JPS6273770A - Semiconductor device - Google Patents

Abstract

PURPOSE:To obtain a high speed a-SiFET having less threshold value shift, no decrease of electric field mobility and excellent rising characteristic by forming the first and second insulating layers between the gate electrode and an amorphous active layer of staggered or reversely staggered thin film transistor. CONSTITUTION:A gate electrode 6 is formed in advance on a substrate 1, and the first insulating layer 3 of optical gap E1 is formed thereon. However, a collecting level exists in the band gap of the layer 3, storage electrons are collected more when the gap E1 is nearer to the optical gap Eg of an a-Si, and a threshold value shift occurs in TFT characteristic. Accordingly, the layer 3 is formed to become E1 Eg, but when the gap E1 increases to approach stoichoimetric composition, a stress is applied into the active layer 2 of the a-Si film of the layer 3 to form a surface level. Thus, it causes an electric field mobility to decrease. Therefore, the second insulating layer 8 is formed, the optical gap E2 is so selected as to become E1 E2 Eg to improve the matching characteristic to the a-Si film of the layer 3.

Description

[Detailed Description of the Invention] [Summary] The present invention relates to semiconductor devices, particularly thin film transistors (Thin Film Transistors).
The gate insulating film of the n film transistor (hereinafter referred to as TPT) has a two-layer structure, and the insulating layer is made of SiNx, etc. whose main component is silicon, and the optical gear of the first and second insulating layers on the gate electrode side is formed. Knob EIE2
By selecting the relationship +>E2, high-speed switching characteristics can be obtained and a thin film transistor with excellent stability can be provided.

[Industrial application field]

The present invention relates to a semiconductor device, and particularly to a semiconductor device in which a gate insulating layer of a thin film transistor for a liquid crystal display device has a double structure.

[Traditional techniques]

LCD (Liqwidcr) is used as a flat display.
ystal displays) with increased display capacity and a considerably large number of pixels are commercially available. As the size increases in this way, the ratio of driving time to non-driving time becomes smaller, the contrast ratio decreases, and the viewing angle becomes narrower.To solve this problem, T
Active matrix display, in which PTs are arranged in a matrix to directly drive an LCD, is widely used in applications where a display with a high contrast ratio can be obtained by applying voltage directly to the pixels.

TPTs and diodes are used as switching elements in such active matrix displays. Especially T.P.
T has been extensively researched because it has a large area and can use glass substrates. In particular, since an amorphous silicon (a-si) film is used for the gate insulating layer, it exhibits high resistance.
The on/off ratio of switching when driving pixels can be increased.

Such a-3i (amorphous silicon) TPT has a staggered structure and an inverted staggered structure.

Each of these structures will be explained in FIGS. 4 to 6. Fig. 4 is a plan view of the a-3i TFT, and Fig. 5 is the A-A' of Fig. 4.
A cross-sectional view of a staggered TPT is shown, and FIG. 6 is a side cross-sectional view of an inverted staggered TPT. In Fig. 4, 4 indicates a drain electrode, which serves as an electrode for one pixel.As shown in Fig. 5, a transparent conductive film is formed on a transparent substrate such as glass, and the drain electrode, 4, and source electrode are formed on a transparent substrate such as glass. 5 is patterned by photoetching, and on these patterns (drain electrode 4
Then, as shown in FIG. 4, an a-St film 2 is formed by a plasma CVD method (with an Opara knob in a small portion). This a
-3t film 2 is patterned to form a pattern, and the same (
A gate insulating layer 3 is formed by the plasma CVD method, a gate electrode film is formed on this gate insulating layer N3, and a gate electrode 6 pattern is formed by photoetching, and after the protective insulating film is formed, the LCD manufacturing process is started. .

In the case of Fig. 6, a gate electrode is formed on the glass substrate IT using an inverted staggered a-3i TFT, a gate insulating layer 3 is formed by plasma CVD, etc., and an a-3i film is formed on it by plasma CVD. Then, the source and drain electrodes are patterned by photoetching. These reverse staggered and staggered types each have their advantages and disadvantages.

In the inverted staggered type, the a-3i of the gate insulating film and active layer
The film can be formed continuously, and in the staggered type, the a-3i film of the active layer is protected by a GaI insulating film, which has the feature of high reliability.

[Problems that the invention attempts to solve]

As described above, the staggered type or reverse staggered type a-3i TFT in which the gate insulating film is partially formed has a problem in that the dark value shifts after gate stress is applied.

In order to reduce such a dark value shift, 4'' and a-3i
The field effect mobility of Al Off (cJ/v,
5ec), which resulted in a disadvantage that the switching characteristics of the TPT deteriorated. That is, FIG. 7 shows a characteristic curve 7 of gate voltage VG and drain current ID, and after application of gate stress, the characteristic curve shifts as shown in 7a.

[Means for solving problems]

The present invention has been made to solve the above-mentioned drawbacks, and its purpose is to provide a gate insulating film with a two-layer structure: a first insulating layer on the gate side, and a second insulating layer formed on the first layer. By setting the respective optical gaps El and E2 such that El>Ez, we aim to obtain a high-speed a-3i TFT with small dark value shift and excellent rise characteristics without deterioration of field effect mobility. The means includes a first electrode between the gate electrode and the amorphous active layer of the staggered or reverse staggered thin film transistor.
This is achieved by a semiconductor device characterized by forming a second insulating layer.

[For production]

In one of the TPTs of the present invention, a gate electrode is formed in advance on a substrate, and a first insulating layer with an optical gap E1 is formed on this gate electrode. There is a correlation between the depth of this trap level and the optical gap E1, and the optical gap E1 is a
The closer the optical gap Eg of -3i is, the more accumulated electrons are captured, which causes a dark value shift in the TPT characteristics.

Therefore, the first insulating layer is formed so that El>Eg. However, the optical gap E1 of the first insulating layer becomes large and the stoichiometry
When approaching a chemical composition called try), the insulating layer/
Stress is applied to the active layer of the a-Si film and surface states are formed, leading to a decrease in field effect mobility.Therefore, the optical gap E2 of the second insulating layer is set as El>Ez>Eg.
The purpose of the present invention is to provide an a-3t TFT which is selected so as to improve the compatibility with the a-3i film of one active layer.

〔Example〕

Two embodiments of the present invention will be described in detail below with reference to the @i diagram.

FIG. 1 shows an inverted staggered a-3i TFT. First, a glass substrate 1 as an insulating substrate is cleaned, and a gate electrode film is made of Cr or ΔLMo.

A NiC4 film is formed, and a gate electrode pattern is formed by photoetching or the like using a resist mask to obtain the gate electrode 6.

Next, a gate oxide film 3, which is a first insulating layer, is formed on the insulating substrate 1 on which the gate electrode 6 is formed by using a mixed gas of silane (StHa) and ammonia (NH3) and decomposing it by glow discharge. Form.

The gate oxide film 3 described above is SiNx, but SiO2,
Even SiC, 5iON, Ae 203, etc. (.

In the case of SiO2, 5t) The mixed gases of la and 02 are each decomposed by glow discharge. At this time, the first insulating layer (S
iN x ) to form an optical gap E1.

As for this condition, the temperature of the substrate 1 is 200° to 300°C.

N Hv / SiHa reaction gas pressure 0.1-10To
rr, r4 power 0.02~0.3 W/c
i, gas flow ratio N H1/S H4 = 1 to 4 is preferred. At this time, the optical gap E1 of the first insulating layer becomes E1=3 to 7ev by changing the film forming conditions.

Next, the second insulating layer 8 is continuously applied without breaking the vacuum state.
form. The optical gap E2 of the second insulating layer 8 is El
The film forming conditions are changed and selected so as to satisfy the relationship <Ez. The optical gap at this time can be selected to be approximately 2<Ez<5ev. After the formation of these first and second insulating layers 3.8, an a-3i film 2 is subsequently deposited as an active layer.

This is deposited by decomposing 5iI (a gas by glow discharge. After patterning the a-3i film by photoetching etc., and forming a resist pattern for the source and drain electrodes, an a-Si film n+a-3 doped with phosphorus is formed. A film 9 is formed by a glow discharge decomposition method, and a source and drain electrode 4 is further formed.
, 5 is buttered. A for source and drain!
! , Ti, Cr or NiCr are used.

FIG. 2 shows the threshold voltage shift and field effect mobility μe i (of the first insulating layer SiN x
Show dependencies. In the same figure, the left side of the vertical axis is the gate voltage ■ = 3
0v, drain voltage ■. After applying −5 V for 1 minute, the field effect mobility p e ff (clll, / V
, see)). Horizontal axis: NH3/Si
It shows Ha. First, the change in μeff in the case of only the gate insulating layer 3, which is the conventional first insulating layer, is shown by characteristic curve 10.
As shown in the characteristic curve 11, there is a large change, but in the case of a two-layer structure, the change is small as shown in the characteristic curve 11. The characteristic curve has Δ■
This shows that. The optical gap of the first insulating layer 3 is E
When selecting l-3 to 7cv.

This insulating layer has a trap level in the band gap,
There is a correlation between the depth of this capture level and the optical gap E1, and the closer the optical gap E1 is to the optical gear knob Eg of a-3i, the more accumulated electrons are captured.

Darkness value shifts in TPT characteristics. Therefore, the optical gap E1 of the first insulating layer 3 is selected so that E+>Eg. However, as the optical gear knob E1 of the first insulating layer 3 becomes larger and approaches a film with a stoichiometric composition, the insulating layer/a-3
Stresses 1 to Stress are added to the i-active N3 to form surface states, and the field effect mobility μeff is reduced. Therefore, a second insulating layer is formed on the first insulating layer 3 using a mixed gas of silane (SiH4) and ammonia (NH3) to form an optical gear.
.

In other words, by selecting E 1 > E 2 > E g, the consistency of the second N with the active N2 of the a St film is improved, and the field effect mobility μeff is increased as shown in the characteristic curve 11 in Figure 2. a-3, which has high speed switching characteristics without any deterioration
i TFT can be obtained.

Figure 3 shows the staggered type a-3i shown in Figure 5.
This is a side cross-sectional view commonly used for TFTs. After cleaning the glass substrate 1, depositing a transparent conductive thin film, forming drain/in, and source snow removal resist patterns, a phosphorous-doped 8i film (n+a-
3i) Form 9, source and 1' rain electrodes 5 and 6, form an a-5i film with plasma C and VD, and then continuously form the first and second insulating layers 3 without breaking the vacuum. After forming the gate electrode 6, a staggered type a-3i TFT is formed by patterning the gate electrode 6.

〔Effect of the invention〕

Since the present invention is constructed as described above, it is possible to provide an a-8i TPT that can reduce the dark value shift after application of the GeI stress and that does not reduce the a-3i field effect mobility.

[Brief explanation of drawings]

Fig. 1 is a side sectional view of the a-3i TFT (inverted staggered type) of the present invention. Fig. 2 is a characteristic diagram showing the dependence of the a-3i TFT characteristics on the gate insulating film. Fig. 3 is the a-3i TFT of the present invention [ [Reverse staggered type] Fig. 4 is a plan view of a conventional a-3i TFT. Fig. 5 is a sectional view taken along the Δ-A line in Fig. 4. Fig. 6 is a sectional view of the conventional a-3i TFT [staggered type] Fig. 7 is a VC-ID characteristic diagram of the a-3i TFT. ...Source electrode 6...Gate electrode 8...Second insulating layer 9...n+a-3i film qθ-5iTF7'' illustration] Draft surface view (seven card shape) Fig. 1 ; a-5iTPTM Sex Works - Toze 9 Rumors” Central Iroku J View Part 2
Figure 0-5 iTFT 4 Norishima - Side view (Sudaka card board) Figure 3 a-9i TFT 4ffi7 Figure 4 figure

Claims (7)

[Claims] (1) A semiconductor device characterized in that first and second insulating layers are formed between a gate electrode and an amorphous active layer of a staggered or inverted staggered thin film transistor. (2) A first insulating layer and a second insulating layer containing silicon as a main component are formed on the gate electrode formed on the insulating substrate, and after forming an amorphous semiconductor layer including an active layer, a source/drain layer is formed. 2. The semiconductor device according to claim 1, comprising a staggered thin film transistor formed with electrodes. (3) After forming an amorphous semiconductor layer including an active layer on the source and drain electrodes formed on the insulating substrate, first and second insulating layers containing silicon as a main component are formed to form a gate electrode. 2. The semiconductor device according to claim 1, comprising an inverted staggered thin film transistor. (4) When the optical gap of the first insulating layer is E_1 and the optical gap of the second insulating layer is E_2, E_1>
The semiconductor device according to claim 1, characterized in that the insulating layer satisfies the relationship E_2. (5) The semiconductor device according to claim 1, wherein the insulating layer is mainly composed of silicon and contains nitrogen (N). (6) The semiconductor device according to claim 1, wherein an amorphous semiconductor layer containing silicon as a main component and serving as a donor is formed on the upper surface of the amorphous active layer. (7) A semiconductor device according to claim 7, wherein source/drain electrodes are formed from the amorphous semiconductor layer and the metal layer using a resist pattern for source/drain electrodes. .