The disclosure relates to the field of semiconductor, and in particular to a contact window structure, a metal plug and a forming method thereof, and a semiconductor structure.
With the development of integrated circuit to super-large scale integrated circuits, the circuit density inside the integrated circuits is increasing, and the number of components included in the integrated circuits is also increasing. Such development makes the surface of a wafer unable to provide enough area to make required interconnecting wires.
In order to meet the requirement of interconnecting wires after scaling down of the components, the design of two or more layers of multi-layer metal interconnecting wires has become a commonly used method in the super large-scale integrated circuit technology. At present, the conduction between different metal layers or between a metal layer and a pad layer can be realized by a metal plug. As the integration of devices becomes higher and higher, the depth-to-width ratio of vias formed in the process of forming the metal plug continues to increase, which leads to compromised performance relative to the circuit requirements proposed by the designer.
A technical problem to be solved by embodiments of the disclosure is to provide a contact window structure, a metal plug and a forming method thereof to reduce a phenomenon that a critical size of a bottom of a via is greater than a critical size of a top of the via, and overcome the problem that a size of the via slightly shrinks in an etching process.
Embodiments of the disclosure provide a forming method of a contact window structure, which may include:
The embodiments of the disclosure further provide a contact window structure, which may include:
The embodiments of the disclosure further provide a semiconductor structure, which may include:
The embodiments of the disclosure further provide a metal plug, which may include:
With reference to
As the integration of devices becomes higher and higher, a depth-to-width ratio of vias formed in the dielectric layer continues to increase, and the via with high depth-to-width ratio is a big challenge for the etching process. Generally, in a downward etching process, the via gradually narrows, and a critical size 21 of a bottom of the via 104 is smaller than a critical size of a top of the via 104. In this slight shrinkage process, the performance of the circuit may be compromised relative to circuit requirements proposed by the designer. In addition, the window size in the bottom layer of the via usually limit a resistance value of the whole contact window, and the slightly shrunk size may greatly reduce the contact area with the target metal layer. As stated in the background, a slight shrink phenomena may occur in the existing process for forming the via, especially for the via with a high depth-to-width ratio, and this phenomena results in that the size of the bottom of the via is smaller than that of the top of the via, and the contact resistance is increased.
Therefore, the embodiments of the disclosure provide a contact window structure, a metal plug and a forming method thereof, as well as a semiconductor structure. The method of forming the contact window structure includes the following steps. A target layer is provided. An annular pad is formed on a surface of the target layer, and a central via, from which partial surface of the target layer is exposed, in the middle part of the annular pad. A dielectric layer covering the target layer and the annular pad is formed. The dielectric layer is etched to form an etch hole connected to the central via in the dielectric layer. The annular pad is removed to form the contact window structure. Through forming the annular pad, in forming the contact window structure, after the annular pad is removed, a size of the central via may be enlarged, so that a size of a bottom of the contact window structure may be enlarged; and in forming the metal plug in the contact window structure, a contact area between a bottom of the metal plug and the target layer may be increased, and a contact resistance between the two is reduced. Furthermore, due to the existence of the annular pad, a depth or depth-to-width ratio of the etch hole formed in the dielectric layer may be reduced, so that the difficulty in forming hole etching is reduced, and therefore, in forming the etch hole, there is no need to increase the size of the etch hole or even may reduce the size of the etch hole to improve the integration, that is, a size of a top of the formed contact window structure may be the same as or smaller than a size of a top formed according to the related technology, while the size of the bottom of the formed contact window structure is increased.
In order to make the objectives, features and advantages of the embodiments of the disclosure more apparent and understandable, specific implementation of the disclosure will be described in detail below in combination with the drawings.
When describing the embodiments of the present disclosure in detail, for ease of description, the schematic diagrams will not be partially enlarged according to a general scale, and the schematic diagrams are only examples, which should not limit the protection scope of the embodiments of the present disclosure herein. Respective to describing the embodiments of the disclosure in detail, for ease of description, the schematic diagrams will be partially enlarged at a non-normal scale, and the schematic diagrams are only examples, which should not limit the protection scope of the embodiments of the disclosure herein. Furthermore, a three-dimensional space size of length, width and depth should be included in practical manufacturing.
Referring to
In some embodiments, the substrate 201 may be a semiconductor substrate. The target layer 202 may be a doped region (for example, a region doped with N-type impurity ions or doped with P-type impurity ions) located in the semiconductor substrate or a metal silicide region (for example, a nickel silicide region or a cobalt silicide region) located in the semiconductor substrate. The semiconductor substrate may be made of silicon (Si), germanium (Ge) or silicon-germanium (GeSi), silicon carbide (SiC); or may be Silicon-on-Insulator (SOI), Germanium-on-Insulator (GOI); or may be other materials, for example, group III-V compounds such as gallium arsenide.
In other embodiments, the substrate 201 may include the semiconductor substrate and an interlevel dielectric layer located on the semiconductor substrate, and the target layer 202 is located in the interlevel dielectric layer. The interlevel dielectric layer may has a monolayer or multilayer stack structure, the target layer 202 may be a metal layer, and the metal layer may be connected with a conductive structure (for example, a conductive plug) formed in the lower dielectric layer.
The surface of the target layer 202 may be flush with a surface of the substrate 201, or is slightly higher than the surface of the substrate 201.
There may be one or more (greater than or equal to 2) target layers 202 formed in the substrate 201. When there are multiple target layers 202, adjacent target layers are separated from each other. The substrate 201 with only one target layer 202 is illustrated as an example in this embodiment.
An annular pad is to be formed on the target layer 202 subsequently. For the subsequent forming of the annular pad, in one embodiment, a columnar structure 204 is formed on partial surface of the target layer 202.
The columnar structure 204 determines a position and a shape of the subsequently formed annular pad. The columnar structure may be of a cylindrical shape or an elliptic cylindrical shape, or other suitable shapes (a cube shape or an oblong shape). A bottom area of the columnar structure 204 is smaller than an area of the target layer 202.
A material of the columnar structure 204 may be different from materials of the target layer 202, the substrate 201 and the subsequently formed annular pad. In the subsequent process of removing the columnar structure 204, the columnar structure 204 has a higher etch selectivity ratio than that for the target layer 202, the substrate 201 and the annular pad, and etching damage to the target layer 202, the substrate 201 and the annular pad is reduced or prevented.
The columnar structure 204 may be made of a photoresist material or a mask material. The mask material may be one or more of silicon nitride, silicon oxide, silicon carbonitride, silicon oxynitride, polysilicon, amorphous silica, amorphous carbon and low-K dielectric material.
In one embodiment, the columnar structure 204 is made of the photoresist material, and the process of forming the columnar structure 204 includes the following steps. A photoresist layer is formed on the substrate 201 and the target layer 202. The photoresist layer is subjected to exposure and development to form the columnar structure on the target layer 202.
In another embodiment, the columnar structure 204 is made of the mask material, and the process of forming the columnar structure 204 includes the following steps. A mask material layer is formed on the substrate 201 and the target layer 202. The mask material layer is subjected to etching to form the columnar structure on the target layer 202.
Referring to
The pad material layer 205 is subsequently used for forming the annular pad. The pad material layer 205 is made of a material different from that of the subsequently formed dielectric layer. In forming an etching hole in the dielectric layer subsequently, the dielectric layer has a higher etch selectivity ratio relative to that of the annular pad.
The pad material layer 205 may be made of one or more of silicon nitride, silicon oxide, silicon carbonitride and silicon oxynitride. The pad material layer is formed by using a chemical vapor deposition process.
A thickness of the pad material layer 205 determines a width of the subsequently formed annular pad and an enlarged size of a central via. The thickness of the pad material layer is 3 times or more of the size of the columnar structure or the subsequently formed central via. At the forgoing specific proportion, a size of a bottom of the central via may be efficiently enlarged in the subsequent process, so as to enable the central via to meet practical requirements. The thicker the deposited pad material layer is, the larger the size and area of the window after the pad material is removed is.
Referring to
The pad material layer is etched by an anisotropic dry etching process, which may be a plasma etching process.
Through the formed annular pad 203, in the subsequent process of forming a contact window structure, when the annular pad is removed, the size of the central via may be enlarged, so that the size of the bottom of the contact window structure may be enlarged; and in forming a metal plug in the contact window structure, a contact area between a bottom of the metal plug and the target layer may be increased, and a contact resistance between the bottom of the metal plug and the target layer is reduced. Furthermore, due to the existence of the annular pad, a depth or depth-to-width ratio of the etch hole formed in the dielectric layer may be reduced, so that the difficulty of forming hole etching is reduced. and therefore, there is no need to increase the size of the etch hole to form the etch hole, or the size of the etch hole may even be reduced to improve the integration. That is, a size of a top of the formed contact window structure may be the same as or smaller than a size of a top formed according to the related technology, while the size of the bottom of the formed contact window structure is increased.
Referring to
The columnar structure may be removed by wet etching or dry etching. In removing the columnar structure, an etch solution or etch gas with a higher etch selectivity ratio is used for the columnar structure relative to that for the annular pad 203, the target layer 202 and the substrate 201.
Another embodiment of the disclosure further provides a method of forming the annular pad 203. Referring to
The mask material layer 206 may be made of one or more of photoresist, silicon nitride, silicon oxide, silicon carbonitride, silicon oxynitride, polysilicon, amorphous silica, amorphous carbon and low-K dielectric material. The mask material layer 206 may be formed by using the chemical vapor deposition process.
In one embodiment, the mask material layer 206 is made of a photoresist material, and the first via 207 is formed in the mask material layer 206 by exposure and developing processes. When the mask material layer 206 is made of other materials, the first via 207 may be formed in the mask material layer 206 by an etching process.
A shape and a position of the first via 207 determines a shape and a position of the subsequently formed annular pad.
Referring to
The pad material layer 208 is subsequently used for forming the annular pad. The pad material layer 208 is made of a material different from that of a subsequently formed dielectric layer. In forming an etching hole in the dielectric layer subsequently, the dielectric layer has a higher etch selectivity ratio that that of the annular pad.
The pad material layer 208 may be made of one or more of silicon nitride, silicon oxide, silicon carbonitride and silicon oxynitride. The pad material layer is formed by using the chemical vapor deposition process.
A thickness of the pad material layer 208 determines a width of the subsequently formed annular pad and an enlarged size of a central through hole. In one embodiment, the thickness of the pad material layer 208 is 3 times or more of the size of the columnar structure or the subsequently formed central via.
Referring to
The pad material layer is etched by an anisotropic dry etching process, which may be a plasma etching process.
In one embodiment, the mask material layer 206 is removed after forming the annular pad 203. The mask material layer 206 may be removed by a wet etching process or a dry etching process.
In another embodiment, if the mask material layer 206 is made of an isolation material and may be used for electrical isolation between devices, for example, when the mask material layer is made of a material the same as that of the subsequently formed dielectric layer, after the annular pad 203 is formed, the mask material layer 206 is retained, and the dielectric layer is directly formed on the mask material layer 206 subsequently, so that there is no need of an additional step to remove the mask material layer 206.
Referring to
Referring to
The dielectric layer 211 is made of a material different from that of the annular pad 203. The dielectric layer 211 may be made of one of silicon nitride, silicon oxide, silicon carbonitride and silicon oxynitride.
The dielectric layer 211 is formed by chemical vapor deposition. In one embodiment, the dielectric layer 211 may be flatted by a flattening process, such that the dielectric layer 211 has a flat surface. The flattening process may be a chemical mechanical grinding process.
In one embodiment, the central via in the middle part of the annular pad 203 may be fully filled with the formed dielectric layer 211. In another embodiment, the central via may be partially filled or not filled with the dielectric layer 211. An air gap is formed in the annular pad. After the subsequent step of forming the etch hole in the dielectric layer, when continuing downward etching, it is very easy to expose the central via in the middle part of the annular pad 203 again, so as to prevent the influence on the size of the etch hole due to excessive long etching time. In one embodiment, the air gap is formed by adjusting a step coverage rate of a depositing process during forming of the dielectric layer 211.
In another embodiment, before the dielectric layer is formed, the central via in the middle part of the annular pad 203 may be filled with a sacrificial layer. In a subsequent step of etching the dielectric layer to form the etch hole, an etching rate of the sacrificial layer is greater than an etching rate of the dielectric layer, so that it is also very easy to expose the central via in the annular pad 203 again, so as to prevent the influence on the size of the etch hole due to excessive long etching time. In one embodiment, when the dielectric layer material is silicon oxide, the sacrificial layer may be made of a semiconductor insulation material such as silicon nitride, silicon oxynitride, silicon carbonitride or silicon oxycarbide. Referring to
In one embodiment, before the dielectric layer 211 is etched, a patterned mask layer (for example, a patterned photoresist layer or a stack structure of patterned hard mask layers and photoresist layers) is formed on the dielectric layer 211. The patterned mask layer is used as a mask to etch the dielectric layer 211.
After the etch hole 212 is formed, a material (for example, a dielectric layer material or a sacrificial layer material) filled in the central via 213 in the bottom of the etch hole 212 is continuously etched, so as to expose the central via 213 again and enable the etch hole 212 to be connected to the central via 213.
In one embodiment, the etch hole 212 formed in the dielectric layer 211 still has a high depth-to-width ratio, so that the size of the top of the formed etch hole 212 will be smaller than that of the bottom of the etch hole 212, that is, in a direction from an upper surface to a lower surface of the dielectric layer 211, the size of the etch hole 212 is gradually reduced. In other embodiments, the size of the top of the etch hole and the size of the bottom of the etch hole may be the same.
In one embodiment, the dielectric layer 211 may be etched by an anisotropic dry etching process, such as an anisotropic plasma etching process. For etching the dielectric layer 211 to form the etch hole 212, the dielectric layer 211 has a high etch selectivity ratio relative to the annular pad 203 (a specific etch selectivity ratio may be greater than or equal to 2:1). A bottom position of the etch hole 212 may be defined by the annular pad 203, and a diameter of the bottom of the etch hole 212 is smaller than an outer diameter of the annular pad 203.
Referring to
The annular pad may be removed by an isotropic wet or dry etching process. In one embodiment, when the material of the annular pad 203 is silicon nitride, the annular pad 203 is removed by wet etching. An etching solution used for the wet etching is hot phosphoric acid.
After the etched pad is removed, the size of the central via 213 is enlarged, such that a size 22 of the central via 213 will be greater than a size 23 of the bottom of the etch hole 212, that is, the size of the bottom of the formed contact window is increased relative to the size of the bottom of the contact window structure formed according to the related technology. In a subsequent process of forming a metal plug in the contact window structure, a contact area between a bottom of the metal plug and the target layer may be increased, and a contact resistance between the bottom of the metal plug and the target layer is reduced.
In one embodiment, in the process of forming the contact window, the target layer 202 is partially etched.
In one embodiment, referring to
The metal plug 214 is made of metal or other suitable conductive materials.
In one embodiment, a process of forming the metal plug 214 includes the following steps. A conductive material layer is formed on the contact window structure and a surface of the dielectric layer 211. The contact window structure is fully filled with the conductive material layer. The conductive material layer may be formed from metal (for example, tungsten) through a sputtering process. The conductive material layer higher than the surface of the dielectric layer 211 is removed by a chemical mechanical grinding process, and the metal plug 214 is formed in the contact window structure.
In another embodiment, after the contact window structure is formed, a capacitor structure is formed in the contact window structure.
The embodiments of the disclosure further provide a semiconductor structure. Referring to
The annular pad 203 is located on a surface of the target layer 202, and a central via 213, from which partial surface of the target layer 202 is exposed, is formed in the middle part of the annular pad 203.
The dielectric layer 211 covers the target layer 202 and the annular pad 203.
The etch hole 212 is located in the dielectric layer 211 and is connected to the central via 213.
It should be noted that definition or description of similar or same structures in the present embodiment (the semiconductor structure) and the forgoing embodiments (the forming process of the contact window structure) will not be defined in the present embodiment. Referring to the definition or description in the corresponding sections of the foregoing embodiments for details.
Another embodiment of the disclosure further provides a contact window structure. Referring to
The dielectric layer 211 is located on the target layer 202.
The contact window is located in the dielectric layer 211. The contact window includes an etch hole 212 and a central via 213 connected to each other. The etch hole 212 is located above the central via 213. Partial surface of the target layer is exposed from the central via 213. A size of the central via 213 is greater than that of a bottom of the etch hole 212.
It should be noted that definition or description of similar or same structures in the present embodiment (the contact window structure) and the forgoing embodiments (the forming process of the contact window structure) will not be defined in the present embodiment. Referring to the definition or description in the corresponding sections of the foregoing embodiments for details.
Another embodiment of the disclosure further provides a metal plug. Referring to
The dielectric layer 211 is located on the target layer 202.
The contact window is located in the dielectric layer 211. The contact window includes an etch hole 212 (referring to
The contact window is filled with the metal plug 214.
It should be noted that definition or description of similar or same structures in the present embodiment (the metal plug) and the forgoing embodiments (the process of forming the contact window structure) will not be defined in the present embodiment. Referring to the definition or description in the corresponding sections of the foregoing embodiments for details. Although the embodiments of the disclosure have been disclosed as above in preferred embodiments, they are not intended to limit the embodiments of the disclosure. Any person skilled in the art may use the above disclosed method and technical contents to make possible changes and variations to the technical solution of the embodiments of the disclosure without departing from the spirit and scope of the embodiments of the disclosure. Therefore, any content that does not depart from the technical solutions of the embodiments of the disclosure, any simple variations, equivalent changes and modification made to the above embodiments based on the technical essence of the embodiments of the disclosure all fall within the protection scope of the technical solutions of the embodiments of the disclosure.
Number | Date | Country | Kind |
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202011001855.8 | Sep 2020 | CN | national |
This is a continuation of International Application No. PCT/2021/099873, filed on Jun. 11, 2021, entitled “CONTACT WINDOW STRUCTURE, METAL PLUG AND FORMING METHOD THEREOF, AND SEMICONDUCTOR STRUCTURE”, which claims priority to Chinese patent application No. 202011001855.8, filed on Sep. 22, 2020, entitled “CONTACT WINDOW STRUCTURE, METAL PLUG AND FORMING METHOD THEREOF, AND SEMICONDUCTOR STRUCTURE”. The disclosures of International Application No. PCT/2021/099873 and Chinese patent application No. 202011001855.8 are hereby incorporated by reference in their entireties.
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Number | Date | Country | |
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Parent | PCT/CN2021/099873 | Jun 2021 | US |
Child | 17401461 | US |