overview
Image recording in optical resist film
Optical lithographic imaging mechanisms
Resist materials platforms

Module 4. Practical optical lithographic resist processing

Process flow
Lithographic process control – contrast curves, focus-exposure matrix, Bossung plots
Planarization
Advanced resist processing
Select applications of optical lithographic resists

Module 5. Reflectivity and control

Overview
CD control over topography
Reflectivity control
Top surface imaging

Module 6. Lift-off Resist Pattern Transfer

Overview of lift-off pattern transfer process
Lift-off pattern transfer versus other pattern transfer approaches
Positive resist lift-off process
Negative resist lift-off process

DAY 3 – Advanced topics in optical lithography
Module 7 – Aberrations, low-k₁ lithography, polarization & high-NA effects

Optical aberrations & their effects on lithographic imaging
Low-k₁ lithography
Optical proximity effects (OPE) & optical proximity correction (OPC)
Off axis illumination (OAI)
Patterning issues & their resolutions

DAY 4 – Advanced topics in optical lithography, cont’d.
Module 8 – EUV lithography

Overview
EUVL exposure system
EUVL sources
EUVL masks
EUV resist materials and processing
EUVL patterning performance & challenges
EUV scaling and extendibility

ALL COURSE DATES FOR THE CATEGORY: Semiconductors Technology

Semiconductors Technology

035 Introduction to Semiconductor Packaging Technology

Location: Barcelona, Spain Date: April 13 - April 15, 2026 Duration: 3 days

Instructor: Dr. Jeffrey Gambino This advanced 3-day course will provide a high-level overview of the packaging options for semiconductor devices. The course covers design considerations, packaging materials, assembly processes, yield, and reliability. The course is addressed to a broad audience and is not intended as a research review, although it will be taught at a high level and in many areas will require familiarity with the subject matter. Read full course description including course schedule.

Early Bird

2 280,00 €2 535,00 €

Early Bird Price Ends: February 13, 2026

Semiconductors Technology

036 Silicon Device Technology: Materials and Processing Overview

Location: Amersfoort, The Netherlands Date: May 18 - May 22, 2026 Duration: 5 days

Instructor: Dr. Jeffrey Gambino This advanced 5-day course is taught by Dr. Jeffrey Gambino, ON Semiconductor, United States which will provide an high-level overview of the entire fabrication process of modern Silicon-Based Integrated Circuits. This course includes all the key materials involved and the process areas utilized in device manufacturing. The course is addressed to a broad audience and is not intended as a research review, although it will be taught at a high level and in many areas will require familiarity with the subject matter. Read full course description including course schedule

Early Bird

3 540,00 €3 935,00 €

Early Bird Price Ends: March 18, 2026

Semiconductors Technology

037 Power Semiconductor Device Technology

Location: Gothenburg, Sweden Date: June 22 - June 24, 2026 Duration: 3 days

Instructor: Dr. Jeffrey Gambino This 3-day course includes all the key materials involved and the process areas utilized in device manufacturing, including the starting wafers, device design, wafer fab processes, assembly processes, yield, and reliability. The course is addressed to a broad audience and is not intended as a research review, although it will be taught at a high level and in many areas will require familiarity with the subject matter. Read full course description including course schedule

Early Bird

2 280,00 €2 535,00 €

Early Bird Price Ends: April 22, 2026

Semiconductors Technology

075 Heterogeneous integration of chiplets – Defect inspection, metrology and failure analysis

Location: Amersfoort, The Netherlands Date: May 18 - May 20, 2026 Duration: 3 days

Instructor: Dr. Ehrenfried Zschech Expand your knowledge of the processing, materials, performance, and reliability aspects of heterogeneous integration of chiplets. Let Professor Zschech guide you all the way from 3D advanced packaging technologies through fault isolation and failure analysis up to the kinetics of degradation processes and reliability challenges. This course will include novel aspects of high-performance computing and AI applications that are driving the demand for increased functionality, performance, and reliability. Read full course description including course schedule.

Early Bird

2 280,00 €2 535,00 €

Early Bird Price Ends: March 18, 2026

Semiconductors Technology

088 Plasma Etching for CMOS Technology and ULSI Applications

Location: Gothenburg, Sweden Date: June 22 - June 25, 2026 Duration: 4 days

Instructor: Dr. Maxime Darnon This course is intended to provide an understanding of plasma processes for CMOS applications and ULSI technology. We will discuss fundamental and practical aspects of front end and back end plasma processes for deep submicron CMOS logic processes. The course is based on experimental results obtained using commercial etchers connected to very powerful diagnostics of the plasma and the plasma surface interaction. The discussions cover several aspects of etch processes of materials integrated in advanced CMOS devices, etch mechanisms, and situations that may be encountered for some important plasma processes. Option 2: Take the short Ecourse #089 Plasma Etching for Microelectronics Applications. Combining self-paced e-learning with live weekly sessions with the instructor. Duration in total is two weeks of effective learning. Content based on the first two days of the public course #088. Option 3: Take the full Ecourse #090 Plasma Etching for Microelectronics Applications: from Fundamental to Practical Applications. Combining self-paced e-learning with live weekly sessions with the instructor. Duration in total is four weeks of effective learning. Content based on complete agenda of the public course #088. Read full course description including course schedule

Early Bird

2 940,00 €3 265,00 €

Early Bird Price Ends: April 22, 2026

Semiconductors Technology

099 Integrated Circuit and MEMS Fabrication Technologies

Location: Gothenburg, Sweden Date: June 22 - June 26, 2026 Duration: 5 days

Instructor: Dr. Henk van Zeijl This 5-day course on Integrated Circuit and MEMS Fabrication Technologies. This course offers a comprehensive introduction to the core fabrication technologies behind Integrated Circuits (ICs) and Microelectromechanical Systems (MEMS)—two pillars of modern microelectronic systems. Participants will explore how foundational technologies like doping, photolithography, etching, and thin-film deposition converge to create the devices that power everything from smartphones to spacecraft.

Designed to bridge the gap between device physics and electronic characteristics, the course examines the intricate process flows of CMOS manufacturing and MEMS fabrication, highlighting how these technologies are integrated in real-world applications. A detailed discussion of 3D micromachining techniques further reveals the power of MEMS in creating multifunctional microsystems.

What You’ll Learn

The basic physical principles of microelectronic devices
Key IC fabrication technologies and how they shape device behavior
Silicon bulk and surface micromachining for MEMS fabrication
Complete CMOS process flow and technology integration challenges
The evolution and ecosystem of modern microfabrication

Read full course description including course schedule

Early Bird

3 540,00 €3 935,00 €

Early Bird Price Ends: April 22, 2026

Semiconductors Technology

855 Semiconductor Lithography

Location: Gothenburg, Sweden Date: June 22 - June 24, 2026 Duration: 3 days

Instructor: Dr. Uzodinma Okoroanyanwu

This 3-day course will give an overview of semiconductor lithographic technologies, comprising optical, extreme ultraviolet, electron beam, and ion beam lithography in terms of their exposure systems, operational principles and theories that underpin them; strategies, processes, and materials used in their operations; their unique features, strengths, and limitations; and specific applications to which they are targeted. Also covered in the course are status, technical challenges, scaling, and future trends of semiconductor lithographic technologies in general.

Dr. Okoroanyanwu is also teaching the 2-day course 856 Alternative Lithography . If booking both these courses in the same week, the total course fee will be EUR 3540 pp (Early Bird) or EUR 3935 (regular fee).

Early Bird

2 280,00 €2 535,00 €

Early Bird Price Ends: April 22, 2026

Semiconductors Technology

856 Alternative Lithography

Location: Gothenburg, Sweden Date: June 25 - June 26, 2026 Duration: 2 days

Instructor: Dr. Uzodinma Okoroanyanwu

This is a 2-day course, which gives an overview of alternative lithographic technologies, including imprint lithography; colloidal particle self-assembly, self-assembling monolayer, and directed block copolymer self-assembly lithography; scanning (proximal) probe lithography based on scanning tunneling microscopy, scanning atomic force microscopy; stereolithography, and interference lithography. Emphasis will be on each alternative lithographic technique’s tool systems, operational principles and theories that underpin their operation; strategies, processes, and materials used in their operations; their unique features, strengths, and limitations; and specific applications to which they are targeted. Also covered in the course are status, technical challenges, scaling, and future trends of alternative lithographic technologies in general.

Dr. Okoroanyanwu is also teaching the 3-day course 855 Semiconductor Lithography If booking both these courses in the same week, the total course fee will be EUR 3540 pp (Early Bird) or EUR 3935 (Regular fee).

Early Bird

1 560,00 €1 735,00 €

Early Bird Price Ends: April 22, 2026

Semiconductors Technology

880 Wafer Fab Process Technology

Location: Gothenburg, Sweden Date: June 22 - 25, 2026 Duration: 4 days

Instructor: Mr. Jim Fraser This intensive 4-day course provides a broad overview of silicon wafer fab processing, with in-depth consideration of each of the many wafer fab process techniques – and associated materials and equipment – used to manufacture today’s broad range of Si-based microchips. Read full course description including course schedule.

Early Bird

2 940,00 €3 265,00 €

Early Bird Price Ends: April 22, 2026

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Tagged Course, Dr. Uzodinma Okoroanyanwu

Semiconductors Technology

Course 857 Optical Lithography

Available course dates

TECHNOLOGY FOCUS

Dr. Uzodinma Okoroanyanwu

COURSE CONTENT

WHO SHOULD ATTEND

ALL COURSE DATES FOR THE CATEGORY: Semiconductors Technology

035 Introduction to Semiconductor Packaging Technology

036 Silicon Device Technology: Materials and Processing Overview

037 Power Semiconductor Device Technology

075 Heterogeneous integration of chiplets – Defect inspection, metrology and failure analysis

088 Plasma Etching for CMOS Technology and ULSI Applications

099 Integrated Circuit and MEMS Fabrication Technologies

What You’ll Learn

855 Semiconductor Lithography

856 Alternative Lithography

880 Wafer Fab Process Technology

Would you like an inhouse course?

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