The present invention relates to the provision of metal shield trenches and metal substrate contacts within the premetallization dielectric layer of an integrated circuit. In a specific implementation for a front-side illuminated light sensor, the metal shield trenches provide an optical shield to prevent light intrusion onto sensitive circuitry.
Front-side illuminated light sensors are well known in the art. The photosensitive region on the front side of the light sensor generates charges when exposed to light. Those charges are accumulated during an integration phase within the photosensitive region and transferred to a memory area. During a next integration phase, the previously transferred charges are read out from the memory area using a read circuit.
It is important for the light sensor to include some optical shielding. For example, optical shielding may be provided between adjacent light sensors in an imaging array in order to ensure that the light directed toward one photosensitive region does not impinge on an adjacent photosensitive region. Additionally, optical shielding may be provided within the light sensor over the memory area in order to ensure that light directed toward the photosensitive region does not additionally generate charges in the memory area.
A premetallization dielectric (PMD) layer is typically provided at the front side of the light sensor. Metal substrate contacts pass through the PMD layer to electrically connect the integrated circuitry in and on the substrate to the metal lines supported within overlying metallization layers. There is a need in the art to support both metal shield trenches and metal substrate contacts within the PMD layer.
In an embodiment, an integrated circuit comprises: a semiconductor substrate including a doped source or drain region for a transistor; a contact etch stop layer overlying the semiconductor substrate; a premetallization dielectric layer overlying the contact etch stop layer; a first trench filled with a metal material, said first trench extending through the premetallization dielectric layer and having a bottom terminating at or in, without passing through, the contact etch stop layer; and a second trench filled with a metal material that is the same metal material filling the first trench, said second trench extending through the premetallization dielectric layer and the contact etch stop layer and having a bottom terminating at or in, without passing through, the doped source or drain region.
In an embodiment, a method comprises: forming a conductive region supported by a semiconductor substrate; depositing a contact etch stop layer overlying the semiconductor substrate and covering the conductive region; depositing a premetallization dielectric layer overlying the contact etch stop layer; forming a first trench in the premetallization dielectric layer, said first trench extending through the premetallization dielectric layer and having a bottom terminating at or in, without passing through, the contact etch stop layer; filling said first trench with a non-conductive material; forming a second trench in the premetallization dielectric layer, said second trench extending through the premetallization dielectric layer and the contact etch stop layer and having a bottom terminating at or in, without passing through, the conductive region; removing the non-conductive material from the first trench; and filling the first and second trenches with a same metal material.
In an embodiment, a method comprises: forming a doped source or drain region for a transistor in a semiconductor substrate; depositing a contact etch stop layer overlying the semiconductor substrate; depositing a premetallization dielectric layer overlying the contact etch stop layer; forming a first trench in the premetallization dielectric layer, said first trench extending through the premetallization dielectric layer and having a bottom terminating at or in, without passing through, the contact etch stop layer; filling said first trench with a non-conductive material; forming a second trench in the premetallization dielectric layer, said second trench extending through the premetallization dielectric layer and the contact etch stop layer and having a bottom terminating at or in, without passing through, the doped source or drain region; removing the non-conductive material from the first trench; and filling the first and second trenches with a same metal material.
In an embodiment, a method comprises: forming a transistor having a gate over a semiconductor substrate; depositing a contact etch stop layer overlying the semiconductor substrate; depositing a premetallization dielectric layer overlying the contact etch stop layer; forming a first trench in the premetallization dielectric layer, said first trench extending through the premetallization dielectric layer and having a bottom terminating at or in, without passing through, the contact etch stop layer; filling said first trench with a non-conductive material; forming a second trench in the premetallization dielectric layer, said second trench extending through the premetallization dielectric layer and the contact etch stop layer and having a bottom terminating at or in, without passing through, the gate of transistor; removing the non-conductive material from the first trench; and filling the first and second trenches with a same metal material.
In an embodiment, a method comprises: forming a capacitive deep trench isolation structure in a semiconductor substrate, the capacitive deep trench isolation structure including a conductive region; depositing a contact etch stop layer overlying the semiconductor substrate; depositing a premetallization dielectric layer overlying the contact etch stop layer; forming a first trench in the premetallization dielectric layer, said first trench extending through the premetallization dielectric layer and having a bottom terminating at or in, without passing through, the contact etch stop layer; filling said first trench with a non-conductive material; forming a second trench in the premetallization dielectric layer, said second trench extending through the premetallization dielectric layer and the contact etch stop layer and having a bottom terminating at or in, without passing through, the conductive region of the capacitive deep trench isolation structure; removing the non-conductive material from the first trench; and filling the first and second trenches with a same metal material.
For a better understanding of the embodiments, reference will now be made by way of example only to the accompanying figures in which:
Reference is now made to
In operation, light is received at the photosensitive region 14 and charges are generated. Those charges are accumulated during an integration phase within the photosensitive region 14 (for example, in the doped region 36). After the integration period terminates, the accumulated charges are transferred from the photosensitive region 14 to the memory region 18. During a next exposure integration phase, the transferred charges in the memory region 18 are read out using read circuitry associated with the sensing node region 20 and the signal treatment region 22.
The plan view of
The plan views of
Reference is now made to
A multi-layer 100 comprising a bottom antireflective coating (BARC) and a resist is deposited on the top surface 68 of the PMD layer 66. The deposition may be made, for example, using a lithographic deposition by spin-on process. Conventional lithographic processing techniques known to those skilled in the art are then used to pattern the multi-layer 100 and form openings 102 at the locations where it is desired to provide metal shield trenches 50. The result is shown in
The lithographically patterned multi-layer 100 is then used as an etch mask. An etch is then performed to remove portions of the PMD layer 66 in alignment with the openings 102 and form openings 102a. The etch may, for example, comprise a reactive ion etch (RIE). The etch is controlled to stop at (or in), without passing through, the contact etch stop layer 60. The result is shown in
The multi-layer 100 is then removed using an in situ strip on reactive ion etching reactor. The result is shown in
An organic planarization layer (OPL) 108 is then deposited using a lithographic deposition by spin-on process. The material fills the openings 102a in the PMD layer 66. A silicon-containing anti-reflective coating (SiARC) layer 112 is then deposited on the organic planarization layer 108 using a lithographic deposition by spin-on process. Finally, a resist layer 116 is deposited on the SiARC layer 112 using a lithographic deposition by spin-on process. Conventional lithographic processing techniques known to those skilled in the art are then used to pattern the resist layer 116 and form openings 122 at the locations where it is desired to provide metal contacts 46. The result is shown in
The lithographically patterned resist layer 116 is then used as an etch mask. An etch is then performed to remove portions of the SiARC layer 112, the organic planarization layer 108, the PMD layer 66 and the contact etch stop layer 66 in alignment with the openings 122 and form openings 122a. The etch may, for example, comprise a reactive ion etch (RIE). The etch is controlled to stop at (or in), without passing through, the gate structure 44 for the MOS transistor, the substrate 26 at the source/drain region for the MOS transistor and the conductive material 32 of the CDTI structure 12. The result is shown in
The lithographically patterned resist layer 116, the SiARC layer 112 and the organic planarization layer 108 are then removed leaving openings 130a at locations where it is desired to provide metal shield trenches 50 and locations 130b where it is desired to provide metal contacts 46. An in situ strip on reactive ion etching reactor may be used for this removal. The result is shown in
The openings 130a and 130b are then filled with a metal material, such as tungsten, to form the metal shield trenches 50 and metal contacts 46. A TiN liner may first be deposited followed by a tungsten deposition. The result is shown in
The foregoing description has provided by way of exemplary and non-limiting examples a full and informative description of the exemplary embodiment of this invention. However, various modifications and adaptations may become apparent to those skilled in the relevant arts in view of the foregoing description, when read in conjunction with the accompanying drawings and the appended claims. However, all such and similar modifications of the teachings of this invention will still fall within the scope of this invention as defined in the appended claims.
This application is a divisional of U.S. patent application Ser. No. 15/263,922 filed Sep. 13, 2016, the disclosure of which is incorporated by reference.
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9236407 | Roy et al. | Jan 2016 | B2 |
9543320 | Pang | Jan 2017 | B2 |
9547125 | Assefa | Jan 2017 | B2 |
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20160150169 | Hynecek | May 2016 | A1 |
20170062495 | Huang | Mar 2017 | A1 |
Number | Date | Country | |
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20180158861 A1 | Jun 2018 | US |
Number | Date | Country | |
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Parent | 15263922 | Sep 2016 | US |
Child | 15866995 | US |