Description

Book Synopsis
Fundamental Principles of Optical Lithography: The Science of Microfabrication presents a complete theoretical and practical treatment of the topic of lithography for both students and researchers. This sole-authored text includes optional computer simulation exercises as well as problems at the end of each chapter.

Table of Contents
Preface.

1. Introduction to Semiconductor Lithography.

1.1 Basics of IC Fabrication.

1.2 Moore’s Law and the Semiconductor Industry.

1.3 Lithography Processing.

Problems.

2. Aerial Image Formation – The Basics.

2.1 Mathematical Description of Light.

2.2 Basic Imaging Theory.

2.3 Partial Coherence.

2.4 Some Imaging Examples.

Problems.

3. Aerial Image Formation – The Details.

3.1 Aberrations.

3.2 Pupil Filters and Lens Apodization.

3.3 Flare.

3.4 Defocus.

3.5 Imaging with Scanners Versus Steppers.

3.6 Vector Nature of Light.

3.7 Immersion Lithography.

3.8 Image Quality.

Problems.

4. Imaging in Resist: Standing Waves and Swing Curves.

4.1 Standing Waves.

4.2 Swing Curves.

4.3 Bottom Antirefl ection Coatings.

4.4 Top Antirefl ection Coatings.

4.5 Contrast Enhancement Layer.

4.6 Impact of the Phase of the Substrate Refl ectance.

4.7 Imaging in Resist.

4.8 Defi ning Intensity.

Problems.

5. Conventional Resists: Exposure and Bake Chemistry.

5.1 Exposure.

5.2 Post-Apply Bake.

5.3 Post-exposure Bake Diffusion.

5.4 Detailed Bake Temperature Behavior.

5.5 Measuring the ABC Parameters.

Problems.

6. Chemically Amplifi ed Resists: Exposure and Bake Chemistry.

6.1 Exposure Reaction.

6.2 Chemical Amplifi cation.

6.3 Measuring Chemically Amplifi ed Resist Parameters.

6.4 Stochastic Modeling of Resist Chemistry.

Problems.

7. Photoresist Development.

7.1 Kinetics of Development.

7.2 The Development Contrast.

7.3 The Development Path.

7.4 Measuring Development Rates.

Problems.

8. Lithographic Control in Semiconductor Manufacturing.

8.1 Defi ning Lithographic Quality.

8.2 Critical Dimension Control.

8.3 How to Characterize Critical Dimension Variations.

8.4 Overlay Control.

8.5 The Process Window.

8.6 H–V Bias.

8.7 Mask Error Enhancement Factor (MEEF).

8.8 Line-End Shortening.

8.9 Critical Shape and Edge Placement Errors.

8.10 Pattern Collapse.

Problems.

9. Gradient-Based Lithographic Optimization: Using the Normalized Image Log-Slope.

9.1 Lithography as Information Transfer.

9.2 Aerial Image.

9.3 Image in Resist.

9.4 Exposure.

9.5 Post-exposure Bake.

9.6 Develop.

9.7 Resist Profi le Formation.

9.8 Line Edge Roughness.

9.9 Summary.

Problems.

10. Resolution Enhancement Technologies.

10.1 Resolution.

10.2 Optical Proximity Correction (OPC).

10.3 Off-Axis Illumination (OAI).

10.4 Phase-Shifting Masks (PSM).

10.5 Natural Resolutions.

Problems.

Appendix A. Glossary of Microlithographic Terms.

Appendix B. Curl, Divergence, Gradient, Laplacian.

Appendix C. The Dirac Delta Function.

Index.

Fundamental Principles of Optical Lithography

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    A Paperback / softback by Chris Mack

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      Publisher: John Wiley & Sons Inc
      Publication Date: 16/11/2007
      ISBN13: 9780470727300, 978-0470727300
      ISBN10: 0470727306
      Also in:
      Technology, Engineering & Agriculture Electronics and communications engineering

      Description

      Book Synopsis
      Fundamental Principles of Optical Lithography: The Science of Microfabrication presents a complete theoretical and practical treatment of the topic of lithography for both students and researchers. This sole-authored text includes optional computer simulation exercises as well as problems at the end of each chapter.

      Table of Contents
      Preface.

      1. Introduction to Semiconductor Lithography.

      1.1 Basics of IC Fabrication.

      1.2 Moore’s Law and the Semiconductor Industry.

      1.3 Lithography Processing.

      Problems.

      2. Aerial Image Formation – The Basics.

      2.1 Mathematical Description of Light.

      2.2 Basic Imaging Theory.

      2.3 Partial Coherence.

      2.4 Some Imaging Examples.

      Problems.

      3. Aerial Image Formation – The Details.

      3.1 Aberrations.

      3.2 Pupil Filters and Lens Apodization.

      3.3 Flare.

      3.4 Defocus.

      3.5 Imaging with Scanners Versus Steppers.

      3.6 Vector Nature of Light.

      3.7 Immersion Lithography.

      3.8 Image Quality.

      Problems.

      4. Imaging in Resist: Standing Waves and Swing Curves.

      4.1 Standing Waves.

      4.2 Swing Curves.

      4.3 Bottom Antirefl ection Coatings.

      4.4 Top Antirefl ection Coatings.

      4.5 Contrast Enhancement Layer.

      4.6 Impact of the Phase of the Substrate Refl ectance.

      4.7 Imaging in Resist.

      4.8 Defi ning Intensity.

      Problems.

      5. Conventional Resists: Exposure and Bake Chemistry.

      5.1 Exposure.

      5.2 Post-Apply Bake.

      5.3 Post-exposure Bake Diffusion.

      5.4 Detailed Bake Temperature Behavior.

      5.5 Measuring the ABC Parameters.

      Problems.

      6. Chemically Amplifi ed Resists: Exposure and Bake Chemistry.

      6.1 Exposure Reaction.

      6.2 Chemical Amplifi cation.

      6.3 Measuring Chemically Amplifi ed Resist Parameters.

      6.4 Stochastic Modeling of Resist Chemistry.

      Problems.

      7. Photoresist Development.

      7.1 Kinetics of Development.

      7.2 The Development Contrast.

      7.3 The Development Path.

      7.4 Measuring Development Rates.

      Problems.

      8. Lithographic Control in Semiconductor Manufacturing.

      8.1 Defi ning Lithographic Quality.

      8.2 Critical Dimension Control.

      8.3 How to Characterize Critical Dimension Variations.

      8.4 Overlay Control.

      8.5 The Process Window.

      8.6 H–V Bias.

      8.7 Mask Error Enhancement Factor (MEEF).

      8.8 Line-End Shortening.

      8.9 Critical Shape and Edge Placement Errors.

      8.10 Pattern Collapse.

      Problems.

      9. Gradient-Based Lithographic Optimization: Using the Normalized Image Log-Slope.

      9.1 Lithography as Information Transfer.

      9.2 Aerial Image.

      9.3 Image in Resist.

      9.4 Exposure.

      9.5 Post-exposure Bake.

      9.6 Develop.

      9.7 Resist Profi le Formation.

      9.8 Line Edge Roughness.

      9.9 Summary.

      Problems.

      10. Resolution Enhancement Technologies.

      10.1 Resolution.

      10.2 Optical Proximity Correction (OPC).

      10.3 Off-Axis Illumination (OAI).

      10.4 Phase-Shifting Masks (PSM).

      10.5 Natural Resolutions.

      Problems.

      Appendix A. Glossary of Microlithographic Terms.

      Appendix B. Curl, Divergence, Gradient, Laplacian.

      Appendix C. The Dirac Delta Function.

      Index.

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