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DRAM (Dynamic Random Access Memory) structure with expansion groove and manufacturing method thereof

A trench, N-type technology, used in semiconductor/solid-state device manufacturing, transistors, electrical components, etc., can solve the problems of high etching process requirements, complex process, increased leakage, etc., to overcome low-leakage thin dielectric layers , the process is simple, the effect of large capacitor plate area

Inactive Publication Date: 2011-03-30
SHANGHAI INST OF MICROSYSTEM & INFORMATION TECH CHINESE ACAD OF SCI
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0004] However, the deep trench capacitors in this kind of DRAM still face many difficulties in the process: (1) In order to meet the capacitance requirements, the groove depth is required to be very deep, that is, there is a high aspect ratio etching requirement, and there will be The etch rate decline effect (lag effect), so the requirements for the etching process are very high; (2) The lower plate of the capacitor adopts the buried substrate (BP, Buried Plate) process, which is complex and difficult; (3) In order to meet the capacitance requirements, the dielectric layer is required to be very thin, which has the risk of increased leakage and affects the yield

Method used

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  • DRAM (Dynamic Random Access Memory) structure with expansion groove and manufacturing method thereof
  • DRAM (Dynamic Random Access Memory) structure with expansion groove and manufacturing method thereof
  • DRAM (Dynamic Random Access Memory) structure with expansion groove and manufacturing method thereof

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Embodiment 1

[0037] See first Figure 8 , this embodiment provides a DRAM structure with extended trenches based on the BEST process for fabricating buried connection straps, including an NMOS transistor 6 and a trench capacitor connected to its source.

[0038] Wherein, the trench capacitor includes:

[0039] The semiconductor substrate can be a P-type substrate or an N-type substrate. The present embodiment takes the N-type Si substrate 1 as an example, so that it is the same N-type as the SiGe / Si epitaxial stack;

[0040] Alternately arranged N-type SiGe layers and N-type Si layers 2 are located on the N-type Si substrate 1 and can be multi-layered. In this embodiment, for example Figure 8As shown, on the N-type Si substrate 1, there are one layer of N-type SiGe layer, one layer of N-type Si layer, another layer of N-type SiGe layer, and another layer of N-type Si layer, which are arranged alternately upward;

[0041] The groove is located in the alternately arranged N-type SiGe laye...

Embodiment 2

[0057] See Figure 9 , which is different from Embodiment 1 in that: the uppermost layer of alternately grown multi-layer N-type SiGe layers and N-type Si layers is an N-type Si layer, and then a P-type Si layer is made on it.

[0058] In the present invention, the stacking order and number of alternate N-type SiGe layers and N-type Si layers are not limited.

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Abstract

The invention discloses a DRAM (Dynamic Random Access Memory) structure with an expansion groove and a manufacturing method thereof. The structure comprises an NMOS (N-channel Metal Oxide Semiconductor) transistor and a groove capacitor connected with a source electrode thereof, wherein the groove capacitor comprises a semiconductor substrate, an N-type SiGe layer and an N-type Si layer which are alternately arranged, a groove, a dielectric layer and a polysilicon layer, wherein the groove is located in the N-type SiGe layer and the N-type Si layer which are alternately arranged and extends into the semiconductor substrate, and the section of a side wall of the groove is in a comb tooth shape; the N-type SiGe layer and the N-type Si layer which are alternately arranged are utilized as a lower pole plate; the dielectric layer is located at the surface of the inner wall of the groove; the polysilicon layer is filled in the groove and utilized as an upper pole plate of the groove capacitor; a P-type Si layer is also prepared on the N-type SiGe layer and the N-type Si layer which are alternately arranged; and the NMOS transistor is manufactured on the P-type Si layer. Through the method, the N-type SiGe layer and the N-type Si layer are alternately grown by utilizing a doping and epitaxial technique and the side wall in the comb tooth shape is manufactured by utilizing selective etching; and the method improves the structure of a deep groove capacitor in the DRAM and simplifies the manufacturing process.

Description

technical field [0001] The invention relates to a dynamic random access memory (DRAM, Dynamic Random Access Memory) unit structure and a manufacturing process thereof, in particular to a DRAM unit structure with extended grooves and a manufacturing process thereof, belonging to the technical field of semiconductor manufacturing. Background technique [0002] Currently, the industry generally adopts a 1T1C (one transistor with one capacitor) structure as a DRAM unit. This combination of 1T1C components makes the storage bit of DRAM the electronic component with the highest density and the lowest unit manufacturing cost, and has an irreplaceable position in computer access devices. With the rapid development of semiconductor technology, DRAM components are rapidly developing towards high density and high capacity. How to design a capacitor with equivalent capacitance while the area of ​​the unit element is continuously reduced is one of the most important challenges in DRAM t...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H01L27/108H01L21/8242H10B12/00
Inventor 黄晓橹陈静张苗王曦
Owner SHANGHAI INST OF MICROSYSTEM & INFORMATION TECH CHINESE ACAD OF SCI
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