A semiconductor device includes a protective circuit at an input/output port thereof, wherein the protective circuit includes a plurality of protective MOS transistors. A diffused region is disposed between the n-type source/drain regions and a guard ring formed in a p-well for encircling the source/drain regions of the protective transistors. The diffused region is of lightly doped p-type or of an n-type and increases the resistance of a parasitic bipolar transistor formed in association with the protective transistors. The increase of the resistance assists protective function of the protective device against an ESD failure of the internal circuit of the semiconductor device.
|
1. A semiconductor device comprising
a semiconductor substrate having a substrate region of a first conductivity type or a second conductivity type opposite to said first conductivity type, a first well region of said first conductivity type formed on a surface region of said semiconductor substrate and having a first impurity concentration, said first well region receiving therein at least one MOS transistor, a guard ring of said first conductivity type disposed on a surface region of said semiconductor substrate and within a second well region, said at least one MOS transistor having source/drain regions of said second conductivity type and surrounded by said first well region, and a diffused region formed on the substrate region and disposed between said source/drain regions of said at least one MOS transistor and said guard ring, said diffused region being of said first conductivity type implemented by a portion of said substrate and having a second impurity concentration lower than said first concentration.
2. The semiconductor device as defined in
3. The semiconductor device as defined in
4. The semiconductor device as defined in
5. The semiconductor device as recited in
a parasitic transistor formed between said source/drain regions of said at least one MOS transistor, said parasitic transistor protecting said at least one MOS transistor by turning on to enter a snap-back operation upon a surge voltage.
|
(a) Field of the Invention
The present invention relates to a semiconductor device having a protective circuit, and more particularly to a structure of a protective transistor capable of protecting the internal circuit of the semiconductor device against an electrostatic breakdown.
(b) Description of the Related Art
In general, when electrostatic charge enters a semiconductor device during the course of a fabrication or inspection process, or during a stage of mounting the semiconductor device onto electronic equipment, the internal circuit of the semiconductor device is prone to breaking. Therefore, a protective transistor is generally provided at an input/output port of a semiconductor device through which the internal circuit is connected to an external circuit.
Next, the operation of the input protective circuit formed by the input/output circuit section will be described with reference to
Next, the principle of the protective transistor will be described with reference to FIG. 3B. The abscissa represents the emitter-to-collector voltage (source-to-drain voltage), and the ordinate represents the collector current. Assuming that, due to electrostatic charge, positive surge voltage enters from the pad 22, a strong electric field is generated between the collector 14c and the emitter 16c, with the result that breakdown starts in the drain region 14n in the vicinity of the gate 15n (at BVDS {circle around (3)} in FIG. 3B). Due to this breakdown, a small breakdown current flows from the pad 22 into the P-well 11 and then flows to the ground via the parasitic resistor 17 and the guard ring 18n through a path {circle around (1)} in FIG. 3A). When the small breakdown current flows through the parasitic resistor 17, a voltage is generated across the parasitic resistor 17 with a resultant increase in the potential of the base 11c. When the potential of the base 11c relative to the emitter 16c exceeds 0.6 to 0.7 volts (i.e., the threshold voltage VBE of the parasitic transistor), the parasitic transistor 12 turns on, resulting in that current starts to flow from the collector 14c to the emitter 16c through a path {circle around (2)} in FIG. 3A). The collector voltage at this stage will be referred to as an initial breakdown voltage V1 and the collector current at this stage will be referred to as a collector current I1 (point {circle around (4)} in FIG. 3B). When the parasitic transistor 12 turns on, the emitter-to-collector voltage decreases abruptly to a snap-back voltage Vsnp that is determined at point {circle around (5)} in
When the current due to the ESD surge increases further, the current starts to flow to ground via the parasitic transistor 12 and the parasitic resistor 17 through paths {circle around (1)} and {circle around (2)} in FIG. 3A. However, due to the internal resistance of the parasitic transistor 12, the emitter-to-collector voltage increases with the collector current as shown as a snap-back region in FIG. 3B. When the emitter-to-collector voltage exceeds the withstand voltage of the parasitic transistor 12, the parasitic transistor 12 is destroyed at the state {circle around (6)} shown in FIG. 3B. The emitter-to-collector voltage at the time of breakage of the parasitic transistor 12 is represented by Vmax, and the collector current at the time of breakage is represented by Imax in FIG. 3B.
Although the pMOSFET 32 operates similarly to the case of nMOSFET 31, the operation of the pMOSFET 32 differs from that of the nMOSFET 31 in that the pMOSFET 32 provides protection against negative surge voltage, because a PNP parasitic transistor is formed in the pMOSFET 32. In this way, even when an ESD surge on the order of tens of thousands volts is applied to the pad 22, the voltage of the drain 14n can-be suppressed to as low as a few tens of volts by the protective circuit including the nMOSFET 31 and the pMOSFET 32. Accordingly, an extreme high voltage due to ESD surge is not transmitted to the internal circuit, thereby preventing break down of the internal circuit.
In the protective circuit, the initial breakdown voltage V1 varies depending on the resistance of the parasitic resistor 17. In order to protect the internal circuit, the voltage V1 is preferably decreased to a possible extent. However, if the parasitic transistor 12 operates in response to ordinary signals, the internal circuit will fail to function. Therefore, the initial breakdown voltage V1 must be greater than several times the voltage of ordinary signals. In order to secure a desired initial breakdown voltage V1, the resistance of the parasitic resistor 17 of the P-well 11 must be set to a specific value. The impurity concentration of the P-well 11 is determined in accordance with the performance of transistors that constitute the internal circuit and other factors, and therefore, the resistance of the parasitic resistor 17 can be determined through change of the impurity concentration of the P-well 11. If the impurity concentration of the P-well 11 is to change, separate processes for forming different wells must be provided for the internal circuit and the input/output circuit section in order to change the impurity concentration of the P-well 11. This increases the number of processes, with a resultant increase in the cost of the semiconductor device. Therefore, this method is not preferred.
In order to set the resistance of the parasitic resistor 17 at the specific value, the distance 20 between the source 14n and the guard ring 18n may be set to a desired value. Incidentally, in response to demands for reduction in cost and increase in operational speed of semiconductor devices, transistor elements that constitute an internal circuit have been progressively miniaturized year after year. In order to reduce the size of a semiconductor device, the impurity concentration of the substrate must be increased in accordance with the scaling-down rule. Since the resistivity of the substrate decreases as the impurity concentration increases, the distance between the guard ring and the source should be increased for a larger resistance. In an exemplified case where the impurity concentration of the substrate is 2.0×1017 cm-3, the distance between the guard ring and the source should be set at 10 μm. However, this relatively large distance increases the area occupied by the protective transistor, hindering efforts to increase the degree of integration.
In view of the foregoing, an object of the present invention is to provide a structure of a protective transistor suitable for miniaturized semiconductor devices.
The present invention provides, in an embodiment thereof, a semiconductor device including a semiconductor substrate having a substrate region of a first conductivity type or a second conductivity type opposite to the first conductivity type, a well region of the first conductivity type formed on a surface region of the semiconductor substrate and having a first impurity concentration, a guard ring of the first conductivity type disposed on a surface region of the semiconductor substrate within the well region, a MOS transistor having source/drain regions of the second conductivity type and surrounded by the well region, and a diffused region disposed between the source/drain regions of the MOS transistor and the guard ring, the diffused region being of the first conductivity type having a second impurity concentration lower than the first concentration or of the second conductivity.
In accordance with the embodiment of the semiconductor device of the present invention as described above, since the substrate region of a first or second conductive type is provided between the source of a protective transistor and the guard ring, the parasitic resistance of the parasitic bipolar transistor can be increased, resulting in that the distance between the source and the guard ring need not be large, and thus, a small chip size for the semiconductor device can be obtained.
The above and other objects, features and advantages of the present invention will be more apparent from the following description, referring to the accompanying drawings.
Generally, an input/output circuit section of the semiconductor device according to the present invention includes a pair of MOSFETs including an nMOSFET and a pMOSFET, as in the case of conventional input/output circuit section described in the Related Art section. By means of overlying interconnects formed above the substrate, the input/output circuit section is selectively fabricated as a protective circuit or an output buffer. Alternatively, a portion of the input/output circuit section is fabricated as a protective circuit and the remaining portion is formed as an output buffer. Since the interconnects used for the input/output circuit section in the semiconductor device of the present invention are similar to those in the conventional input/output circuit section, the description therefor is omitted. In addition, in the following description, among the transistors of the input/output circuit section, only the structure of the nMOSFET will be described in detail, because, with the exception of polarity, the pMOSFET has a structure similar to that of the nMOSFET.
Referring to
Next, the operation will be described with reference to FIG. 4B. As in the case of conventional technique, an NPN parasitic transistor 12 is formed at a location corresponding to the first transistor 33 adjacent to the guard ring 18n such that the drain 14n serves as a collector, the source 16n serves as an emitter, and the first P-well 11a serves as a base. A parasitic resistor 17a is formed between the base and the guard ring 18n. When a surge voltage due to electrostatic charge is applied to the pad 22, a surge current flows to the drain via the interconnect 14a, resulting in breakdown occurring at the interface between the drain region 14n and the first P-well 11a. Due to the breakdown, surge current flows from the pad 22 to the guard ring 18n via the parasitic resistor 17a; i.e., via the first P-well 11a, the lightly-doped P-type region 10a, and the second P-well 11b, and then flows to the ground. When the surge current flows through the parasitic resistor 17a, a voltage drop is generated across the parasitic resistor 17a. When the base voltage of the parasitic transistor 12 exceeds the threshold voltage VBE, a current flows through the parasitic transistor 12, resulting in that the collector voltage is suppressed to a predetermined value or less. In this way, the protective circuit prevents the ESD surge from being transmitted to the internal circuit to thereby protect the internal circuit.
As described above, the parasitic resistor 17a in the present embodiment is formed in the first P-well 11a, the lightly-doped P-type region 10a, and the second P-well 11b. Since the impurity concentration of the lightly-doped P-type region 10a is two orders of magnitude lower than that of the first and second P-wells 11a and 11b, the resistivity of the lightly-doped P-type region 10a is large. Therefore, even when the length of the parasitic resistor 17a is made smaller than that of the conventional parasitic resistor 17 implemented by the P-well 11, the resistance of the parasitic resistor 17a can be made equal to that of the conventional parasitic resistor 17. Conventionally, the distance between the guard ring 18n and the source region 16n of the first transistor 33 adjacent to the guard ring 18n is on the order of 10 μm. By contrast, a similar parasitic resistance can be obtained even when the distance is decreased to about 3 μm. Therefore, the size of the nMOSFET 31 can be decreased, so that the chip size of the semiconductor device can be decreased. Further, since the lightly-doped P-type region 10a between the first P-well 11a and the second P-well 11b can be formed through modification of a mask pattern for the wells in the internal circuit, the P-type region 10a can be formed without involving an additional fabrication process.
Referring to
Referring to
Conventionally, the distance between the guard ring 18n and the source region 16n of the first transistor 33 adjacent to the guard ring 18n was about 10 μm. By contrast, the same resistance as that of the conventional parasitic resistor can be obtained even when the distance is decreased to about 3 μm. Therefore, the size of the nMOSFET 31 can be decreased, resulting in that the chip size of the semiconductor device can be decreased. Further, since the N-well 25 disposed between the first P-well 11a and the second 11b can be formed in a common fabrication step for forming N-wells in the internal circuit, the N-well 25 can be formed through modification of a mask pattern, without addition of any specific fabrication process.
Referring to
Referring to
Referring to
Referring to
Referring to
The present inventors noticed the fact that in order to initiate a snap-back operation of the first protective transistors disposed adjacent to the guard ring prior to the snap-back operation of the second transistors, the parasitic bipolar transistor requires a higher base potential than the conventional protective circuit. In this respect, in each of the first, third, fifth, seventh, and ninth embodiments, there has been described a technique for increasing the resistance of the parasitic resistor formed in the path of breakdown current of the first protective transistors 33 disposed adjacent to the guard ring, without increasing the distance between the guard ring and the protective transistors.
In each of the second, fourth, sixth, and eighth embodiments, a substrate region of a first or second conductivity type is provided on the right and left portions in the respective drawings. Therefore, there can be realized a semiconductor device in which a snap-back operation occurs quickly, and which has an enhanced resistance against latch-up and noise during operation. The guard ring provides an enhanced effect in prevention of latch-up, when the resistance between the drain region and the guard ring is low, thereby decreasing the substrate resistance of a current path between a current source and a point from which substrate current is withdrawn.
Referring to
The operation of the present embodiment will be described with reference to FIG. 12B. Especially, in a semiconductor device in which the gate of an output transistor is connected to a pre-buffer, when a surge current enters the device, the gate potential increases via a capacitive coupling, resulting in that a channel current flows from the drain to the source. As a result, concentration of current occurs, and when the parasitic resistance of the P-well is low, breakdown current and channel current both flow into the protective transistor before the protective transistor enters a snap-back operation, resulting in breakage of the protective transistor (at point {circle around (7)} in FIG. 12B).
In the present embodiment, since the gates of the output transistors used as an output-stage pre-buffer are selectively grounded, the resistance of the selected output buffer transistors increases, with the result that the second protective transistors 34 require a higher voltage to enter a bipolar operation as compared with the first protective transistors 33. Consequently, the output buffer transistors 34 enter a snap-back operation less easily than do the first protective transistors 33, so that the first protective transistors 33 in the buffer region cause the snap-back operation. This structure allows the second protective transistors to reliably enter a snap-back operation for protection against a surge voltage caused by electrostatic charge. A semiconductor device according to the present embodiment was experimentally fabricated and the ESD withstand voltage was measured. The measurement demonstrated that the ESD withstand voltage was increased from a conventional level of 1000 V (MIL standard) to 4000 V, and that a sufficient effect is obtained.
Since the above embodiments are described only for examples, the present invention is not limited to the above embodiments and various modifications or alterations can be easily made therefrom by those skilled in the art without departing from the scope of the present invention.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
5572294, | Oct 27 1993 | Minolta Co., Ltd. | Contact charger and image forming apparatus provided with same |
5751042, | Feb 15 1996 | Winbond Electronics Corporation | Internal ESD protection circuit for semiconductor devices |
5754380, | Apr 06 1995 | Transpacific IP Ltd | CMOS output buffer with enhanced high ESD protection capability |
5874763, | Dec 02 1995 | SAMSUNG ELECTRONICS CO , LTD | Integrated circuits having improved electrostatic discharge capability |
JP5840865, | |||
JP6318674, | |||
JP8288403, | |||
JP9148452, | |||
JP9181195, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Mar 24 1999 | NEC Corporation | (assignment on the face of the patent) | / |
Date | Maintenance Fee Events |
Date | Maintenance Schedule |
Feb 26 2005 | 4 years fee payment window open |
Aug 26 2005 | 6 months grace period start (w surcharge) |
Feb 26 2006 | patent expiry (for year 4) |
Feb 26 2008 | 2 years to revive unintentionally abandoned end. (for year 4) |
Feb 26 2009 | 8 years fee payment window open |
Aug 26 2009 | 6 months grace period start (w surcharge) |
Feb 26 2010 | patent expiry (for year 8) |
Feb 26 2012 | 2 years to revive unintentionally abandoned end. (for year 8) |
Feb 26 2013 | 12 years fee payment window open |
Aug 26 2013 | 6 months grace period start (w surcharge) |
Feb 26 2014 | patent expiry (for year 12) |
Feb 26 2016 | 2 years to revive unintentionally abandoned end. (for year 12) |