Comparing techniques for fabrication polysilicon contacted emitter bipolar transistors

Proceedings of the 1988 Bipolar Circuits and Technology Meeting, Pub Date : 1988-09-12 DOI:10.1109/BIPOL.1988.51046

R. Bagri, G. Neudeck, W. Klaasen, J. Pak, J. Logsdon

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引用次数: 1

Abstract

Four methods for fabricating polysilicon-contacted BJTs have been investigated. In the first method polysilicon was deposited using low-pressure chemical vapor deposition (LPCVD) at 620 degrees C. In the remaining three methods a-Si was first deposited and then recrystallized to form polysilicon. In the second method a-Si was deposited using LPCVD at 580 degrees C. The third method used plasma-enhanced chemical vapor deposition (PECVD) to deposit a-Si-H. The fourth method involved a plasma etch with argon or hydrogen prior to deposition of a-Si:H using PECVD. The results indicated that using the PECVD method for depositing a-Si-H without any prior plasma-etch step and recrystallizing it to form polysilicon resulted in the highest current gain ( beta ) enhancement of 3.5 and also allowed the reduction of the polysilicon anneal temperature down to 800 degrees C or 900 degrees C from 1000 degrees C. The compactness in the spread of the peak beta values for the devices fabricated using this technique also reflects its ability to reproducible fabrication of polysilicon contacted shallow emitter BJTs.<>

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多晶硅接触发射极双极晶体管的制备技术比较

研究了四种制备多晶硅接触bjt的方法。在第一种方法中，使用620℃的低压化学气相沉积(LPCVD)沉积多晶硅。在其余三种方法中，首先沉积a-Si，然后再结晶形成多晶硅。第二种方法是在580℃下用LPCVD沉积a-Si，第三种方法是用等离子体增强化学气相沉积(PECVD)沉积a-Si- h。第四种方法是在使用PECVD沉积a- si:H之前用氩或氢进行等离子体蚀刻。PECVD方法"结果表明,使用沉淀a-Si-H等离子腐蚀步骤之前没有任何和再结晶形成多晶硅导致最高的电流增益(β)增强3.5还允许减少多晶硅退火温度降到800度或900度1000度C的密实度的传播高峰β值设备制造使用这种技术也反映了其可再生制造的能力多晶硅接触浅射极bjt的研究

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Proceedings of the 1988 Bipolar Circuits and Technology Meeting,

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