Embodiments described herein relate to a semiconductor device and a method of manufacturing the same.
Integration of a semiconductor memory such as a three-dimensional memory has been improved year by year. Accordingly, unless a flow of carriers in or near memory cells is controlled with high accuracy, it may be difficult to cause a highly integrated semiconductor memory to perform a desired operation. For example, the carriers may flow among the memory cells, resulting in erroneous writing into a non-selected cell.
In one embodiment, a semiconductor device includes a substrate, a plurality of insulating films and a plurality of first films alternately stacked on the substrate, at least one of the first films including an electrode layer and a charge storage layer provided on a face of the electrode layer via a first insulator, the face of the electrode layer being parallel to a direction of the stacking, and a semiconductor layer provided on a face of the charge storage layer via a second insulator, the face of the charge storage layer being parallel to the direction of the stacking. The device further includes at least one of a first portion including nitrogen and provided at least between the first insulator and the charge storage layer with an air gap provided in the first insulator, a second portion including nitrogen, provided at least between the charge storage layer and the second insulator, and including a portion protruding toward the charge storage layer, and a third portion including nitrogen and provided at least between the second insulator and the semiconductor layer with an air gap provided in the first insulator.
Embodiments will now be explained with reference to the accompanying drawings. In
The semiconductor device illustrated in
The intermediate portion 3 includes an electrode layer 11, a block insulator 12, and a charge storage layer 13 as components of a memory cell in a three-dimensional memory. The semiconductor device illustrated in
The semiconductor device illustrated in
The substrate 1 is a semiconductor substrate such as a silicon (Si) substrate.
The insulating layer 2 is a silicon oxide film (SiO2), for example. The thickness of the insulating layer 2 is 30 nm, for example. Similarly, the thickness of the intermediate portion 3 is 30 nm, for example.
The electrode layer 11 is a metal layer such as a tungsten (W) layer, and functions as a word line. The block insulator 12 includes an insulator 12a provided on a side face, an upper face, and a lower face of the electrode layer 11 and an insulator 12b provided on a side face, an upper face, and a lower face of the charge storage layer 13. The insulator 12a is an aluminum oxide film (AlOX), for example, and the insulator 12b is a silicon oxide film, for example. The insulator 12a is provided on a face that is a side face of the electrode layer 11 and opposes the charge storage layer 13, and the insulator 12b is provided on a face that is a side face of the charge storage layer 13 and opposes the electrode layer 11. The upper layer of the electrode layer 11 is a face opposing the insulating layer 2 positioned above the electrode layer 11 among the faces of the electrode layer 11. The lower face of the electrode layer 11 is a face opposing the insulating layer 2 positioned below the electrode layer 11 among the surfaces of the electrode layer 11. The side face of the electrode layer 11 is a face positioned between the upper face and the lower face of the electrode layer 11 among the faces of the electrode layer 11. The same applies to the side face, the upper face and the lower face of the charge storage layer 13.
The charge storage layer 13 is formed on the side face of the electrode layer 11 via the block insulator 12 (the insulators 12a and 12b). The charge storage layer 13 functions as a layer storing a charge for data storage. The charge storage layer 13 is a silicon layer, for example, and the silicon layer stores the charge. The charge storage layer 13 is also referred to as a floating electrode. The charge storage layer 13 may be formed of a metal layer or an insulator functioning as a layer storing the charge.
The tunnel insulator 14 is continuously formed on the side face of the charge storage layer 13 and the side faces of the insulating layers 2. The tunnel insulator 14 is a silicon oxide film, for example. The channel semiconductor layer 15 is formed on the side face of the charge storage layer 13 and the side faces of the insulating layers 2 via the tunnel insulator 14. The channel semiconductor layer 15 is a silicon layer.
The silicon nitride film 21 is formed between the block insulator 12 and the charge storage layer 13, and specifically is formed on the side face of the charge storage layer 13. The silicon nitride film 22 is formed between the tunnel insulator 14 and the channel semiconductor layer 15, and specifically is divided into an upper portion and a lower portion along the side face of the charge storage layer 13. In
The silicon nitride films 21 and 22 in the present embodiment may be replaced with portions each containing nitrogen but remaining less than a film, although each formed as a film containing nitrogen. That is, the portions each containing nitrogen but remaining less than a film may be respectively formed between the block insulator 12 and the charge storage layer 13 or between the tunnel insulator 14 and the channel semiconductor layer 15 instead of the silicon nitride films 21 and 22. The portions are also respectively examples of the first portion and the third portion.
Details of the silicon nitride films 21 and 22 will be described below.
The semiconductor device of the present embodiment reverses a channel between cells by a fringe electric field that has leaked out of a word line (the electrode layer 11) to cause carriers to flow because it does not include a diffusion layer. To promote this, impurities can conceivably be added into the charge storage layer 13 (the silicon layer). However, the impurities are not easily added if the thickness of the charge storage layer 13 is small. On the other hand, when a high voltage is applied to the word line in the non-selected cell to reverse the channel between the cells, erroneous writing into the non-selected cell may occur.
The semiconductor device of the present embodiment includes the silicon nitride film 21 between the block insulator 12 and the charge storage layer 13, and includes the silicon nitride film 22 between the tunnel insulator 14 and the channel semiconductor layer 15. Accordingly, problems such as erroneous writing into the non-selected cell can be suppressed.
For example, the silicon nitride film 22 in the present embodiment is formed along the side faces of the insulating layers 2, and is divided into the upper portion and the lower portion along the side face of the charge storage layer 13. Therefore, according to the present embodiment, a nitrogen concentration in a region between the tunnel insulator 14 and the channel semiconductor layer 15 can be made higher in a region between the cells than that in a region of a cell portion. Accordingly, a threshold voltage between the cells can be reduced, and the channel between the cells can be reversed even when a high voltage is not applied to the word line in the non-selected cell. As a result, erroneous writing into the non-selected cell can be reduced. In the present embodiment, when the threshold voltage between the cells is reduced, an ON current increases.
The silicon nitride film 22 in the present embodiment can suppress charge trapping, and accordingly can suppress a variation of the ON current. Therefore, according to the present embodiment, a reading time period from the cell can be shortened, whereby erroneous writing into the non-selected cell can be further reduced.
The silicon nitride film 21 in the present embodiment can provide a layer having a high dielectric constant between the block insulator 12 and the charge storage layer 13. Accordingly, a leak current from the cell can be reduced, and a writing characteristic into the cell can be improved.
As described above, according to the present embodiment, a flow of the carriers can be controlled with high accuracy, whereby problems such as erroneous writing into the non-selected cell can be suppressed.
First, a plurality of insulating layers 2 and a plurality of sacrifice layers 4 are alternately formed on a substrate 1 (
Then, a trench H1 is formed in the insulating layers 2 and the sacrifice layers 4 by RIE (reactive ion etching). The trench H1 is formed to extend in a Y-direction. In a process illustrated in
Then, an insulator 5 is embedded in the trench H1 (
Then, a plurality of holes H2 are formed in the insulator 5 by RIE (
Then, a portion of each of the sacrifice layers 4 exposed to the inside of the hole H2 is selectively removed by wet etching using a hot phosphoric acid (
Then, an insulator 12b constituting a block insulator 12 and a charge storage layer 13 are formed in this order in the cavity H3 (
Then, a tunnel insulator 14 and a channel semiconductor layer 15 are formed in this order in each of the holes H2 (
Then, a remainder of each of the sacrifice layers 4 exposed to the inside of a hole (not illustrated) is selectively removed by wet etching using a hot phosphoric acid (
Then, nitriding treatment using the cavity H4 is performed (
The charge storage layer 13 in the present embodiment has a function of blocking a nitriding gas or a substance produced from a nitriding gas. Therefore, the silicon nitride film 22 in the present embodiment is not formed along the side face of the charge storage layer 13, and is divided into an upper portion and a lower portion along the side face of the charge storage layer 13.
Then, an insulator 12a constituting the block insulator 12 and an electrode layer 11 are formed in this order in the cavity H4 (
Then, various interconnect layers and inter layer dielectrics are formed on the substrate 1. In this manner, the semiconductor device of the present embodiment is manufactured.
More details of the present embodiment will be described below.
Although the insulating layer 2 and the sacrifice layer 4 are formed by CVD in the present embodiment, they may be formed using another method. The insulating layer 2 (the silicon oxide film) may be formed using SiH4 and N2O by plasma CVD, for example. The sacrifice layer 4 (the silicon nitride film) may be formed using SiH2Cl2 and NH3 by plasma CVD, for example.
Although the charge storage layer 13 is formed using SiH4 in the present embodiment, it may be formed using another gas. For example, the charge storage layer 13 may be formed using Si2H6. A seed layer of the charge storage layer 13 may be formed using an organic Si source gas or Si2H6, and a main layer of the charge storage layer 13 may be formed using SiH4. A P atom or a B atom may be added to the charge storage layer 13 (the silicon layer) (P represents phosphorous, and B represents boron) by supplying a PH3 gas or a BCl3 gas, together with a source gas in the charge storage layer 13. Accordingly, a threshold voltage of the memory cell can be adjusted to an appropriate value so that a characteristic of a memory cell can be improved.
In a process illustrated in
A silicon layer may be formed as the charge storage layer 13, and a portion of the silicon layer may be changed to a SiN film by adding nitrogen to the silicon layer. The charge storage layer 13 may be constituted by a silicon layer and a SiN film inserted into the silicon layer. The charge storage layer 13 can be formed during formation of the silicon layer by switching a Si source gas (e.g., a SiH2Cl2 gas) in the silicon layer to an NH3 gas in situ. When nitrogen is contained in the charge storage layer 13, a charge holding property of the charge storage layer 13 can be improved, for example.
Although the tunnel insulator 14 and the insulator 12b (the silicon oxide film) are formed by ALD using TDMAS and O3 in the present embodiment, they may be formed by another method using another gas. For example, the tunnel insulator 14 and the insulator 12b may be formed by CVD using SiH4 and N2O.
In the nitriding treatment illustrated in
In the present embodiment, when the charge storage layer 13 outside the cavity H3 is removed by a chemical solution in the process illustrated in
If a silicon nitride film is formed on an upper face and a lower face of the charge storage layer 13 by the nitriding treatment illustrated in
Although the silicon nitride film 21 is formed between the block insulator 12 and the charge storage layer 13 and the silicon nitride film 22 is formed between the tunnel insulator 14 and the channel semiconductor layer 15 in the present embodiment, silicon nitride films may be respectively formed between the charge storage layer 13 and the tunnel insulator 14 and between the insulating layers 2 and the tunnel insulator 14. For example, a silicon nitride film can be formed between the charge storage layer 13 and the tunnel insulator 14 by performing nitriding treatment at a temperature of 500° C. or more using NO, NH3, or ND3 after the tunnel insulator 14 is formed. In this case, a silicon nitride film may also be formed between the tunnel insulator 14 and the channel semiconductor layer 15 by performing nitriding treatment at a temperature of 500° C. or more using NO after the channel semiconductor layer 15 is formed. The silicon nitride film is formed not only along the side faces of the insulating layers 2 but also along the side face of the charge storage layer 13.
If the silicon nitride film is formed between the tunnel insulator 14 and the channel semiconductor layer 15, the silicon nitride film 22 is formed again between the tunnel insulator 14 and the channel semiconductor layer 15 by the nitriding treatment illustrated in
If a semiconductor device including a silicon nitride film between the charge storage layer 13 and the tunnel insulator 14 is manufactured, the side face of the charge storage layer 13 may be nitrided after the charge storage layer 13 is formed and before the tunnel insulator 14 is formed. In this case, nitriding may be performed by plasma nitriding or radial nitriding using N2, NH3, ND3, or NO.
Details of a silicon nitride film other than the silicon nitride films 21 and 22 will be described below.
Although the insulator 12a constituting the block insulator 12 is an aluminum oxide film in the present embodiment, it may be another insulator. For example, the insulator 12a may be a stacked film alternately including two or more silicon nitride films and one or more silicon oxide films, or may be a high-k insulator (high-dielectric constant insulator) other than an aluminum oxide film. Examples of the high-k insulator include a HfOX film and an LaAlOX film (Hf represents hafnium, and La represents lanthanum). The insulator 12a may be a stacked film including a silicon oxide film and a high-k insulator. The foregoing materials are also applicable to the tunnel insulator 14.
Various modifications to the first embodiment will be described below.
The semiconductor device illustrated in
First, processes from
In the present modification, processes from
The semiconductor device illustrated in
First, the processes from
Then, an insulator (silicon nitride film) 24b constituting the silicon nitride film 24 is formed on a side face, exposed to the inside of a hole H2, of the charge storage layer 13 (
In the present modification, the processes from
The semiconductor device illustrated in
First, the processes from
Then, an insulator (silicon nitride film) 25b constituting the silicon nitride film 25 is formed on respective side faces, exposed to the inside of the hole H2, of the charge storage layer 13 and insulating layers 2 (
In the present modification, the processes from
According to the modifications, when the silicon nitride films 23, 24, and 25 are formed, a similar effect to that when the silicon nitride films 21 and 22 are formed can be obtained. For example, charge trapping to the tunnel insulator 14 or the like can be suppressed, and a leak current from a cell can be reduced. Accordingly, problems such as erroneous writing into a non-selected cell can be suppressed.
As described above, in the present embodiment and the modifications, the silicon nitride films 21 to 25 are each formed between the block insulator 12 and the charge storage layer 13, between the charge storage layer 13 and the tunnel insulator 14, or between the tunnel insulator 14 and the channel semiconductor layer 15. Therefore, according to the present embodiment and the modifications, the flow of carriers can be controlled with high accuracy, whereby problems such as erroneous writing into the non-selected cell can be suppressed.
The semiconductor device illustrated in
The electrode layer 11 includes the barrier metal layer 11a provided on a side face, an upper face, and a lower face of the insulator 12a, and the electrode material layer 11b provided on a side face, an upper face, and a lower face of the barrier metal layer 11a. The barrier metal layer 11a is a TiN layer, for example. The electrode material layer 11b is a W layer, for example.
The block insulator 12 includes the insulator 12a provided on a side face, an upper face, and a lower face of the electrode layer 11, and the insulators 12d, 12c, and 12b that are provided in this order on a side face, an upper face, and a lower face of the charge storage layer 13. The insulator 12a is an aluminum oxide film, for example. The insulator 12b is a silicon oxide film, for example. The insulator 12c is a silicon nitride film or a high-k insulator (high-dielectric constant insulator) containing a metal. The insulator 12d is a silicon oxide film, for example. According to the present embodiment, when the insulator 12c is provided between the insulators 12b and 12d, the performance of the block insulator 12 on the side of the charge storage layer 13 can be improved.
The block insulator 12 includes an air gap G in the insulators 12b, 12c, and 12d positioned on the side of the charge storage layer 13. The air gap G in the present embodiment is sandwiched between the insulator 12b and the insulator 12d, like the insulator 12c. As described below, the air gap G is formed by removing a portion of the insulator 12c.
According to the present embodiment, when the air gap G is included in the block insulator 12, it is possible to reduce an interference between cells, to reduce a leak current from the cell, and to reduce erroneous writing caused by the insulator 12c.
First, after the processes from
Then, the charge storage layer 13 and the insulators 12d and 12c outside the cavity H3 are removed by wet etching using an alkaline chemical solution (
Then, a portion of the insulator 12c is selectively removed by wet etching from a hole H2 (
In the present embodiment, the processes illustrated in
In the modification illustrated in
In the modification illustrated in
In the modification illustrated in
A shape of the air gap G may be a shape illustrated in
In the modification illustrated in
In the modification illustrated in
As described above, the block insulator 12 in each of the present embodiment and the modifications includes the air gap G in the insulators 12b, 12c, and 12d positioned on the side of the charge storage layer 13. Therefore, according to the present embodiment and the modifications, it is possible to reduce an interference between cells, to reduce a leak current from the cell, and to reduce erroneous writing caused by the insulator 12c.
The semiconductor device illustrated in
The semiconductor film 13a is formed on an upper face and a lower face of the insulator 12d and a side face of the silicon nitride film 21. The semiconductor film 13a is a silicon film, for example. The metal film 13b is formed on an upper face, a lower face, and a side face of the semiconductor film 13a. The metal film 13b is a titanium nitride film, for example. The metal film 13b is formed in not the whole but a portion of the upper face and the lower face of the semiconductor film 13a. The semiconductor film 13c is formed on an upper face, a lower face, and a side face of the metal film 13b and the upper face and the lower face of the semiconductor film 13a. The semiconductor film 13c is a silicon film, for example.
The metal film 13b is sandwiched between the semiconductor films 13a and 13c, and is further completely covered with the semiconductor films 13a and 13c. Therefore, the metal film 13b does not contact a tunnel insulator 14.
The charge storage layer 13 in the present embodiment can be formed by forming the semiconductor film 13a, the metal film 13b, and the semiconductor film 13c in this order in a cavity H3 in the process illustrated in
As described above, the charge storage layer 13 in the present embodiment includes not only the semiconductor films 13a and 13c but also the metal film 13b. If the charge storage layer 13 is formed of only a semiconductor, electrons from a channel semiconductor layer 15 may pass through the charge storage layer 13 into the electrode layer 11. However, according to the present embodiment, the metal film 13b can inhibit electrons from passing into the electrode layer 11 by scattering the electrons.
The electrons in the charge storage layer 13 may be accumulated in the semiconductor films 13a and 13c or may be accumulated in the metal film 13b. In the present embodiment, the electrons in the charge storage layer 13 are accumulated in the semiconductor films 13a and 13c.
The metal film 13b in the present embodiment is formed not to contact the tunnel insulator 14. Accordingly, it is possible to improve a window of a memory cell and to suppress a damage to the tunnel insulator 14 from the metal film 13b.
In the modification illustrated in
In the modification illustrated in
As described above, in the present embodiment and the modifications, the charge storage layer 13 includes the metal film 13b. Therefore, according to the present embodiment and the modifications, electrons can be inhibited from passing through the charge storage layer 13 into the electrode layer 11.
The semiconductor device illustrated in
The block insulator 12 includes the insulator 12a provided on a side face, an upper face, and a lower face of an electrode layer 11, and the insulators 12f, 12e, and 12b that are provided in this order on a side face, an upper face, and a lower face of a charge storage layer 13. The insulator 12a is an aluminum oxide film, for example. The insulator 12b is a silicon oxide film, for example. The insulator 12e is a high-k insulator (high dielectric constant insulator), for example, and specifically is a HfOX film (or a HfTiOX film containing a titanium atom at a low composition ratio). The insulator 12f is a high-k insulating layer, for example, and specifically is a HfTiOX film containing a titanium atom at a high composition ratio. In the present embodiment, the composition ratio of the titanium atom in the insulator 12e is lower than the composition ratio of the titanium atom in the insulator 12f. If the insulator 12e is a HfOX film, the composition ratio of the titanium atom in the insulator 12e is zero or substantially zero. According to the present embodiment, the block insulator 12 on the side of the charge storage layer 13 includes not only the insulator 12b but also the insulators 12e and 12f so that the performance of the block insulator 12 on the side of the charge storage layer 13 can be improved.
An end of the insulator 12f in the present embodiment is covered with the insulator 12e and the silicon nitride film 24. Therefore, the insulator 12f in the present embodiment does not contact a tunnel insulator 14, like the insulator 12c in the second embodiment. In the present embodiment, the insulator 12e in the vicinity of the end of the insulator 12f is a HfOX film containing a nitrogen atom.
A result of an experiment has indicated that when the insulators 12e and 12f are each a HfTiOX film, a trap density in the insulators 12e and 12f more increases than when the insulators 12e and 12f are each a HfOX film. Accordingly, a writing characteristic and an erasing characteristic of a memory cell can be improved.
The result of the experiment has further indicated that a trap density in the HfTiOX film increases as the composition ratio of the titanium atom in the HfTiOX film. The increase in the trap density may increase erroneous writing into the memory cell, although it results in an improvement in the writing characteristic and the erasing characteristic of the memory cell. The block insulator 12 in the present embodiment includes the insulator 12e containing a titanium atom at a low composition ratio and the insulator 12f containing a titanium atom at a high composition ratio, and the insulator 12e prevents contact between the insulator 12f and the tunnel insulator 14. Accordingly, a profit produced by the increase in the trap density can be enjoyed while erroneous writing into the memory cell is suppressed.
The result of the experiment has further indicated that when a nitrogen concentration in each of the HfOX film and the HfTiOX film is high, the titanium atom is not easily diffused from the outside to the inside of the films and the titanium atom is easily diffused from the inside to the outside of the films. In the present embodiment, a nitrogen atom is doped into the insulators 12e and 12f in the vicinity of the tunnel insulator 14. Accordingly, a structure in which the end of the insulator 12f is covered with the insulator 12e can be implemented (see
A titanium concentration in the insulator 12e is 1.0×1020 atoms/cm3 or less, for example, at least in the vicinity of the end of the insulator 12f, and a titanium concentration in the insulator 12f is 1.0×1020 atoms/cm3 or more, for example. Further, a nitrogen concentration in the insulator 12e is 1.0×1020 atoms/cm3 or more, for example, at least in the vicinity of the end of the insulator 12f, and a nitrogen concentration in the insulator 12f is 1.0×1020 atoms/cm3 or less, for example. The insulators 12e and 12f in the present embodiment may include an Al atom, a Si atom, or a Zr (zirconium) atom instead of a Hf atom.
First, after the processes illustrated in
Then, the charge storage layer 13 and the insulators 12f and 12e outside the cavity H3 are removed by wet etching using an alkaline chemical solution (
Then, the insulators 12e and 12f are nitrided from a hole H2, to nitride an end having a thickness of approximately 1 nm of each of the insulators 12e and 12f. Such nitriding treatment is performed at a temperature of 300 to 800° C. in a N2 atmosphere by plasma annealing, for example. A N2 gas may be replaced with an NH3 gas. According to the nitriding treatment, a titanium atom can be diffused outward from the end of each of the insulators 12e and 12f. As a result, both the ends of the insulators 12e and 12f each become a HfOX film (or a HfTiOX film containing a titanium atom at a low composition ratio). This corresponds to a change of the end of the insulator 12f to the insulator 12e. Accordingly, the end of the insulator 12f can be moved toward an electrode layer 11 so that a structure in which the end of the insulator 12f is covered with the insulator 12e can be implemented (
In the present embodiment, the processes illustrated in
In the modification illustrated in
In the modification illustrated in
In the modification illustrated in
In the modification illustrated in
According to the present embodiment and the modifications, when the block insulator 12 on the side of the charge storage layer 13 is configured using the HfOX film and/or the HfTiOX film, a profit produced by the increase in the trap density can be obtained.
First, after the processes illustrated in
Then, a charge storage layer 13 is formed in the cavity H3, for example (
Then, the charge storage layer 13 outside the cavity H3 is removed by wet etching using an alkaline medicinal solution (
A process illustrated in
Then, nitriding treatment using a hole H2 is performed (
In a process illustrated in
Then, a tunnel insulator 14 and a channel semiconductor layer 15 are formed in this order in each of holes H2, like in the process illustrated in
Then, various interconnect layers and inter layer dielectrics are formed on a substrate 1. In such a manner, the semiconductor device of the present embodiment is manufactured.
The silicon nitride film 27 in the present embodiment is formed to a shape similar to that of the above-described silicon nitride film 25. Therefore, according to the present embodiment, when the silicon nitride film 27 is formed, a similar effect to that when the silicon nitride film 25 is formed can be obtained.
In the present embodiment, the silicon nitride film 27 is formed to enter the seam B1 and the bird's beak B2. If the seam B1 and the bird's beak B2 are left covered with the natural oxide film 32, a writing characteristic into a memory cell decreases due to an influence of a damage at respective positions of the seam B1 and the bird's beak B2 and an influence of the natural oxide film 32. However, according to the present embodiment, when the silicon nitride film 27 is formed to enter the seam B1 and the bird's beak B2, the writing characteristic into the memory cell can be made favorable. If fluorine is supplied by thermal diffusion, an interface defect is fluorine terminated so that a writing/erasing cycle stress tolerance is improved. In this case, in the channel semiconductor layer 15, a channel current increases, a threshold value distribution decreases, and a memory cell is easily multivalued, for example, due to the fluorine termination of a grain boundary defect of crystallized silicon and the interface defect between the tunnel insulator 14 and the channel semiconductor layer 15.
The semiconductor device illustrated in
The block insulator 12 includes the insulator 12a provided on a side face, an upper face, and a lower face of an electrode layer 11, the insulator 12g provided on an upper face and a lower face of a charge storage layer 13, and the insulator 12h provided on a side face of the charge storage layer 13. The insulator 12a is an aluminum oxide film, for example. The insulator 12g is a SiOC film containing a carbon atom at a relatively high composition ratio. The insulator 12h is a SiO2 film (or a SiOC film containing a carbon atom at a relatively low composition ratio), for example. In the present embodiment, a carbon concentration in the insulator 12g is higher than a carbon concentration in the insulator 12h. If the insulator 12h is a SiO2 film, the carbon concentration in the insulator 12h is zero or substantially zero. The carbon concentration in the insulator 12h is 1.0×1016 atoms/cm3 or less, for example, and the carbon concentration in the insulator 12g is 1.0×1016 atoms/cm3 or more, for example. The insulator 12h is an example of a first region, and the insulator 12g is an example of a second region.
First, the processes illustrated in
Then, to modify the insulator 12a (the aluminum oxide film), the insulator 12a is annealed in a nitrogen atmosphere at a temperature of 600 to 1200° C. (
Then, an electrode layer 11 is formed in a cavity H4 (
Then, various interconnect layers and inter layer dielectrics are formed on a substrate 1. In such a manner, the semiconductor device of the present embodiment is manufactured.
As described above, the block insulator 12 in the present embodiment includes the insulator 12g containing carbon on the upper face and the lower face of the charge storage layer 13. Accordingly, it is possible to suppress a load electric field to a non-selected cell and to reduce erroneous writing to the non-selected cell.
While a specific dielectric constant of the SiO2 film is 3.9, a specific dielectric constant of the SiOC film becomes lower than 3.9. In the present embodiment, when the insulator 12g contains carbon, a specific dielectric constant of the insulator 12g can be decreased to approximately 3.0. Accordingly, erroneous writing into the non-selected cell can be effectively reduced.
The semiconductor device illustrated in
Therefore, the silicon nitride film 25 in the present embodiment has a higher composition ratio of nitrogen to silicon and nitrogen than that of the charge storage layer 13. When the silicon nitride film 25 is represented by a composition formula Si1-XNX, and the charge storage layer 13 is represented by a composition formula Si1-YNY, a relationship of X>Y holds. Accordingly, the composition ratio of nitrogen in the silicon nitride film 25 is relatively large, for example, a value of “X/(1−X)” is 1.22 or more (e.g., 1.30). On the other hand, the composition ratio of nitrogen in the charge storage layer 13 is relatively low, for example, a value of “Y/(1−Y)” is 1.22 or less.
The charge storage layer 13 and the silicon nitride film 25 may contain silicon, nitrogen, and further another element. For example, the charge storage layer 13 may contain at least either one of oxygen and carbon.
First, the processes from
Then, an insulator 12b constituting a block insulator 12 is formed in a cavity H3, for example (
Then, an insulator 25a constituting a silicon nitride film 25 is formed in the cavity H3, for example (
Then, a charge storage layer 13 is formed in the cavity H3, for example (
Then, the charge storage layer 13 and the insulator 25a outside the cavity H3 are removed by wet etching using an alkaline medicinal solution (
Then, nitriding treatment using a hole H2 is performed (
In a process illustrated in
In the present embodiment, the processes illustrated in
As described above, the charge storage layer 13 in the present embodiment is a Si-rich silicon nitride film, and is covered with the Ni-rich silicon nitride film (the silicon nitride film 25). Therefore, according to the present embodiment, it is possible to store charges in the Si-rich silicon nitride film and for the N-rich silicon nitride film to prevent the charges from passing through the Si-rich silicon nitride film. Therefore, according to the present embodiment, it is possible to control a flow of carriers with high accuracy and thereby to suppress problems such as erroneous writing into a non-selected cell.
In the present modification, processes illustrated in
Then, annealing treatment using a NO gas is performed (
As described above, in the present embodiment and the modifications, the charge storage layer 13 is the Si-rich silicon nitride film, and is covered with the N-rich silicon nitride film (the silicon nitride film 25). Therefore, according to the present embodiment and the modifications, it is possible to control a flow of carriers with high accuracy and thereby to suppress problems such as erroneous writing into a non-selected cell, like in the first embodiment, for example.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel devices and methods described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the devices and methods described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2019-048973 | Mar 2019 | JP | national |
This application is a divisional of U.S. application Ser. No. 17/136,621, filed Dec. 29, 2020, which is a divisional of U.S. application Ser. No. 16/559,165 filed Sep. 3, 2019 and claims the benefit of priority from the prior Japanese Patent Application No. 2019-048973, filed on Mar. 15, 2019, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | 17136621 | Dec 2020 | US |
Child | 17659881 | US | |
Parent | 16559165 | Sep 2019 | US |
Child | 17136621 | US |