Patent Application
20250142819
This application claims priority to Chinese patent application No. 202311413739.0, filed on Oct. 27, 2023, the disclosure of which is incorporated herein by reference in its entirety.
The present disclosure relates to semiconductor manufacturing technologies, and in particular, to a method for manufacturing a NOR flash.
NOR erasable programmable read only memory with tunnel oxide or EPROM with tunnel oxide (ETOX) flash memory (hereinafter referred to as NOR flash) is a non-volatile flash with a high read speed, high reliability, and intra-chip execution capability, and has become one of the most widely applied non-volatile memories currently. With the advancement of manufacturing technologies and increased market demand for high-capacity, high-density and low-power NOR flashes, the NOR flash has transitioned from the 65/55 nm node of mass production to the 40 nm+ node of research and development and mass production. The source polysilicon gate gap of NOR flashes at smaller technology nodes is further reduced compared with the 65/55 nm NOR flash, and the coupling effect between polysilicon gates continues to be enhanced, affecting the performance and reliability. During the research and development of NOR flashes at smaller nodes, the development of new process flows is required to weaken the coupling effect, so as to improve the device performance and reliability.
An effective way to weaken the coupling effect of polysilicon gates on both sides of the source is to use a filler dielectric with a lower dielectric constant. Among optional filler dielectrics, air has a very low dielectric constant. As reference, silicon dioxide, the most commonly used filler material, has a relative dielectric constant of about 3.9, while air has a relative dielectric constant of about 1. Therefore, replacing the existing silicon dioxide with the air gap, as the filler material between the polysilicon gates at the source, can significantly weaken the coupling effect.
On the other hand, the NOR flash has a large space at the drain, and the coupling effect of polysilicon gates on both sides of the drain is very weak, having negligible impacts on the performance and reliability. However, unlike the structure in which multiple sources share one single pickup, each bit of the NOR flash necessarily has an individual drain pickup. Considering the subsequent contact process of the drain pickup, good filling of the drain is required, in which case the air gap process cannot be used.
The method for manufacturing a NOR flash provided by the present disclosure includes the following steps:
Optionally, after step S2, a hard mask layer 610, a bottom anti reflection coating 620 are sequentially deposited, followed by step S3; and
Optionally, after step S4, a source-drain area and a logic area sidewall 700 are first formed on both sides of the gate structure in the storage area A and on both sides of the peripheral polysilicon gate 230a, followed by step S5.
Optionally, after step S4, the source-drain area and the logic region sidewall 700 are first formed on both sides of the gate structure in the storage area A and on both sides of the peripheral polysilicon gate 230a, and then a metal silicide is formed on an upper end of the gate structure in the storage area A and on an upper end of the peripheral polysilicon gate 230a, followed by step S5.
Optionally, after step S12, a metal silicide 810 is formed on an upper end of the gate structure in the storage area and on an upper end of the peripheral polysilicon gate 230a, followed by step S13.
Optionally, in S12, pre-bake and dry etch are performed to remove an oxide and a nitride on the polysilicon gate individually, so as to expose polysilicon.
Optionally, in step S9, self-align source etch is performed to expose the semiconductor substrate 100 in the middle of the gate structure in the source area and the semiconductor substrate 100 of the gate structure in the source area that is close to the peripheral isolation groove, so as to form the source area groove 330.
Optionally, in step S9, surface O2 treatment is first performed to increase adhesion of the photoresist, followed by etch.
Optionally, in step S9, after the source area groove 330 is formed, ion implantation is performed on the semiconductor substrate 100 at the source area groove 330 to form a source pickup.
Optionally, in step S6, the trench isolation oxide 410 is deposited using an HDP chemical vapor deposition process;
Optionally, after step S15, Ti/TiN is deposited on the surface of the semiconductor substrate 100 at the bottom of the drain area contact 900, and a thermal process is performed to form a TiSi structure, followed by step S16.
Optionally, the thickness of the Ti/TiN deposited on the surface of the semiconductor substrate 100 at the bottom of the drain area contact 900 is 50 Å-00 Å, and an annealing temperature of the subsequent thermal process is 500° C.-600° C.
Optionally, 4h1<h2, h1 being the thickness of the barrier silicon nitride layer 820, and h2 being the width of the drain area groove 310; and
Optionally, in step S16, the contact 900 is filled with metal tungsten and subjected to chemical mechanical polishing.
Optionally, in step S1, a shallow trench isolation is formed on the semiconductor substrate 100; and
In the method for manufacturing a NOR flash of the present disclosure, the drain area groove 310 and the peripheral isolation grooves 320 are first formed and filled with the trench isolation oxide 410, followed by the formation of the source area groove 330, and then the SiH4 layer 420 is deposited. Due to the poor filling property of SiH4, the air gap may be formed at the source area groove 330 with a small gap, and at this time, the drain area groove 310 in the drain area AB of the storage area and the peripheral isolation groove 320 in the logic area B both have been filled and thus are unaffected.
The method for manufacturing a NOR flash of the present disclosure allows the formation of the source air gap of the NOR flash based on a post-source preparation process and good filling of the drain, reducing the coupling effect between the source polysilicon gates, thereby weakening the coupling effect between the polysilicon gates on both sides, and improving the performance and reliability of the NOR flash.
In order to more clearly explain the technical solutions of the present disclosure, the drawings required to be used in the present disclosure will be briefly described below. It is obvious that the drawings described below are merely some embodiments of the present disclosure, and those skilled in the art could also obtain other drawings on the basis of these drawings without the practice of inventive effort.
100: semiconductor substrate; A: storage area; B: logic area; AA: source area; AB: drain area; 210: gate oxide layer; 220: gate structure; 230: peripheral polysilicon layer; 221: floating gate polysilicon layer; 222: inter-gate dielectric layer; 223: control gate polysilicon layer; 230a: peripheral polysilicon gate; 310: drain area groove; 320: peripheral isolation groove; 820: barrier silicon nitride layer; 410: trench isolation oxide; 330: source area groove; 701: source area gate sidewall; 420: SiH4 layer; 430: protective oxide layer; 900: drain area contact; 610: hard mask layer; 620: bottom anti reflection coating; 700: source drain area and logic area sidewall; 810: metal silicide; 222a: bottom oxide layer; 222b: intermediate nitride layer; 222c: top oxide layer; 910: metal.
The technical solutions in the embodiments of the present disclosure will be clearly and completely described below in conjunction with the drawings. Obviously, the described embodiments are only part of the embodiments of the present disclosure, rather than all of the embodiments. Based on the embodiments in the present disclosure, all other embodiments obtained by those skilled in the art without the practice of inventive effort shall fall into the protection scope of the present disclosure.
The terms such as “first” and “second” used in the present application do not indicate any order, quantity, or importance, but are only used to distinguish different constituent parts. The terms such as “include” or “comprise” mean that the components or objects in front of these terms cover the components or objects listed after the terms and equivalents thereof, but does not exclude other components or objects. The terms such as “connection” or “coupling” are not limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect. The terms such as “upper”, “lower”, “left”, “right”, “front”, and “rear” are only used to represent relative positional relationships, which may be changed accordingly after absolute positions of the described objects are changed.
It should be noted that the embodiments or features in the embodiments of the present disclosure can be combined with each other in the case of no conflicts.
A method for manufacturing a NOR flash includes the following steps:
In the method for manufacturing a NOR flash of Embodiment I, the drain area groove 310 and the peripheral isolation grooves 320 are first formed and filled with the trench isolation oxide 410, followed by the formation of the source area groove 330, and then the SiH4 layer 420 is deposited. Due to the poor filling property of SiH4, the air gap may be formed at the source area groove 330 with a small gap, and at this time, the drain area groove 310 in the drain area AB of the storage area and the peripheral isolation groove 320 in the logic area B both have been filled and thus are unaffected.
The method for manufacturing a NOR flash of Embodiment I allows the formation of the source air gap of the NOR flash based on a post-source preparation process and good filling of the drain, reducing the coupling effect between the source polysilicon gates, thereby weakening the coupling effect between the polysilicon gates on both sides, and improving the performance and reliability of the NOR flash.
Based on the method for manufacturing a NOR flash of Embodiment I, after step S2, a hard mask layer 610, a bottom anti reflection coating (BARC) 620 are sequentially deposited, followed by step S3; and
in step S4, the gate structure 220 in the source area AB is first removed by etch to expose the gate oxide layer 310, so as to form the drain area groove 310, and then the photoresist and the bottom anti reflection coating (BARC) 620 are removed; the peripheral polysilicon layer 230 is etched to form the peripheral polysilicon gate 230a, with the peripheral isolation grooves 320 being formed on both sides of the peripheral polysilicon gate 230a, and then the hard mask layer 610 is removed.
In some examples, after step S4, a source-drain area and a logic area sidewall 700 are first formed on both sides of the gate structure in the storage area A and on both sides of the peripheral polysilicon gate 230a, followed by step S5.
In some examples, after step S4, the source-drain area and the logic region sidewall 700 are first formed on both sides of the gate structure in the storage area A and on both sides of the peripheral polysilicon gate 230a, and then a metal silicide is formed on an upper end of the gate structure in the storage area A and on an upper end of the peripheral polysilicon gate 230a, followed by step S5.
Based on the method for manufacturing a NOR flash of Embodiment I, after step S12, a metal silicide 810 is formed on an upper end of the gate structure in the storage area and on an upper end of the peripheral polysilicon gate 230a, followed by step S13.
In some examples, in S12, pre-bake (PREB) and dry etch are performed to remove an oxide and a nitride on the polysilicon gate individually, so as to expose polysilicon, facilitating the formation of the metal silicide.
Based on the method for manufacturing a NOR flash of Embodiment I, in step S9, self-align source (SAS) etch is performed to expose the semiconductor substrate 100 in the middle of the gate structure in the source area and the semiconductor substrate 100 of the gate structure in the source area that is close to the peripheral isolation groove, so as to form the source area groove 330.
In some examples, in step S9, surface O2 treatment is first performed, and since there is much surface silicon nitride at this time, to which the adhesion of the photoresist is not good, surface treatment (O2 treatment) thus is required to increase the adhesion of photoresist, followed by etch.
Optionally, in step S9, after the source area groove 330 is formed, ion implantation is performed on the semiconductor substrate 100 at the source area groove 330 to form a source pickup.
In some examples, in step S6, the trench isolation oxide 410 is deposited using a high-density plasma (HDP) chemical vapor deposition process, where the high-density plasma (HDP) chemical vapor deposition process has good filling property.
In some examples, in step S11, the source area gate sidewall 701 is deposited using an atomic layer deposition (ALD) process, where the ALD process has a low temperature and good conformability.
In some examples, the thickness of the source area gate sidewall 701 is 100 Å-200 Å.
In some examples, in step S14, the protective oxide layer 430 is formed by means of plasma-enhanced chemical vapor deposition (PECVD) with tetraethoxysilane (TEOS).
Based on the method for manufacturing a NOR flash of Embodiment I, after step S15, Ti/TiN is deposited on the surface of the semiconductor substrate 100 at the bottom of the drain area contact 900, and a thermal process is performed to form a TiSi structure, followed by step S16.
In some examples, the thickness of the Ti/TiN deposited on the surface of the semiconductor substrate 100 at the bottom of the drain area contact 900 is 50 Å-00 Å, and an annealing temperature of the subsequent thermal process is 500° C.-600° C.
Since no nickel silicide is formed on a drain of the storage area or on a source or drain of a logic device, after the drain area contact 900 is formed depositing the Ti/TiN and forming the TiSi structure via an appropriate thermal process, with a sidewall of the drain area contact 900 being used as an adhesive layer, may reduce a contact resistance of the drain area contact 900, ensuring the performance of the device.
In some examples, 4h1<h2, h1 being the thickness of the barrier silicon nitride layer 820, and h2 being the width of the drain area groove 310.
In some examples, the width of the source area groove 310 is less than 55 nm.
In some examples, in step S16, the contact 900 is filled with metal tungsten and subjected to chemical mechanical polishing (CMP).
In some examples, in step S1, a shallow trench isolation (STI) is formed on the semiconductor substrate 100.
In some examples, the inter-gate dielectric layer 222 is composed of a bottom oxide layer 222a, an intermediate nitride layer 222b, and a top oxide layer 222c stacked in sequence.
The above descriptions are merely examples of the embodiments of the present disclosure and are not intended to limit the present disclosure. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the present disclosure shall be included within the protection scope of the present disclosure.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202311413739.0 | Oct 2023 | CN | national |
