1. Field of the Invention
The present invention relates to a semiconductor device having a conductor usable for registration and a method for fabricating a semiconductor device.
2. Description of the Related Art
In recent, with the downsizing of electronic devices or the provision of higher functionalities for electronic devices, a CoC (Chip on Chip) semiconductor device has been developed, including a chip stacked body formed of a plurality of semiconductor chips stacked on each other. In the CoC semiconductor device, the registration of semiconductor chips, that is, the alignment of semiconductor chips is performed in stacking semiconductor chips on each other.
FIGS. 2B and 3 in JP2005-217071A disclose alignment marks for use in aligning semiconductor chips. A semiconductor chip described in JP2005-217071A is a chip for a multichip semiconductor device having two or more conductive through plugs. One or more plugs among a plurality of through plugs are used for alignment marks. In other words, the alignment mark is formed of the same conductive member as the conductive member of the through plug, a metal material, for example. This alignment mark can be identified on the front and back surface of the chip. Thus, the alignment mark can be fabricated by the same process steps as the process steps for the through plug.
The alignment mark described in JP2005-217071A is fabricated by the same process steps as the process steps for the through plug. Therefore, the alignment mark is made of the same metal material as the metal material of the through plug, copper, for example. The inventor found that the characteristics of a semiconductor element formed on a semiconductor substrate sometimes deteriorate when metal atoms forming an alignment mark diffuse into the semiconductor substrate.
For example, in the case where a semiconductor chip is a memory chip like a DRAM, electric charges stored in a capacitor as a semiconductor element tend to leak which is caused by metal impurity in a semiconductor substrate. Thus, the data hold time of the DRAM is shortened.
Therefore, in a semiconductor chip including alignment marks formed of a conductive member, it is desirable to suppress deterioration of device characteristics caused by diffusion of atoms that form the conductive member.
In one embodiment, a semiconductor device includes: a semiconductor substrate having a first surface and a second surface located opposite to each other in a thickness direction; a semiconductor element formed on the first surface of the semiconductor substrate; a through electrode penetrating the semiconductor substrate from the first surface to the second surface and electrically connected to the semiconductor element; a conductor penetrating the semiconductor substrate from the first surface to the second surface and not electrically connected to the semiconductor element; and an insulating separator penetrating the semiconductor substrate from the first surface to the second surface and formed in a ring so as to surround the conductor.
In another embodiment, a semiconductor device includes: a plurality of semiconductor chips stacked on each other, each of the plurality of semiconductor chips having a semiconductor substrate and a wiring layer; a through electrode penetrating the semiconductor substrate in a thickness direction and electrically connected to each other between the semiconductor chips adjacent to each other; a conductor penetrating the semiconductor substrate in the thickness direction and not electrically connected between the other semiconductor chips; and an insulating separator penetrating the semiconductor substrate in the thickness direction and formed in a ring so as to surround the conductor.
In other embodiment, a method for fabricating a semiconductor device, comprising: preparing a first semiconductor chip having a conductor and a insulating separator, the conductor penetrating the first semiconductor chip in a thickness direction and being not electrically connected to any element formed on the first semiconductor chip, the insulating separator penetrating the first semiconductor chip in the thickness direction and being formed in a ring so as to surround the conductor; aligning a second semiconductor chip with the first semiconductor chip by using the conductor of the first semiconductor chip; and stacking the second semiconductor chip on the first semiconductor chip.
According to the semiconductor devices in the foregoing configurations and the method for fabricating the same, it is possible to use the conductor not electrically connected to the semiconductor element for an alignment mark. Moreover, the ring-shaped insulating separator surrounding the conductor prevents atoms that form the conductor from diffusing into the semiconductor substrate. Thus, it is possible to suppress the deterioration of the characteristics of a semiconductor element caused by the diffusion of atoms.
The above features and advantages of the present invention will be more apparent from the following description of certain preferred embodiments taken in conjunction with the accompanying drawings, in which:
The invention will be now described herein with reference to illustrative embodiments. Those skilled in the art will recognize that many alternative embodiments can be accomplished using the teachings of the present invention and that the invention is not limited to the embodiments illustrated for explanatory purposes.
The semiconductor chip has semiconductor substrate 10, through electrode 20 penetrating semiconductor substrate 10, alignment mark part 40, and cylindrical insulating films 30 and 50 of electrical insulating properties. For the material of semiconductor substrate 10, a semiconductor like a silicon substrate, for example, can be used. Semiconductor substrate 10 is formed with a functional element according to the function of the semiconductor chip, that is, semiconductor element 80. Functional element 80 is supplied with electric power from through electrode 20.
Functional element 80 is provided in device region B on a surface opposite one surface of the semiconductor substrate shown in
Through electrode 20 and an alignment mark part, that is, metal post 40 are exposed in at least one surface of the semiconductor chip. In the example shown in
Alignment mark part 40 penetrates semiconductor substrate 10. Alignment mark part 40 may be a metal post including the same metal material as the metal material of through electrode 20. Thus, alignment mark part 40 can be formed by the same process steps of fabricating through electrode 20. As a result, fabricating the semiconductor chip is facilitated. The end of the metal post forming alignment mark part 40 is exposed in the surface of the semiconductor chip, and used for alignment mark 47 for registration.
Alignment mark part 40 can be formed of a given conductive member. This conductive member 40 may penetrate the semiconductor substrate from first surface 10a to second surface 10b. Conductive member 40 is not electrically connected to semiconductor element 80.
First cylindrical insulating film 30 is formed on semiconductor substrate 10, and surrounds through electrode 20. Second cylindrical insulating film 50 is formed on semiconductor substrate 10, and surrounds alignment mark part 40. More specifically, cylindrical insulating film 30 or 50 surrounds through electrode 20 or alignment mark part 40 in a plane parallel with the surface of the semiconductor chip. In the first embodiment, insulating films 30 and 50 are disposed apart from through electrode 20 or alignment mark part 40. As described above, second insulating film 50 forms insulating separator 50 formed in a shape of a ring surrounding conductive member 40.
Preferably, both insulating films 30 and 50 may be made of the same material. Thus, both insulating films 30 and 50 can be fabricated by the same fabricating process steps.
Insulating separator 50 prevents atoms that form conductive member 40, particularly metal atoms, from diffusing into semiconductor substrate 10, device region B of the semiconductor substrate particularly. Therefore, it is possible to suppress the deterioration of characteristics of semiconductor element 80 caused by the diffusion of metal atoms. From a viewpoint of preventing metal atoms from diffusing, preferably, second insulating film 50 penetrates semiconductor substrate 10.
In order to prevent a metal material from diffusing, preferably, insulating films 30 and 50 include silicon nitride films 32 and 52. More preferably, insulating films 30 and 50 include silicon oxide films 34 and 54 whose surfaces are covered with these silicon nitride films 32 and 52. Moreover, insulating film 50 may include a poly-crystalline silicon film (polysilicon film). In this case, it is possible to further suppress the diffusion of metal atoms out of conductive member 40.
The semiconductor chip may have interlayer insulating layer 61, wiring layer 78, bump electrode 70, plug 77, and so on formed on semiconductor substrate 10. Bump electrode 70 is exposed in a surface opposite one surface of the semiconductor chip, in which through electrode 20 is exposed.
Wiring layer 78 may be formed in a plurality of levels. Interlayer insulating layer 61 is formed between wiring layer 78 in a certain level and wiring layer 78 adjacent thereto. Plug 77 extends in interlayer insulating layer 61. Plug 77 is electrically connected to through electrode 20, bump electrode 70, and wiring layer 78.
For the material of wiring layer 78, aluminum, tungsten, or the like can be used. Here, for an example, wiring layer 78 that makes contact with through electrode 20 was made of tungsten, and the other wiring layers 78 were made of aluminum. Moreover, preferably, etching stopper layer 48 that makes contact with alignment mark part 40 is formed at the same level at which wiring layer 78 that makes contact with through electrode 20 is located.
Insulating layer 67 made of polyimide and cover layer 66, for example, may be formed on one surface of the semiconductor chip on which bump electrode 70 is formed.
This semiconductor chip is preferably for use in a semiconductor device having semiconductor chips stacked on each other. End 47 of conductive member 40 that forms alignment mark part 40 is used for registration in stacking semiconductor chips on each other. A plurality of semiconductor chips may be the same kind of chips, or may be different kinds of chips. End 47 of conductive member 40 can be used for an alignment mark in aligning the semiconductor chip with a given member.
In the embodiment, end 47 of conductive member 40 is exposed only in one surface of the semiconductor chip. End 47 of conductive member 40 may be exposed in both surfaces of the semiconductor chip, not limited thereto. In this case, preferably, alignment mark part 40 exposed in one surface, on which bump electrode 70 is formed, is made of the same metal material as the metal material of wiring layer 78 that is located closest to the one surface. In the case where members to be aligned are on both sides of the chip, alignment mark parts 40 on both surfaces of the semiconductor chip are effective in cases where, for example, chips are to be stacked in three or more layers.
Alignment mark 47 can be recognized by an imaging device like a camera, for example. An image captured by the imaging device is subject to image processing, so that chips can be accurately aligned with each other by a computer. The shape of alignment mark part 40 is different from the shape of through electrode 20. Thus, the difference between alignment mark part 40 and through electrode 20 can be detected. Alignment mark part 40 may have any shape as long as the difference between alignment mark part 40 and through electrode 20 can be detected.
Next, exemplary process steps of fabricating the semiconductor chip will be described. In this example, silicon substrate 10 is prepared for a semiconductor substrate. As shown in
Subsequently, insulating films 30 and 50 are formed in trench 12. More specifically, as shown in
After that, as shown in
Subsequently, functional element 80 according to the function of the semiconductor chip, interlayer insulating layer 61, wiring layer 78, plug 77, cover layer 66, insulating layer 67, and so on are formed on first surface 10a of semiconductor substrate 10 (see
In the case where the semiconductor chip is a chip for a DRAM, a transistor and a capacitor are formed for functional element 80. Moreover, preferably, etching stopper layer 48 is formed in a region in which alignment mark part 40 is to be formed in interlayer insulating layer 61.
Preferably, etching stopper layer 48 is formed at the position of wiring layer 78 that is located closest to first surface 10a of semiconductor substrate 10. More preferably, etching stopper layer 48 is made of the same metal material as the material for forming this wiring layer 78. In this example, tungsten was used for etching stopper layer 48.
As shown in
Subsequently, an electrode is formed on seed layer 71. Positive resist 90 in a predetermined shape is formed on seed layer 71 by photolithography, for example, and resist 90 is patterned in such a way that seed layer 71 on plug 77 is exposed from the resist. Subsequently, an electrode is formed on seed layer 71 exposed from resist 90 by electroplating.
The electrode can be formed in which metal post 72 made of copper, for example, is formed in the opening of resist 90, for example, and metal film 73 made of SnAg, for example, is formed on the surface of this metal post 72. In this manner, bump electrode 70 formed of seed layer 71, metal post 72, and metal film 73 can be formed. It is noted that the material for forming bump electrode 70 is not limited to the example described above.
After forming bump electrode 70, resist 90 is removed, and seed layer 71 exposed in the surface of the semiconductor chip is removed. After removal, the temperature of bump electrode 70 is temporarily increased to melt only SnAg 22, and then reduced. Thus, as shown in
Subsequently, as shown in
Subsequently, as shown in
Subsequently, as shown in
Hole 92 can be formed by dry etching, for example. Preferably, hole 92 is formed on the inner side of insulating films 30 and 50, and penetrates semiconductor substrate 10. In this formation, the depth of hole 92 is determined by etching stopper layer 48 described above. It is sufficient that etching stopper layer 48 is a material resistant against etching. In order to vary the shape of through electrode 20 from the shape of alignment mark part 40, the shape of the hole for through electrode 20 may be varied from the shape of the hole for alignment mark part 40.
Subsequently, as shown in
Subsequently, as shown in
Through electrode 20 may be a through silicon via (TSV) that penetrates silicon as semiconductor substrate 10. Although alignment mark part 40 has a shape different from the shape of this through electrode 20, preferably, alignment mark part 40 has a similar structure.
Preferably, through electrode 20 and alignment mark part 40 are made of the same metal material, as described above. In this case, through electrode 20 and alignment mark part 40 can be formed at the same time by the same process steps.
Next, resist 93 is removed, and unnecessary seed layer 21 on insulating layer 62 is removed. Subsequently, intermediate layer 68 and support 69 are removed, so that the semiconductor chip shown in
In the following, a semiconductor chip according to a second embodiment will be described with reference to
In the semiconductor chip according to the second embodiment, the configurations of through electrode 20 and the alignment mark part for forming alignment mark 47 are the same as the configurations in the semiconductor chip according to the first embodiment. Insulating films 30 and 50 surround through electrode 20 or the alignment mark part. However, insulating film 50 for the insulating separator is formed of a smooth closed curve with no corners in a plane parallel with the surface of semiconductor substrate 10. Corners at which cracks tend to be produced are eliminated, so that it is possible to maintain the effect of insulating film 50 that prevents metal atoms from diffusing.
In the following, a semiconductor chip according to a third embodiment will be described with reference to
In the third embodiment, the configurations of through electrode 20 and the alignment mark part forming alignment mark 47 are the same as the configurations in the semiconductor chip according to the first embodiment. Insulating films 30 and 50 surround through electrode 20 or alignment mark part 40. In this embodiment, insulating films 30 and 50 form a side wall that makes contact with through electrode 20 or alignment mark part 40 (also see
Next, a method for fabricating the semiconductor chip according to the third embodiment will be described. First, as similar to the first embodiment, semiconductor substrate 10 is prepared. Here, the processes shown in
Subsequently, as shown in
Subsequently, silicon nitride films 32 and 52 and silicon oxide films 34 and 54 are formed on the bottom face and side face of hole 92. In this manner, insulating films 30 and 50 formed of silicon nitride films 32 and 52 and silicon oxide films 34 and 54 are formed. Subsequently, extra silicon oxide films 34 and 54 and/or silicon nitride films 32 and 52 on second surface 10b of semiconductor substrate 10 are removed by an etch back process, as necessary (see
As shown in
Subsequently, as shown in
As described above, preferably, through electrode 20 and alignment mark part 40 are made of the same metal material. In this case, through electrode 20 and alignment mark part 40 can be formed at the same time by the same process steps.
Subsequently, resist 93 and unnecessary seed layers 21 and 41 are removed, and intermediate layer 68 and support 69 are removed, so that it is possible to fabricate the semiconductor chip according to the third embodiment.
Next, a semiconductor device including the aforementioned semiconductor chips stacked on each other will be described.
As shown in
First semiconductor chip 100a and second semiconductor chip 100b are then heated at the melting point of solder 150, or more, at a temperature of about 300° C., for example, for reflowing solder 150, while pressing first semiconductor chip 100a against second semiconductor chip 100b at a constant pressure. As described above, through electrodes 20 of semiconductor chips 100a and 100b are electrically connected to each other, and wiring layers 78 of semiconductor chips 100a and 100b are also electrically connected to each other. A pressure (load) applied in joining the chips to each other may be applied to the extent that the pressure does not affect internal structures formed in semiconductor chips 100a and 100b.
It is noted that in joining semiconductor chips 100a and 100b to each other, conductor 40 used for the alignment mark of first semiconductor chip 100a is not electrically connected to second semiconductor chip 100b.
Similarly, third semiconductor chip 100c is mounted on second semiconductor chip 100b, and then fourth semiconductor chip 100d is mounted on third semiconductor chip 100c.
Subsequently, underfill resin 110 is filled between semiconductor chips 100a to 100d. Subsequently, through electrode 20 for an external terminal formed on semiconductor chip 100a of the lowermost level is connected to package substrate 130. Subsequently, ball grid array (BGA) 140 formed of mold resin 120 and a solder ball is formed. Thus, semiconductor device 200 shown in
The uppermost semiconductor chip 100d may receive signals and power supplied from terminal 70 of semiconductor chip 100c through terminal 160 of chip 100d of semiconductor chip 100c. It is not necessary for the uppermost semiconductor chip 100d to supply signals supplied from terminal 70 of semiconductor chip 100c to the other semiconductor chips. Therefore, through electrode 20 does not need to be formed in uppermost semiconductor chip 100d. As described above, in the case where through electrode 20 is not formed in semiconductor chip 100d, it is unnecessary to reduce the thickness of the chip to facilitate the formation of through electrode 20. Therefore, the thickness of uppermost semiconductor chip 100d can be made thicker than the thicknesses of other semiconductor chips 100a to 100c. As a result, it is possible to suppress the deformation of the chips caused by thermal stress in fabricating semiconductor device 200, more specifically, in mounting uppermost semiconductor chip 100d on semiconductor chip 100c.
It is noted that in
From a viewpoint that all the semiconductor chips can be formed in a similar configuration, the uppermost semiconductor chip may have through electrodes and terminals that are similar to the other semiconductor chips. The foregoing advantages can also be obtained by applying the invention of the present application to such semiconductor devices.
While preferred embodiments of the present invention have been described using specific terms, such description is for illustrative purposes only, and it is to be understood that changes and variations may be made without departing from the spirit or scope of the following claims.
Number | Date | Country | Kind |
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2011-086330 | Apr 2011 | JP | national |
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Number | Date | Country | |
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20150206827 A1 | Jul 2015 | US |
Number | Date | Country | |
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Parent | 14196560 | Mar 2014 | US |
Child | 14676934 | US | |
Parent | 13427960 | Mar 2012 | US |
Child | 14196560 | US |