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intro_wafer [2025/11/24 10:10] – [What are the main environmental impacts associated to the manufacturing processes?] louiseintro_wafer [2025/12/05 17:03] (Version actuelle) – [What paths/ideas should be explored?] arthur
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-## Introduction +## System definition
- +
-### Definition+
  
 A silicon wafer is a thin slice of silicon (semiconductor material) that is used in the manufacturing of integrated circuits.   A silicon wafer is a thin slice of silicon (semiconductor material) that is used in the manufacturing of integrated circuits.  
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 Wafers are at the basis of many electronic components like RAMs, CPUs, GPUs, SSDs, etc. Wafers are at the basis of many electronic components like RAMs, CPUs, GPUs, SSDs, etc.
- 
 ### Are they different types and technologies? ### Are they different types and technologies?
  
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 Several wafer technologies exist, with the two main types being logic and memory: Several wafer technologies exist, with the two main types being logic and memory:
-* Logic wafers contain the circuits that perform computations, logical operations, and data processing, for example in CPUs and GPUs. They follow a specific modeling approach. 
-* Memory wafers contain the circuits that store information, either volatile or non-volatile. 
-  * Volatile memory: Data is lost when power is turned off, as in RAM. In this case, the internal structure is very similar to that of logic wafers. 
-  * Non-volatile memory: Data is retained even without power, as in NAND flash memory technology used in SSDs. Especially for 3D NAND, the structure is more vertical and significantly different from that of logic wafers. The processing steps also differ. 
  
 +* **Logic wafers** contain the circuits that perform computations, logical operations, and data processing, for example in CPUs and GPUs. They follow a specific modeling approach.
 +* **Memory wafers** contain the circuits that store information, either volatile or non-volatile.
 +  * **Volatile memory**: Data is lost when power is turned off, as in RAM. In this case, the internal structure is very similar to that of logic wafers.
 +  * **Non-volatile memory**: Data is retained even without power, as in NAND flash memory technology used in SSDs. Especially for 3D NAND, the structure is more vertical and significantly different from that of logic wafers. The processing steps also differ.
  
-## Manufacturing 
  
-### What is it made of?+## Life Cycle
  
-A silicon wafer is made from single-crystal silicon, which is derived from high-purity sand. +### Manufacturing
  
-### How is it manufactured?+#### What is it made of? 
 + 
 +A silicon wafer is made from single-crystal silicon, which is derived from high-purity sand. 
 + 
 +#### How is it manufactured?
  
 The process involves purifying the sand, melting it, and re-crystallizing it into a large, pure silicon ingot (Czochralski process). This ingot is then sliced into thin discs, which are polished to a mirror-like finish to form the wafer. The process involves purifying the sand, melting it, and re-crystallizing it into a large, pure silicon ingot (Czochralski process). This ingot is then sliced into thin discs, which are polished to a mirror-like finish to form the wafer.
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   * DUV (Deep Ultra-Violet) Lithography: Uses KrF (248 nm) for nodes ≥150 nm and ArF (193 nm) in dry (≥65 nm) and immersion forms (≥7 nm).   * DUV (Deep Ultra-Violet) Lithography: Uses KrF (248 nm) for nodes ≥150 nm and ArF (193 nm) in dry (≥65 nm) and immersion forms (≥7 nm).
   * EUV (Extreme Ultra-Violet) Lithography: Employs a 13.5 nm light source, achieving the smallest nodes, such as 5 nm.   * EUV (Extreme Ultra-Violet) Lithography: Employs a 13.5 nm light source, achieving the smallest nodes, such as 5 nm.
 +
 The resolution of each photolithography technique directly impacts the achievable node size, with EUV technology leading the way in current semiconductor advancements. The resolution of each photolithography technique directly impacts the achievable node size, with EUV technology leading the way in current semiconductor advancements.
 +
 * **Etching**: This step removes parts of the photoresist and oxide layer exposed by the laser, creating the desired patterns on the wafer. Etching can be performed using either dry (plasma-phase) or wet (liquid-phase) techniques. * **Etching**: This step removes parts of the photoresist and oxide layer exposed by the laser, creating the desired patterns on the wafer. Etching can be performed using either dry (plasma-phase) or wet (liquid-phase) techniques.
 * **Doping**: Introducing small amounts of charged particles to modify the electrical properties of the wafer surface. Doping is achieved through ion implantation or diffusion, creating regions of p-type or n-type semiconductor material. * **Doping**: Introducing small amounts of charged particles to modify the electrical properties of the wafer surface. Doping is achieved through ion implantation or diffusion, creating regions of p-type or n-type semiconductor material.
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 See Gauthier's posters for more details See Gauthier's posters for more details
  
-### Who are the main manufacturers?+#### Who are the main manufacturers?
  
 For logic wafers: Intel, AMD, Qualcomm. They rely on foundires like TSMC and GlobalFoundries. For logic wafers: Intel, AMD, Qualcomm. They rely on foundires like TSMC and GlobalFoundries.
 For memory wafers: For memory wafers:
 +
 * NAND: Samsung, Kioxia, Western Digital * NAND: Samsung, Kioxia, Western Digital
 * DRAM: Samsung, SK Hynix, Micron Technology * DRAM: Samsung, SK Hynix, Micron Technology
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 The semiconductor industry is comprised of three main types of companies, each playing a distinct role: The semiconductor industry is comprised of three main types of companies, each playing a distinct role:
 +
 * IDMs (Integrated Device Manufacturers): Perform all stages from design to manufacturing and sales in-house. Examples include Intel, Texas Instruments, Samsung Electronics, and Micron Technology. * IDMs (Integrated Device Manufacturers): Perform all stages from design to manufacturing and sales in-house. Examples include Intel, Texas Instruments, Samsung Electronics, and Micron Technology.
 * Fabless Companies: Design and sell chips but outsource manufacturing to foundries. Notable fabless companies are Nvidia, Qualcomm, AMD, Apple, Broadcom, MediaTek, and Marvell Technology Group. * Fabless Companies: Design and sell chips but outsource manufacturing to foundries. Notable fabless companies are Nvidia, Qualcomm, AMD, Apple, Broadcom, MediaTek, and Marvell Technology Group.
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 TBC TBC
 +
 +
 ### What are the main environmental impacts associated to the manufacturing processes? ### What are the main environmental impacts associated to the manufacturing processes?
  
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 TBC TBC
- 
 ### What paths/ideas should be explored? ### What paths/ideas should be explored?
  
 * Confront Negaoctet's datasets and imec results in order to understand what are the reasons for the differences * Confront Negaoctet's datasets and imec results in order to understand what are the reasons for the differences
  
 +* Estimate the environmental impact of the wafer packaging [[categorie:page#ici|wafer packaging]]
intro_wafer.1763975422.txt.gz · Dernière modification : de louise