CN205177824U - Metal level - insulating layer - metal level condenser - Google Patents
Metal level - insulating layer - metal level condenser Download PDFInfo
- Publication number
- CN205177824U CN205177824U CN201520792014.1U CN201520792014U CN205177824U CN 205177824 U CN205177824 U CN 205177824U CN 201520792014 U CN201520792014 U CN 201520792014U CN 205177824 U CN205177824 U CN 205177824U
- Authority
- CN
- China
- Prior art keywords
- layer
- metal
- electric capacity
- capacitor
- side wall
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn - After Issue
Links
Landscapes
- Semiconductor Integrated Circuits (AREA)
Abstract
The utility model provides a metal level - insulating layer - metal level condenser is suitable for the piece internal capacitance of being applied to integrated circuit, include: the first metal layer, the definition has that the noncapacitive is regional, electric capacity is regional on the first metal layer, a plurality of cofferdam side wall that the first metal layer in the electric capacity region set up on the surface, cofferdam side wall are including the first dielectric layer that is located the bottom and the first barrier layer on being located first dielectric layer, and the cofferdam side wall corresponds flutedly, the electric capacity bottom crown, electric capacity dielectric layer, the electric capacity top crown that set gradually in cofferdam side wall and recess surface, the conductive plug layer that sets up on the electric capacity top crown, the second metal level that sets up on the conductive plug layer. Owing to adopt spatial structure's MIM condenser, increased the corresponding active electrode area of the upper and lower polar plate of electric capacity, improved electric capacity density, can realize great capacitance value on limited chip area, satisfied big electric capacity integrated circuit's such as LCD drive circuit, RFCMOS circuit demand, be suitable for the piece internal capacitance of being applied to integrated circuit.
Description
Technical field
The utility model relates to integrated circuit fields, is specifically related to a kind of metal-insulator-metal capacitor.
Background technology
The application of capacitor is a lever in integrated circuit design all the time, and designer wishes the capacitor using capacitance as far as possible large, but bulky capacitor value often brings is exactly increase chip area, improves manufacturing cost.How improving the capacitance (i.e. capacitance density) on unit chip area, is a challenge of integrated circuit fields all the time.
Existing capacitor, roughly can be divided into front road capacitor and rear road capacitor, front road capacitor is MOS capacitor, capacitance of PN junction device such as, rear road capacitor such as MIM(metal-insulator-metal) capacitor, MOM(metal level-oxide layer-metal level) capacitor.Wherein, MIM capacitor can provide good frequency and temperature correlated characteristic, and interlayer metal and copper-connection processing procedure can be formed at, reduce the degree of difficulty and complexity integrated with CMOS front-end process, be thus widely used in various integrated circuit and such as simulate in-logic, analog to digital, mixed signal and radio circuit.
Existing MIM capacitor is generally planar structure, comprises electric capacity bottom crown, capacitor dielectric layer and electric capacity top crown, forms the sandwich structure clipping insulating medium layer between double layer of metal electrode.For the MIM capacitor of planar structure, its capacitance density can reach 4-6fF/ μm at most
2, and in actual applications, the demand of the bulky capacitor integrated circuit such as LCD drive circuit, RFCMOS circuit still cannot be met far away.
Utility model content
The purpose of this utility model is to provide a kind of metal-insulator-metal capacitor, and electric capacity in the sheet being suitable for being applied to integrated circuit, improves capacitance density, meet the demand of bulky capacitor integrated circuit.
For achieving the above object, the utility model adopts following technical scheme:
A kind of metal-insulator-metal capacitor, electric capacity in the sheet being suitable for being applied to integrated circuit, it comprises: the first metal layer, and on the first metal layer, definition has noncapacitive region, capacitor regions; Some cofferdam side wall that the first metal layer in capacitor regions is arranged on the surface, described cofferdam side wall comprises the first medium layer being positioned at bottom and the first barrier layer be positioned on first medium layer, and described cofferdam side wall correspondence is fluted; In electric capacity bottom crown, capacitor dielectric layer, electric capacity top crown that cofferdam side wall and groove surfaces set gradually; The conductive plug layer arranged on electric capacity top crown; The second metal level arranged on conductive plug layer.
Preferably, in the side wall of described cofferdam, described first barrier layer height is 50nm-5 μm, and described first medium layer height is 50nm-5 μm.
Preferably, the second barrier layer is provided with between described first medium layer and the first metal layer.
Preferably, described first barrier layer, the second barrier layer are any one or the multiple combination in SiN, SiON, SiC, SiNC, SiONC.
Preferably, the edge of described capacitor dielectric layer extends across the edge of electric capacity bottom crown with electrical isolation electric capacity top crown and electric capacity bottom crown.
Preferably, the cross sectional shape of described groove is any one or the multiple combination in triangle, rectangle, polygon, circle, ellipse.
Preferably, described the first metal layer and described second metal level are metal level adjacent in noncapacitive region or non-conterminous metal level.
Preferably, described conductive plug layer flushes with the dielectric layer of noncapacitive region surface, and described second metal level is arranged on the dielectric layer of described conductive plug layer and described noncapacitive region surface.
Compared with prior art, of the present utility model have following technique effect:
The utility model is by adopting the MIM capacitor of stereochemical structure, add the effective electrode area that the upper and lower pole plate of electric capacity is corresponding, improve capacitance density (by adopting different sizes and material, the capacitance density of stereochemical structure MIM capacitor of the present utility model can reach the 10-200 of existing planar structure MIM capacitor doubly), larger capacitance can be realized on limited chip area, meet the demand of the bulky capacitor integrated circuit such as LCD drive circuit, RFCMOS circuit, electric capacity in the sheet being suitable for being applied to integrated circuit.
Accompanying drawing explanation
By Figure of description and subsequently together with Figure of description for illustration of the embodiment of some principle of the utility model, the further feature that the utility model has and advantage will become clear or more specifically be illustrated.Wherein:
Fig. 1-Figure 10 is the process schematic of the manufacture method of metal-insulator-metal capacitor according to the utility model embodiment 1;
Fig. 2-Figure 20 is the process schematic of the manufacture method of metal-insulator-metal capacitor according to the utility model embodiment 2;
Figure 21 is the exemplary embodiments of the cross-sectional schematic obtained along A-A line in Fig. 6, and wherein, Figure 21 (A) is regular hexagon; Figure 21 (B) is square; Figure 21 (C) is triangle; Figure 21 (D) is rectangle; Figure 21 (E) is circular;
Figure 22 is the exemplary embodiments of the cross-sectional schematic obtained along B-B line in Figure 16, and wherein, Figure 22 (A) is regular hexagon; Figure 22 (B) is square; Figure 22 (C) is triangle; Figure 22 (D) is rectangle; Figure 22 (E) is circular.
Embodiment
For the capacitance density solving existing MIM capacitor cannot meet the problem of bulky capacitor integrated circuit demand, the utility model provides a kind of metal-insulator-metal capacitor, electric capacity in the sheet being suitable for being applied to integrated circuit, it comprises: the first metal layer, and on the first metal layer, definition has noncapacitive region, capacitor regions; Some cofferdam side wall that the first metal layer in capacitor regions is arranged on the surface, described cofferdam side wall comprises the first medium layer being positioned at bottom and the first barrier layer be positioned on first medium layer, and described cofferdam side wall correspondence is fluted; In electric capacity bottom crown, capacitor dielectric layer, electric capacity top crown that cofferdam side wall and groove surfaces set gradually; The conductive plug layer arranged on electric capacity top crown; The second metal level arranged on conductive plug layer.
The utility model is by adopting the MIM capacitor of stereochemical structure, add the effective electrode area that the upper and lower pole plate of electric capacity is corresponding, improve capacitance density (by adopting different sizes and material, the capacitance density of stereochemical structure MIM capacitor of the present utility model can reach the 10-200 of existing planar structure MIM capacitor doubly), larger capacitance can be realized on limited chip area, meet the demand of the bulky capacitor integrated circuit such as LCD drive circuit, RFCMOS circuit, electric capacity in the sheet being suitable for being applied to integrated circuit.
Below in conjunction with accompanying drawing, specific embodiment of the utility model is described in detail.
embodiment 1
Fig. 1-Figure 10 is the process schematic of the manufacture method of metal-insulator-metal capacitor according to the utility model embodiment 1.
See Fig. 1, provide the first metal layer 100, define noncapacitive region, capacitor regions on the first metal layer 100, Fig. 1 only illustrates the structure of wherein capacitor regions at this, and the structure in not shown noncapacitive region.
In capacitor regions, form first medium layer the 400, the 3rd barrier layer 500, second dielectric layer 600 successively on the surface in the first metal layer 100.Wherein, the thickness T1 forming first medium layer 400 is 50nm-5 μm, and the thickness T2 forming second dielectric layer 600 is 50nm-5 μm.
In addition, preferably before the step forming first medium layer 400, on the first metal layer 100, adhesion layer 200, second barrier layer 300 is formed successively.Wherein, adhesion layer 200 is generally TiN layer, and the second barrier layer 300, the 3rd barrier layer 500 can be any one or multiple combination in SiN, SiON, SiC, SiNC, SiONC.
See Fig. 2, etching second dielectric layer 600, stops at the 3rd barrier layer 500, forms some bulge-structures 601.
See Fig. 3, form the first barrier layer 700 in second dielectric layer 600 and surface, the 3rd barrier layer 500.First barrier layer 700 can be any one or multiple combination in SiN, SiON, SiC, SiNC, SiONC.
See Fig. 4, the first barrier layer 700 of etching bulge-structure 601 top surface, the first barrier layer 700 between etching bulge-structure 601, the 3rd barrier layer 500, retain the hard mask of the first barrier layer 700 as subsequent etching of bulge-structure side surface.
See Fig. 5, etch second dielectric layer 600 and the first medium layer 400 of the first both sides, barrier layer 700, stop at the 3rd barrier layer 500 and the second barrier layer 300 respectively.
See Fig. 6, etching the 3rd barrier layer 500 and the second barrier layer 300, exposes the adhesion layer 200 on the first metal layer 100.
So the first medium layer 400 and the first barrier layer 700 be positioned at above first medium layer 400 that are positioned at bottom form cofferdam side wall 1400, and wherein, the height T3 on the first barrier layer 700 is 50nm-5 μm, and the height T1 of first medium layer 400 is 50nm-5 μm.
Cofferdam side wall 1400 corresponding fluted 1401, the cross sectional shape of groove 1401 is preferably any one or multiple combination in triangle, rectangle, polygon, circle, ellipse.Figure 21 illustrates several preferred embodiments of metal-insulator-metal capacitor further groove 1401 of the present utility model, wherein, Figure 21 (A), Figure 21 (B), Figure 21 (C), Figure 21 (D), Figure 21 (E) adopt regular hexagon, square, triangle, rectangle, circular groove design respectively, in the confined space, place multiple groove as far as possible, recess sidewall area is maximized, to increase the corresponding effective electrode area of the upper and lower pole plate of electric capacity, thus realize maximized capacitance density.
In above-mentioned etch step, preferably adopt barrier layer 300, anisotropic dry etch first barrier layer 700, second, the 3rd barrier layer 500, first medium layer 400, second dielectric layer 600.
See Fig. 7, form electric capacity bottom crown 800, BARC layer (anti-reflecting layer) 900 successively in cofferdam side wall 1400 and groove 1401 surface.
See Fig. 8, return etching BARC layer 900 to remove the electric capacity bottom crown 800 in noncapacitive region.It will be understood by those skilled in the art that the method removing bottom crown also realizes by additive method.
See Fig. 9, remove BARC layer 900, form capacitor dielectric layer 1000, electric capacity top crown 1100 successively, conductive plug layer 1200 is set on electric capacity top crown 1100.
See Figure 10, etching or grinding conductive plug layer 1200 flush to the second dielectric layer 600 of noncapacitive region surface, and remove capacitor dielectric layer 1000 and the electric capacity top crown 1100 in noncapacitive region, the second metal level 1300 is set on conductive plug layer 1200 with the second dielectric layer 600 of noncapacitive region surface.
Owing to removing the electric capacity bottom crown 800 in noncapacitive region before the step forming capacitor dielectric layer 1000, after the step forming electric capacity top crown 1100, remove capacitor dielectric layer 1000 and the electric capacity top crown 1100 in noncapacitive region, make the edge of capacitor dielectric layer 1000 extend across the edge of electric capacity bottom crown 800 with electrical isolation electric capacity top crown 1100 and electric capacity bottom crown 800.
In the present embodiment, the first metal layer 100 and the second metal level 1300 are metal level adjacent in noncapacitive region.In other embodiments unshowned, can also there are other metal levels between the first medium layer 400 in noncapacitive region, the 3rd barrier layer 500, then the first metal layer 100 and the second metal level 1300 are non-conterminous metal level in noncapacitive region.
According to the utility model embodiment 1 formed metal-insulator-metal capacitor as shown in Figure 10, it comprises: the first metal layer 100, on the first metal layer 100 definition have noncapacitive region, capacitor regions; Some cofferdam side wall 1400 that the first metal layer 100 in capacitor regions is arranged on the surface, described cofferdam side wall 1400 comprises the first medium layer 400 being positioned at bottom and the first barrier layer 700 be positioned on first medium layer 400, described cofferdam side wall 1400 corresponding fluted 1401; In electric capacity bottom crown 800, capacitor dielectric layer 1000, electric capacity top crown 1100 that cofferdam side wall 1400 and groove 1401 surface set gradually; The conductive plug layer 1200 arranged on electric capacity top crown 1100; The second metal level 1300 arranged on conductive plug layer 1200.
Preferably, in described cofferdam side wall 1400, the height T3 on described first barrier layer 700 is 50nm-5 μm, and the height T1 of described first medium layer 400 is 50nm-5 μm.
Preferably, the second barrier layer 300 is provided with between described first medium layer 400 and the first metal layer 100.
Preferably, described first barrier layer, barrier layer 700, second 300 is any one or the multiple combination in SiN, SiON, SiC, SiNC, SiONC.
Preferably, the edge of described capacitor dielectric layer 1000 extends across the edge of electric capacity bottom crown 800 with electrical isolation electric capacity top crown 1100 and electric capacity bottom crown 800.
Preferably, the cross sectional shape of described groove 1401 is any one or the multiple combination in triangle, rectangle, polygon, circle, ellipse.
Preferably, described the first metal layer 100 and described second metal level 1300 are metal level adjacent in noncapacitive region or non-conterminous metal level.
Preferably, the material of described electric capacity bottom crown 800 and described electric capacity top crown 1100 is any one or the multiple combination in aluminium copper, titanium, titanium nitride, tantalum, tantalum nitride, cobalt, tungsten, tungsten nitride, tungsten carbide.
Preferably, the material of described capacitor dielectric layer 1000 is high dielectric constant film (the such as ZrO that dielectric constant K is greater than 3.9
2, Al
2o
3, Si
3n
4, HfO
2, Y
2o
3, SiO
2, Ta
2o
5, La
2o
3, TiO
2) in any one or multiple combination.
Preferably, the material of described conductive plug layer 1200 is any one or the multiple combination in tungsten, copper, titanium, titanium nitride, tantalum, tantalum nitride, cobalt, tungsten nitride, tungsten carbide.
Preferably, the material of the first metal layer 100 and the second metal level 1300 is any one or the multiple combination in aluminium, copper, aluminium copper, titanium, titanium nitride, tantalum, tantalum nitride.
embodiment 2
Figure 11-Figure 20 is the process schematic of the manufacture method of metal-insulator-metal capacitor according to the utility model embodiment 2.
See Figure 11, provide the first metal layer 2100, define noncapacitive region, capacitor regions on the first metal layer 2100, Figure 11 only illustrates the structure of wherein capacitor regions at this, and the structure in not shown noncapacitive region.
In capacitor regions, form first medium layer 2400 on the surface in the first metal layer 2100.Wherein, the gross thickness T0 of first medium layer 2400 is 50nm-5 μm.In addition, preferably before the step forming first medium layer 2400, on the first metal layer 2100, adhesion layer 2200, second barrier layer 2300 is formed successively.Wherein, adhesion layer 2200 is generally TiN layer, and the second barrier layer 2300 can be any one or multiple combination in SiN, SiON, SiC, SiNC, SiONC.
See Figure 12, etching first medium layer 2400 to preset thickness T0 ', forms some bulge-structures 2401.Wherein, the preset thickness T0 ' of etching first medium layer 2400 is 50nm-5 μm, and preset thickness T0 ' is less than the gross thickness T0 of first medium layer 2400.
See Figure 13, form the first barrier layer 2500 in first medium layer 2400 surface.First barrier layer 2500 can be any one or multiple combination in SiN, SiON, SiC, SiNC, SiONC
See Figure 14, the first barrier layer 2500 of etching bulge-structure 2401 top surface, the first barrier layer 2500 between etching bulge-structure 2401, retains the hard mask of the first barrier layer 2500 as subsequent etching of bulge-structure side surface.
See Figure 15, etch the first medium layer 2400 of the first both sides, barrier layer 2500.
See Figure 16, etch the second barrier layer 2300, expose the adhesion layer 2200 on the first metal layer 2100.
So, the first medium layer 2400 and the first barrier layer 2500 be positioned at above first medium layer 2400 that are positioned at bottom form cofferdam side wall 3200, wherein, the height T5 on the first barrier layer 2500 is 50nm-5 μm, and the height T4 of first medium layer 2400 is 50nm-5 μm.
Cofferdam side wall 3200 corresponding fluted 3201, the cross sectional shape of groove 3201 is preferably any one or multiple combination in triangle, rectangle, polygon, circle, ellipse.Figure 22 illustrates several preferred embodiments of metal-insulator-metal capacitor further groove 3201 of the present utility model, wherein, Figure 22 (A), Figure 22 (B), Figure 22 (C), Figure 22 (D), Figure 22 (E) adopt regular hexagon, square, triangle, rectangle, circular groove design respectively, in the confined space, place multiple groove as far as possible, recess sidewall area is maximized, to increase the corresponding effective electrode area of the upper and lower pole plate of electric capacity, thus realize maximized capacitance density.
In above-mentioned etch step, preferably adopt barrier layer 2300, anisotropic dry etch first barrier layer 2500, second, first medium layer 2400.
See Figure 17, form electric capacity bottom crown 2600, BARC layer (anti-reflecting layer) 2700 successively in cofferdam side wall 3200 and groove 3201 surface.
See Figure 18, return etching BARC layer 2700 to remove the electric capacity bottom crown 2600 in noncapacitive region.It will be understood by those skilled in the art that the method removing bottom crown also realizes by additive method.
See Figure 19, remove BARC layer 2700, form capacitor dielectric layer 2800, electric capacity top crown 2900 successively, conductive plug layer 3000 is set on electric capacity top crown 2900.
See Figure 20, etching or grinding conductive plug layer 3000 flush to the first medium layer 2400 of noncapacitive region surface, and remove capacitor dielectric layer 2800 and the electric capacity top crown 2900 in noncapacitive region, the second metal level 3100 is set on conductive plug layer 3000 with the first medium layer 2400 of noncapacitive region surface.
Owing to removing the electric capacity bottom crown 2600 in noncapacitive region before the step forming capacitor dielectric layer 2800, after the step forming electric capacity top crown 2900, remove capacitor dielectric layer 2800 and the electric capacity top crown 2900 in noncapacitive region, make the edge of capacitor dielectric layer 2800 extend across the edge of electric capacity bottom crown 2600 with electrical isolation electric capacity top crown 2900 and electric capacity bottom crown 2600.
In the present embodiment, the first metal layer 100 and the second metal level 1300 are metal level adjacent in noncapacitive region.In other embodiments unshowned, first medium layer 2400 in noncapacitive region can comprise multiple dielectric layer be spaced, can also there is other metal level between these multiple dielectric layers be spaced, then the first metal layer 2100 and the second metal level 3100 are non-conterminous metal level in noncapacitive region.
According to the metal-insulator-metal capacitor of the utility model embodiment 2 as shown in figure 20, it comprises: the first metal layer 2100, and on the first metal layer 2100, definition has noncapacitive region, capacitor regions; Some cofferdam side wall 3200 that the first metal layer 2100 in capacitor regions is arranged on the surface, described cofferdam side wall 3200 comprises the first medium layer 2400 being positioned at bottom and the first barrier layer 2500 be positioned on first medium layer 2400, described cofferdam side wall 3200 corresponding fluted 3201; In electric capacity bottom crown 2600, capacitor dielectric layer 2800, electric capacity top crown 2900 that cofferdam side wall 3200 and groove 3201 surface set gradually; The conductive plug layer 3000 arranged on electric capacity top crown 2900; The second metal level 3100 arranged on conductive plug layer 3000.
Preferably, in described cofferdam side wall 3200, the height T5 on the first barrier layer 2500 is 50nm-5 μm, and the height T4 of first medium layer 2400 is 50nm-5 μm.
Preferably, the second barrier layer 2300 is provided with between described first medium layer 2400 and the first metal layer 2100.
Preferably, described first barrier layer, barrier layer 2500, second 2300 is any one or the multiple combination in SiN, SiON, SiC, SiNC, SiONC.
Preferably, the edge of described capacitor dielectric layer 2800 extends across the edge of electric capacity bottom crown 2600 with electrical isolation electric capacity top crown 2900 and electric capacity bottom crown 2600.
Preferably, the cross sectional shape of described groove 3201 is any one or the multiple combination in triangle, rectangle, polygon, circle, ellipse.
Preferably, described the first metal layer 2100 and described second metal level 3100 are metal level adjacent in noncapacitive region or non-conterminous metal level.
Preferably, the material of described electric capacity bottom crown 2600 and described electric capacity top crown 2900 is any one or the multiple combination in aluminium copper, titanium, titanium nitride, tantalum, tantalum nitride, cobalt, tungsten, tungsten nitride, tungsten carbide.
Preferably, the material of described capacitor dielectric layer 2800 is high dielectric constant film (the such as ZrO that dielectric constant K is greater than 3.9
2, Al
2o
3, Si
3n
4, HfO
2, Y
2o
3, SiO
2, Ta
2o
5, La
2o
3, TiO
2) in any one or multiple combination.
Preferably, the material of described conductive plug layer 3000 is any one or the multiple combination in tungsten, copper, titanium, titanium nitride, tantalum, tantalum nitride, cobalt, tungsten nitride, tungsten carbide.
Preferably, the material of the first metal layer 2100 and the second metal level 3100 is any one or the multiple combination in aluminium, copper, aluminium copper, titanium, titanium nitride, tantalum, tantalum nitride.
The utility model is by adopting the MIM capacitor of stereochemical structure, add the effective electrode area that the upper and lower pole plate of electric capacity is corresponding, improve capacitance density (by adopting different sizes and material, the capacitance density of stereochemical structure MIM capacitor of the present utility model can reach the 10-200 of existing planar structure MIM capacitor doubly), larger capacitance can be realized on limited chip area, meet the demand of the bulky capacitor integrated circuit such as LCD drive circuit, RFCMOS circuit, electric capacity in the sheet being suitable for being applied to integrated circuit.
Although the utility model discloses as above, the utility model is not defined in this.Any those skilled in the art, not departing from spirit and scope of the present utility model, all can make various changes or modifications, and therefore protection range of the present utility model should be as the criterion with claim limited range.
Claims (7)
1. a metal-insulator-metal capacitor, electric capacity in the sheet being suitable for being applied to integrated circuit, is characterized in that, comprising:
The first metal layer, on the first metal layer, definition has noncapacitive region, capacitor regions;
Some cofferdam side wall that the first metal layer in capacitor regions is arranged on the surface, described cofferdam side wall comprises the first medium layer being positioned at bottom and the first barrier layer be positioned on first medium layer, and described cofferdam side wall correspondence is fluted;
In electric capacity bottom crown, capacitor dielectric layer, electric capacity top crown that cofferdam side wall and groove surfaces set gradually;
The conductive plug layer arranged on electric capacity top crown;
The second metal level arranged on conductive plug layer.
2. metal-insulator-metal capacitor as claimed in claim 1, it is characterized in that, in the side wall of described cofferdam, described first barrier layer height is 50nm-5 μm, and described first medium layer height is 50nm-5 μm.
3. metal-insulator-metal capacitor as claimed in claim 1, is characterized in that, be provided with the second barrier layer between described first medium layer and the first metal layer.
4. metal-insulator-metal capacitor as claimed in claim 1, it is characterized in that, the edge of described capacitor dielectric layer extends across the edge of electric capacity bottom crown with electrical isolation electric capacity top crown and electric capacity bottom crown.
5. metal-insulator-metal capacitor as claimed in claim 1, is characterized in that, the cross sectional shape of described groove is any one or multiple combination in triangle, rectangle, polygon, circle, ellipse.
6. metal-insulator-metal capacitor as claimed in claim 1, it is characterized in that, described the first metal layer and described second metal level are metal level adjacent in noncapacitive region or non-conterminous metal level.
7. metal-insulator-metal capacitor as claimed in claim 1, it is characterized in that, described conductive plug layer flushes with the dielectric layer of noncapacitive region surface, and described second metal level is arranged on the dielectric layer of described conductive plug layer and described noncapacitive region surface.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201520792014.1U CN205177824U (en) | 2015-10-13 | 2015-10-13 | Metal level - insulating layer - metal level condenser |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201520792014.1U CN205177824U (en) | 2015-10-13 | 2015-10-13 | Metal level - insulating layer - metal level condenser |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN205177824U true CN205177824U (en) | 2016-04-20 |
Family
ID=55741774
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201520792014.1U Withdrawn - After Issue CN205177824U (en) | 2015-10-13 | 2015-10-13 | Metal level - insulating layer - metal level condenser |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN205177824U (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105304609A (en) * | 2015-10-13 | 2016-02-03 | 格科微电子(上海)有限公司 | Metal layer-insulating layer-metal layer capacitor and manufacturing method thereof |
-
2015
- 2015-10-13 CN CN201520792014.1U patent/CN205177824U/en not_active Withdrawn - After Issue
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105304609A (en) * | 2015-10-13 | 2016-02-03 | 格科微电子(上海)有限公司 | Metal layer-insulating layer-metal layer capacitor and manufacturing method thereof |
| CN105304609B (en) * | 2015-10-13 | 2019-12-17 | 格科微电子(上海)有限公司 | Metal layer-insulating layer-metal layer capacitor and manufacturing method thereof |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN105226046A (en) | Metal-insulator-metal capacitor and preparation method thereof | |
| CN205069629U (en) | Metal level - insulating layer - metal level condenser | |
| TWI553885B (en) | Capacitor and method of manufacturing the same | |
| KR20160092463A (en) | Metal-insulator-metal (mim) capacitors and forming methods | |
| US20140104745A1 (en) | Mim capacitor and fabrication method thereof | |
| CN104103495A (en) | Semiconductor device with MIM capacitor and formation method thereof | |
| TWI543340B (en) | Semiconductor arrangement and method for forming the same | |
| CN103346148B (en) | A kind of Vertical-type capacitor structure and preparation method thereof | |
| CN108573971B (en) | Organization of semiconductor memory | |
| CN105845668B (en) | Mim capacitor structure and preparation method thereof | |
| CN205177824U (en) | Metal level - insulating layer - metal level condenser | |
| CN101378057B (en) | Metal-insulator-metal capacitor and method for manufacturing the same | |
| US20090059466A1 (en) | Metal-insulator-metal capacitor and method for manufacturing the same | |
| CN102751176B (en) | Manufacture method for PIP (poly-insulator-poly) and PPS (polypropylene film) capacitor | |
| CN105304609A (en) | Metal layer-insulating layer-metal layer capacitor and manufacturing method thereof | |
| CN103700645A (en) | MOM (metal-oxide-metal) capacitor and manufacturing method thereof | |
| US9196620B2 (en) | Semiconductor devices and methods of manufacturing the same | |
| CN105097765A (en) | Mim capacitor structure and manufacturing method thereof | |
| CN103426728A (en) | Capacitor structure and manufacturing method thereof | |
| CN105590923B (en) | Mim capacitor and forming method thereof | |
| TWI466172B (en) | Manufacturing method of semiconductor devices | |
| CN203859119U (en) | MIM capacitor and semiconductor device comprising MIM capacitor | |
| CN104659031A (en) | Integrated structure of MOS capacitors with different capacitance densities in RFLDMOS technology and manufacturing method of integrated structure | |
| TWI602309B (en) | Capacitor structure and manufacturing method thereof | |
| CN110416191A (en) | A kind of integrated MIM capacitor and its manufacturing method |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| AV01 | Patent right actively abandoned |
Granted publication date: 20160420 Effective date of abandoning: 20191217 |
|
| AV01 | Patent right actively abandoned |