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BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter.

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Presentation on theme: "BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter."— Presentation transcript:

1 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate n + buried layer p-base layer n + layer p + layer

2 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate

3 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate n + buried layer n epi layer

4 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate n + buried layer p + isolation layer

5 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate n + buried layer p + isolation layer p-base layer

6 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate n + buried layer p + isolation layer p-base layer n + layer

7 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate n + buried layer p + isolation layer p-base layer n + layer p + layer

8 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate n + buried layer p + isolation layer p-base layer n + layer p + layer

9 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate n + buried layer p + isolation layer p-base layer n + layer p + layer

10 BJT Processing 1. Implantation of the buried n + layer 2. Growth of the epitaxial layer 3. p + isolation diffusion 4. Base p-type diffusion 5. Emitter n + diffusion 8. Metal deposition and etching 6. p + ohmic contact 7. Contact etching 9. Passivation and bond pad opening p-substrate n + buried layer p + isolation layer p-base layer n + layer p + layer

11 Doping Profiles in a BJT

12 Substrate PNP BJT

13 Lateral PNP BJT

14 Modifications to a BJT Process Dielectric isolation --- substrate isolation Superbeta transistors Double diffusion --- make acceptable JFETs Ion implanted JFETs --- make good JFETs Double diffused pnp BJTs --- make good pnp devices

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