The present invention relates to a semiconductor device, in particular, to the technology which is effective when applied to a semiconductor device that is used as a driver for LCD (Liquid Crystal Display).
Japanese Patent Laid-Open No. 2006-210607 describes the technique capable of reducing the chip size. Specifically, buffers are arranged collectively in regions distant from pads, respectively. The regions are the main region except for the regions where the central processing unit, the nonvolatile memory, and the volatile memory are formed. The buffers that require a large area are not provided in the pad peripheral part, and therefore, it is possible to reduce the interval between the pads and the distance between the pad and the internal circuit (for example, the central processing unit). Due to this, the chip size can be reduced.
Japanese Patent Laid-Open No. 2007-103848 describes the technique capable of reducing the size of a semiconductor chip. Specifically, first the pad and the wiring other than the pad are provided over the insulating film. Over the insulating film including over the pad and the wiring, the surface protection film is formed and the opening is provided in the surface protection film. The opening is formed over the pad and the surface of the pad is exposed. Over the surface protection film including the opening, the bump electrode is formed. Here, the pad is configured to have the size sufficiently smaller than that of the bump electrode. Due to this, the wiring is disposed immediately under the bump electrode and in the same layer as that of the pad. That is, the wiring is disposed in the space under the bump electrode formed by reducing the size of the pad.
In recent years, an LCD that uses liquid crystal as a display element has been spreading rapidly. The LCD is controlled by a driver that drives the LCD. The LCD driver includes a semiconductor chip, and is mounted on a glass substrate. The semiconductor chip that constitutes the LCD driver has a structure in which a plurality of transistors and multilayer wirings are formed over a semiconductor substrate and bump electrodes are formed on the surface thereof. Then, the semiconductor chip is mounted on the glass substrate via the bump electrode formed on the surface.
The semiconductor chip that constitutes an LCD driver is in the form of a rectangle having short sides and long sides and a plurality of bump electrodes is arranged along the long-side direction of the semiconductor chip. For example, along a first long side of a pair of long sides, input bump electrodes are arranged linearly and along a second long side in opposition to the first long side, output bump electrodes are arranged in a staggered manner. That is, the semiconductor chip constituting an LCD driver is characterized in that the number of output bump electrodes is greater than that of input bump electrodes. This is because the input bump electrode receives mainly serial data while the output bump electrode outputs parallel data converted by the LCD driver.
Accompanying the miniaturization of semiconductor elements, the downsizing of the semiconductor chip constituting an LCD driver is also being progressed. However, in the semiconductor chip constituting an LCD driver, the length in the long-side direction is affected largely by the number of bump electrodes. That is, in a liquid crystal display device, the number of output bump electrodes of an LCD driver is substantially determined, and therefore, the number of output bump electrodes cannot be reduced and it is becoming difficult to reduce the long side of the semiconductor chip constituting the LCD driver. That is, it is necessary to form a predetermined number of output bump electrodes along the long side of the semiconductor chip constituting the LCD driver, however, the distance between the bump electrodes has been reduced to a minimum, and therefore, it is difficult to further reduce the length in the long-side direction of the semiconductor chip.
An object of the present invention is to reduce the chip size of a semiconductor chip.
The above-mentioned and the other purposes and the new feature of the present invention will become clear from the description of the present specification and the accompanying drawings.
The following explains briefly the outline of a typical invention among the inventions disclosed in the present application.
A semiconductor device according to a typical embodiment comprises a semiconductor chip in the form of a rectangle having a pair of short sides and a pair of long sides. Here, the semiconductor chip includes (a) a plurality of first bump electrodes arranged along a first long side of the semiconductor chip and arranged at a position closer to the first long side than to a second long side in opposition to the first long side, (b) an internal circuit formed in the semiconductor chip, and (c) a plurality of first electrostatic protection circuits which protect the internal circuit against static electricity and are electrically coupled to the first bump electrodes. At this time, part of the first electrostatic protection circuits electrically coupled to part of the first bump electrodes are arranged at a position that overlaps the part of the first bump electrodes in a planar view, and the other first electrostatic protection circuits of the first electrostatic protection circuits electrically coupled to the other first bump electrodes of the first bump electrodes are arranged at a position different from a position that overlaps the other first bump electrodes in a planar view.
A semiconductor device according to a typical embodiment comprises a semiconductor chip in the form of a rectangle having a pair of short sides and a pair of long sides. Here, the semiconductor chip includes (a) a plurality of first bump electrodes arranged along a first long side of the semiconductor chip and arranged at a position closer to the first long side than to a second long side in opposition to the first long side, (b) an internal circuit formed in the semiconductor chip, and (c) a plurality of first electrostatic protection circuits which protect the internal circuit against static electricity and are electrically coupled to the first bump electrodes. At this time, the first electrostatic protection circuits are arranged at a position different from a position that overlaps the first bump electrodes in a planar view.
A semiconductor device according to a typical embodiment comprises a semiconductor chip in the form of a rectangle having a first short side, a second short side in opposition to the first short side, a first long side, and a second long side in opposition to the first long side. Here, the semiconductor chip includes (a) first bump electrodes and second bump electrodes arranged along the first long side of the semiconductor chip and arranged at a position closer to the first long side than to the second long side and (b) an uppermost layer wiring arranged via an insulating film at a position that overlaps the first bump electrode and the second bump electrode in a planar view. Further, the semiconductor chip includes (c) a first opening formed in the insulating film in order to be coupled to the first bump electrode and (d) a second opening formed in the insulating film in order to be coupled to the second bump electrode. At this time, the position where the first opening is formed relative to the first bump electrode is different from the position where the second opening is formed relative to the second bump electrode in the direction along the first short side or the second short side.
A semiconductor device according to a typical embodiment comprises a semiconductor chip in the form of a rectangle having a pair of short sides and a pair of long sides. Here, the semiconductor chip includes (a) first bump electrodes and second bump electrodes arranged along a first long side of the semiconductor chip and arranged at a position closer to the first long side than to a second long side in opposition to the first long side and (b) an uppermost layer wiring arranged via an insulating film at a position that overlaps the first bump electrode and the second bump electrode in a planar view. The semiconductor chip further has (c) a first opening formed in the insulating film in order to be coupled to the first bump electrode and (d) a second opening formed in the insulating film in order to be coupled to the first bump electrode. At this time, the uppermost layer wiring includes a first uppermost layer wiring that is coupled to the first bump electrode via the first opening and a second uppermost layer wiring which is coupled to the first bump electrode via the second opening and is different from the first uppermost layer wiring, and the first opening and the second opening are formed so as to be coupled to the first bump electrode at different positions.
A semiconductor device according to a typical embodiment comprises a semiconductor chip in the form of a rectangle having a first short side, a second short side in opposition to the first short side, a first long side, and a second long side in opposition to the first long side. Here, the semiconductor chip includes (a) first bump electrodes arranged along the first long side of the semiconductor chip and arranged at a position closer to the first long side than to the second long side in opposition to the first long side, (b) an internal circuit formed in the semiconductor chip, and (c) a first electrostatic protection circuit which protects the internal circuit against static electricity and is electrically coupled to the first bump electrode. At this time, the internal circuit is disposed at a position that overlaps the first bump electrode in a planar view and the first electrostatic protection circuit is arranged at a position different from a position that overlaps the first bump electrode in a planar view.
A semiconductor device according to a typical embodiment comprises a semiconductor chip in the form of a rectangle having a first short side, a second short side in opposition to the first short side, a first long side, and a second long side in opposition to the first long side. Here, the semiconductor chip includes (a) first bump electrodes arranged along the first long side of the semiconductor chip and arranged at a position closer to the first long side than to the second long side in opposition to the first long side, (b) an internal circuit formed in the semiconductor chip, and (c) a first electrostatic protection circuit which protects the internal circuit against static electricity and is electrically coupled to the first bump electrode. At this time, the first electrostatic protection circuit is disposed at a position different from a position that overlaps the first bump electrode in a planar view and a plurality of wirings passes at the position that overlaps the first bump electrode in a planar view.
The following explains briefly the effect acquired by the typical invention among the inventions disclosed in the present application.
It is possible to reduce the chip size of a semiconductor chip.
The following embodiments will be explained, divided into plural sections or embodiments, if necessary for convenience. Except for the case where it shows clearly in particular, they are not mutually unrelated and one has relationships such as a modification, details, and supplementary explanation of some or entire of another.
In the following embodiments, when referring to the number of elements, etc. (including the number, a numeric value, an amount, a range, etc.), they may be not restricted to the specific number but may be greater or smaller than the specific number, except for the case where they are clearly specified in particular and where they are clearly restricted to a specific number theoretically.
Furthermore, in the following embodiments, it is needless to say that an element (including an element step etc.) is not necessarily indispensable, except for the case where it is clearly specified in particular and where it is considered to be clearly indispensable from a theoretical point of view, etc.
Similarly, it is assumed that, in the following embodiments, when the shapes, positional relationships, etc., of the components etc. are referred to, except when explicitly stated in particular or when they can apparently be thought otherwise in principle, those substantially similar to or resembling the shapes etc. are also included. This also applies to the above-mentioned numerical values and ranges.
In all of the drawings for explaining embodiments, the same symbol is attached to the same member, as a principle, and the repeated explanation thereof is omitted. In order to make a drawing intelligible, hatching may be attached even if it is a plane view.
For an LCD driver, the downsizing of a semiconductor chip is progressed as described above, and in particular, the reduction of a semiconductor chip in the short-side direction has been examined.
First, an external configuration of a general LCD driver will be described.
The semiconductor chip CHP1 is in the form of a rectangle having a pair of short sides (short side SS1 and short side SS2) and a pair of long sides (long side LS1 and long side LS2) and along one of the pair of long sides, that is, the long side LS1 (side on the lower side in
Next, along the other of the pair of long sides, that is, the long side LS2 (side on the upper side in
As described above, along the pair of the long side LS1 and the long side LS2 constituting the outer circumference of the semiconductor chip CHP1, the input bump electrodes IBMP and the output bump electrodes OBMP are formed as a result. At this time, the number of the output bump electrodes OBMP is greater compared to the number of the input bump electrodes IBMP, and therefore, while the input bump electrodes IBMP are formed linearly along the long side LS1, the output bump electrodes OBMP are arranged along the long side LS2 in a staggered manner. This is because while the input bump electrode IBMP is a bump electrode for an input signal to be input to an LDC driver, the output bump electrode OBMP is a bump electrode for an output signal to be output from an LCD driver. That is, an input signal to be input to an LCD driver is serial data, and therefore, the number of the input bump electrodes IBMP, an external connection terminal, is not so great. In contrast to this, an output signal to be output from an LCD driver is parallel data, and therefore, the number of the output bump electrodes OBMP, an external connection terminal, is great. That is, the output bump electrode OBMP is provided corresponding to each individual cell (pixel) constituting a liquid crystal display element, and therefore, the number of the output bump electrodes OBMP needs to be that corresponding to the number of rows and columns (for example, gate line, source line) for driving cells. Because of this, the number of the output bump electrodes OBMP is greater than that of the input bump electrodes IBMP. As a result of the above, it is possible to arrange the input bump electrodes IBMP along the long side LS1 linearly, however, the output bump electrodes OBMP are arranged along the long side LS2 in a staggered manner so that the number of the output bump electrodes OBMP that can be arranged is increased.
In
The external configuration of the semiconductor chip CHP1 is as described above, and the function of an LCD driver that is realized by an integrated circuit formed in the semiconductor chip CHP1 will be described below.
The I/O circuit has a function to input/output data to be input to and output from the semiconductor chip CHP1, and the SRAMs 2a, 2b are an example of a storage circuit (memory circuit) that stores data. The SRAMs 2a, 2b have a structure in which storage elements that store data are arranged in an array and store data of images etc. to be displayed in a liquid crystal display device. The word driver has a function to select a row of the SRAMs 2a, 2b arranged in an array (matrix) and the SRAM control part has a function to control the writing of data to and reading data from the SRAMs 2a, 2b. That is, the SRAM control part includes an address decoder and a read/write control circuit to control the reading and writing of the SRAMs 2a, 2b.
The LCD control part has a function to generate access signals for a microcomputer to be mounted outside the LCD driver (semiconductor chip CHP1), timing signals to operate the SRAMs 2a, 2b and an internal circuit required to produce a display of a counter, etc., and comprises a reset circuit to reset a display, a clock circuit to generate a clock signal, etc. Further, the analog part has a function (level shift function) to, for example, increase the voltage level of image data stored in the SRAMs 2a, 2b and convert the voltage into a voltage suitable to a liquid crystal display cell etc. That is, the analog circuit is configured so as to include a step-up circuit to increase a voltage and so as to generate various voltages to be applied to a liquid crystal display cell.
The input protection circuit 3 is a circuit having a function to protect internal circuits (SRAM, word driver, SRAM control part, LCD control part, analog part, etc.) against a surge voltage applied accidentally to the input bump electrode IBMP. Here, a surge voltage refers to an abnormal voltage induced instantaneously by static electricity etc. Similarly, the output protection circuit 4 is a circuit that protects the internal circuit against a surge voltage applied accidentally to the output bump electrode OBMP. By providing the input protection circuit 3 and the output protection circuit 4 as described above, it is possible to protect the internal circuit that realizes the function of the LCD driver against static electricity etc.
A configuration example of the input protection circuit 3 and the output protection circuit 4 will be described below.
First, the normal operation will be described. When an input voltage is applied to the input bump electrode IBMP, the potential at the terminal A becomes a predetermined potential. At this time, the potential at the terminal A is higher than the ground potential Vss and lower than the power source potential Vdd. Because of this, when the diode D1 is considered, the cathode of the diode D1 (potential at the terminal A) is higher in potential than the anode of the diode D1 (ground potential Vss), and therefore, no current flows through the diode D1. Similarly, when the diode D2 is considered, the cathode of the diode D2 (power source potential Vdd) is higher in potential than the anode of the diode D2 (potential at the terminal A), and therefore, no current flows through the diode D2. As described above, in the normal operation, no current flows through the diode D1 or the diode D2, and therefore, an input voltage (input signal) input to the input bump electrode IBMP is output to the internal circuit IU.
Subsequently, an abnormal operation will be described. For example, a case is considered, where a surge voltage is applied to the input bump electrode IBMP due to the influence of static electricity etc. Specifically, when a positive voltage greater than the power source potential Vdd is applied as a surge voltage, a positive voltage greater than the power source potential Vdd is applied to the terminal A to which the cathode of the diode D1 is coupled. Because of this, to the diode D1, a great backward voltage is applied, causing breakdown, and a backward current flows from the terminal A toward the ground potential Vss. On the other hand, a positive voltage greater than the power source potential Vdd is applied to the anode of the diode D2, and therefore, a forward current flows through the diode D2 from the terminal A toward the power source potential Vdd. As described above, when a positive voltage greater than the power source potential Vdd is applied as a surge voltage, the diode D1 breaks down in the backward direction and the diode D2 turns on in the forward direction, and therefore, it is possible to let charges accompanying the surge voltage escape to the power source line or the ground line. As a result of that, it is possible to prevent the internal circuit IU from being destroyed by the application of a high voltage.
Similarly, when a negative voltage of absolute value greater than the ground potential Vss is applied as a surge voltage, a negative potential smaller than the ground potential Vss is applied to the terminal A to which the cathode of the diode D1 is coupled. Because of this, a forward voltage is applied to the diode D1 and a forward current flows from the ground potential Vss toward the terminal A. On the other hand, a great negative potential is applied to the anode of the diode D2, and therefore, a great backward voltage is applied to the diode D2, the diode D2 breaks down, and a backward current flows from the power source potential Vdd toward the terminal A. As described above, when a great negative voltage is applied as a surge voltage, the diode D2 breaks down in the backward direction and the diode D1 turns on in the forward direction, and therefore it is possible to let charges accompanying the surge voltage escape to the power source line and the ground line. As a result of that, it is possible to prevent the internal circuit IU from being destroyed by the application of a high voltage.
Further,
In the input protection circuit 3 also, which has the above-described configuration, when a surge voltage is applied to the terminal A from outside, one of the n-channel type MISFET Tr1 and the p-channel type MISFET Tr2 turns on in accordance with the polarity of the surge voltage and the other breaks down between the source region and the drain region. Due to this, it is possible to let charges accompanying the surge voltage escape to the power source line and the ground line. As a result of that, it is possible to prevent the internal circuit IU from being destroyed by the application of a high voltage. As described above, the configuration example of the input protection circuit 3 is described, and the output protection circuit 4 has a configuration similar to that of the input protection circuit 3.
The main functions of the LCD driver are realized in the functional blocks described above, and these functional blocks are arranged so as to stand side by side in the long-side direction of the semiconductor chip CHP1 in the form of a rectangle as shown in
On the other hand, the analog part includes an analog circuit and the MISFET constituting the analog circuit includes a high withstand voltage MISFET having an operating voltage of the absolute value comparatively higher than that of the low withstand voltage MISFET. This is because the analog circuit has a function to convert the voltage level of image data and apply a voltage of a medium or high voltage (a few tens of V) to the liquid crystal display cell. As described above, in the semiconductor chip CHP1 constituting the LCD driver, a plurality of kinds of MISFET having an operating voltage of different absolute values is formed and in particular, in the SRAM control part and the LCD control part, a low withstand voltage MISFET having an operating voltage of the smallest absolute value is used. In contrast to this, in the analog part, a high withstand voltage MISFET having an operating voltage of the comparatively high absolute value is used. Further, as the MISFET used in the input protection circuit 3 or the output protection circuit 4 described above, a high withstand voltage MISFET is used. The absolute value of operating voltage of these high withstand voltage MISFETs is, for example, about 20 to 30 V.
Next, the operation of the LCD driver will be described briefly. First, serial data to display an image is input from a microcomputer etc. mounted outside the LCD driver (semiconductor chip CHP1). The serial data is input to the LCD control part via an I/O circuit. The LCD control part having received the serial data converts the serial data into parallel data based on a clock signal generated in a clock circuit. Then, the LCD control part outputs a control signal to the SRAM control part to store the converted parallel data in the SRAMs 2a, 2b. The SRAM control part, when receiving the control signal from the LCD control part, activates the word driver and causes the SRAMs 2a, 2b to store image data, which is parallel data. Then, the SRAM control part reads the image data stored in the SRAMs 2a, 2b at a predetermined timing and outputs it to the analog part. The analog part converts the voltage level of the image data (parallel data) and outputs the image data from the LCD driver. The image data (parallel data) output from the LCD driver is applied to each individual liquid crystal display cell and thus an image is displayed. Thus, it is possible for the LCD driver to display an image in the liquid crystal display device.
In the semiconductor chip CHP1 constituting a general LCD driver shown in
Here, points of difference between the semiconductor chip CHP2 in the present first embodiment shown in
In contrast to this, in the semiconductor chip CHP2 in the present first embodiment shown in
As described above, the semiconductor chip CHP2 constituting the LCD driver in the present first embodiment is characterized in that the output protection circuit 4, the SRAMs 2a to 2c, the control part 1, and the input protection circuits 3a to 3c are arranged separately in the two tiers, that is, the upper tier block and the center block, rather than arranged in the three tiers, that is, the upper tier block, the center block, and the lower tier block. In other words, the present first embodiment is characterized in that the input protection circuits 3a to 3c are arranged in part of the center block where the SRAMs 2a to 2c and the control part 1 are arranged instead of that the input protection circuits 3a to 3c are arranged in the lower tier block so that they are arranged along the long side LS1. Due to this, according to the semiconductor chip CHP2 in the present first embodiment, it is possible to reduce the length in the short-side direction. That is, in the semiconductor chip CHP1 constituting the general LCD driver shown in
In the present first embodiment, by devising the position of arrangement of the input protection circuits 3a to 3c, the length in the short-side direction of the semiconductor chip CHP2 is reduced. Specifically, as shown in
The characteristic of the present first embodiment can be expressed differently from the above, such as that part of the input protection circuits 3a, 3b are disposed in an inner region sandwiched between a region where the input bump electrodes IBMP are formed and a region where the output bump electrodes OBMP are formed. It can be expressed further, such as that part of the input protection circuits 3a to 3c are formed in a region that does not overlap the input bump electrodes IBMP in a planar view, or that part of the input protection circuits 3a, 3b are formed in a region adjacent to the SRAMs 2a to 2c in the long-side direction. Furthermore, it can be expressed, such as that part of the input protection circuits 3a, 3b electrically coupled to part of the input bump electrodes IBMP are disposed at a position that overlaps the part of the input bump electrodes in a planar view and the other input protection circuits of the input protection circuits 3a, 3b electrically coupled to the other input bump electrodes of the input bump electrodes IBMP are disposed at a position different from a position that overlaps the other input bump electrodes in a planar view.
In the present first embodiment, the input protection circuit 3a and the input protection circuit 3b are disposed between the SRAMs 2a to 2c, however, there arises a problem whether there exists a space where the input protection circuit 3a and the input protection circuit 3b can be disposed between the SRAMs 2a to 2c as described above. This is because it can be thought normally that the length in the long-side direction of the semiconductor chip CHP2 is determined so that no excess space is left in order to make an attempt to reduce in size the semiconductor chip CHP2. However, in actuality, it is possible to ensure a space into which the input protection circuit 3a and the input protection circuit 3b can be inserted between the SRAMs 2a to 2c. The reason for that will be described below.
The length in the long-side direction of the semiconductor chip CHP2 is also reduced as much as possible, however, the length in the long-side direction is regulated by the output bump electrodes OBMP arranged along the long side LS2. That is, the length in the long-side direction of the semiconductor chip CHP2 is not regulated by the SRAMs 2a to 2c or the control part 1 put side by side along the long-side direction but by the number of the output bump electrodes OBMP. For example, it can be conceived of reducing the formation region of the SRAMs 2a to 2c and the control part 1 put side by side along the long-side direction as much as possible from the standpoint of the reduction in length in the long-side direction of the semiconductor chip CHP2. Specifically, it can be conceived of reducing the space between the SRAMs 2a to 2c and the control part 1 as much as possible. However, even if the length in the long-side direction of the semiconductor chip CHP2 is reduced by densely arranging the formation regions of the SRAMs 2a to 2c and the control part 1 as described above, this attempt will be in vain if all of the output bump electrodes OBMP cannot be arranged along the long side LS2 of the semiconductor chip CHP2. Because of this, it is necessary for the length in the long-side direction of the semiconductor chip CHP2 to have at least a length that allows arrangement of all of the output bump electrodes OBMP. That is, the length in the long-side direction of the semiconductor chip CHP2 is determined from the standpoint of the possibility of arrangement of all of the output bump electrodes OBMP.
At this time, there is a problem of, for example, the relationship in magnitude between the length in the long-side direction of the SRAMs 2a to 2c and the control part 1 put side by side in the long-side direction and the total length of the output bump electrodes OBMP arranged along the long side LS2, however, in actuality, the total length of the output bump electrodes OBMP is greater than the length of the SRAMs 2a to 2c and the control part 1 put side by side. Because of this, if the length in the long-side direction of the semiconductor chip CHP2 is determined so that all of the output bump electrodes OBMP can be arranged, there exists an excess space in the region where the SRAMs 2a to 2c and the control part 1 are put side by side. Because of this, for example, it is possible to ensure a space between the SRAMs 2a to 2c where the input protection circuit 3a and the input protection circuit 3b are inserted. Because of this, in the present first embodiment, it is possible to reduce the length in the short-side direction of the semiconductor chip CHP2 by, for example, inserting the input protection circuit 3a and the input protection circuit 3b between the SRAMs 2a to 2c.
Next, in the semiconductor chip CHP2, the output protection circuit 4 exists in addition to the input protection circuits 3a to 3c. The input protection circuits 3a to 3c and the output protection circuit 4 function as an electrostatic protection circuit that protects the internal circuit against static electricity. Then, they function as the same electrostatic protection circuit, and therefore, it can be thought that the input protection circuits 3a to 3c and the output protection circuit 4 have the same configuration. Because of this, it can be conceived of inserting the output protection circuit 4 instead of the input protection circuits 3a, 3b into the space created when the SRAMs 2a to 2c and the control part 1 are put side by side in the long-side direction. In this case also, if all of the output protection circuits 4 can be inserted into the excess space created between the SRAMs 2a to 2c and the control part 1, it is possible to reduce the length in the short-side direction of the semiconductor chip CHP2. However, in the present first embodiment, the arrangement of the output protection circuit 4 is not modified but only the arrangement of the input protection circuits 3a to 3c is modified. The reason for that will be described below.
As shown in
Here, the space created when the SRAMs 2a to 2c and the control part 1 are put side by side in the long-side direction is not so large. That is, the space created when the SRAMs 2a to 2c and the control part 1 are put side by side in the long-side direction is not large enough to allow the insertion of all of the output protection circuits 4. In other words, it is not possible to make large enough the space created when the SRAMs 2a to 2c and the control part 1 are put side by side in the long-side direction, and therefore, instead of the output protection circuits 4, the input protection circuits 3a to 3c are inserted into the space described above.
Subsequently, a second characteristic point in the present first embodiment will be described. The second characteristic point in the present first embodiment is that the input protection circuits 3a to 3c are dispersed in the long-side direction of the semiconductor chips CHP2 rather than concentrated at one part, as shown in
For example, it is necessary to electrically couple the input protection circuits 3a to 3c between the input bump electrode IBMP and the internal circuit. At this time, for example, in the semiconductor chip CHP1 constituting the general LCD driver shown in
In the present first embodiment, however, in the region that does not overlap the input bump electrode IBMP in a planar view, the input protection circuits 3a to 3c are formed as a result. Because of this, it is necessary to use a routing wiring that extends in the direction of the plane of the semiconductor chip CHP2 in order to couple the input bump electrodes IBMP and the input protection circuits 3a to 3c in the present first embodiment. Based on the assumption of the above, if the input protection circuits 3a to 3c are arranged together at one part, it is necessary to couple the input protection circuits 3a to 3c arranged together and the input bump electrodes IBMP arranged in the long-side direction of the semiconductor chip CHP2 using a routing wiring that extends in the direction of the plane of the semiconductor chip CHP2. In this case, if the input protection circuits 3a to 3c are concentrated at one part, the layout configuration of the routing wiring will become complicated.
Because of this, in the present first embodiment, on the assumption that the input protection circuits 3a to 3c are formed in a region that does not overlap the input bump electrodes IBMP in a planar view, the input protection circuits 3a to 3c are arranged dispersedly. Due to this, it is possible to couple each of the input bump electrodes IBMP arranged in the long-side direction of the semiconductor chip CHP2 to the input protection circuit having the shortest distance from the input bump electrode IBMP, among the input protection circuits 3a to 3c arranged dispersedly. This means that it is possible to reduce the length of a routing wiring used to couple the input bump electrode IBMP and the input protection circuits 3a to 3c and to simplify the layout configuration of the routing wiring more than that in the case where the input protection circuits 3a to 3c are concentrated at one part. Because of this, according to the present first embodiment, due to the first characteristic point that the input protection circuits 3a to 3c are arranged in the space created when the SRAMs 2a to 2c and the control part 1 are put side by side in the long-side direction, it is possible to reduce the length in the short-side direction of the semiconductor chip CHP2 constituting the LCD driver. Then, according to the first characteristic point, the input protection circuits 3a to 3c are formed in the region that does not overlap the input bump electrodes IBMP in a planar view, and further, due to the second characteristic point that the input protection circuits 3a to 3c are arranged dispersedly in the long-side direction of the semiconductor chip CHP2 rather than concentrated at one part, it is possible to simplify the layout configuration of the routing wiring used to electrically couple the input bump electrodes IBMP and the input protection circuits 3a to 3c.
Although it is desirable to comprise the first characteristic point and the second characteristic point as in the present first embodiment, it is possible to sufficiently achieve the object of the present invention to reduce the length in the short-side direction of the semiconductor chip CHP2 even with the configuration in which only the first characteristic point is comprised.
According to the semiconductor chip CHP2 in the present first embodiment, it is possible to reduce the length in the short-side direction of the semiconductor chip CHP2, and this will be described next using an enlarged view.
The input bump electrode IBMP1 and the uppermost layer wiring TM1 are electrically coupled by filling an opening CNT1 with a conductive material. Then, the uppermost layer wiring TM1 is coupled to an input protection circuit 3A via a multilayer wiring formed in the lower layer. Similarly, the input bump electrode IBMP2 and the uppermost layer wiring TM2 are electrically coupled by filling an opening CNT2 with a conductive material. Then, the uppermost layer wiring TM2 is coupled to an input protection circuit 3B via a multilayer wiring formed in the lower layer. In the semiconductor chip CHP1 constituting a general LCD driver as described above, in the lower layers of the input bump electrodes IBMP1, IBMP2, the input protection circuits 3A, 3B are formed. Because of this, the internal circuit IU is formed at an inner side of the input bump electrodes IBMP1, IBMP2 (region farther from the long side LS1) so as not to overlap the input bump electrodes IBMP1, IBMP2 in a planar view. Because of this, the distance between the internal circuit IU and the long side LS1 of the semiconductor chip CHP1 is distance Y1.
In contrast to this,
The input bump electrode IBMP1 and the uppermost layer wiring TM1 are electrically coupled by filling the opening CNT1 with a conductive material, however, in the present first embodiment, no input protection circuit is formed in the lower layer of the uppermost layer wiring TM1. Similarly, the input bump electrode IBMP2 and the uppermost layer wiring TM2 are electrically coupled by filling the opening CNT2 with a conductive material, however, in the present first embodiment, no input protection circuit is formed in the lower layer of the uppermost layer wiring TM2. In the present first embodiment, the input protection circuit (not shown schematically in
Here, from the comparison between the distance Y1 shown in
The part of the input bump electrode IBMP1 in
In the present first embodiment, the example is shown, in which the uppermost layer wirings TM3, TM4 pass through the lower layers of the input bump electrodes IBMP1, IBMP2, however, this is not limited, and the same effect can be obtained when at least one or more uppermost layer wirings pass through. This also applies to the following embodiments.
In the first embodiment described above, the configuration is described, in which, for example, as shown in
In a second embodiment, an example will be described, where no input protection circuit is formed in the lower layer of all of the input bump electrodes IBMP.
At this time, in the present second embodiment also, the input protection circuits 3a, 3b are formed in the space created when the SRAMs 2a, 2b and the control part 1 are put side by side in the long-side direction. However, the input protection circuits 3a, 3b formed in the space are formed so as not to overlap the input bump electrodes IBMP arranged along the long side LS1. That is, in the present second embodiment, unlike the above-mentioned first embodiment, no input protection circuits are formed in the lower layer of any of the input bump electrodes IBMP.
It is also possible to configure the semiconductor chip CHP2 constituting an LCD driver as in the present second embodiment. In the case of the configuration as in the present second embodiment also, due to the first characteristic point that the input protection circuits 3a, 3b are arranged in the space created when the SRAMs 2a, 2b and the control part 1 are put side by side in the long-side direction, it is possible to reduce the length in the short-side direction of the semiconductor chip CHP2 constituting the LCD driver. Then, according to the first characteristic point, the input protection circuits 3a, 3b are formed in a region that does not overlap the input bump electrodes IBMP in a planar view, and further, due to the second characteristic point that the input protection circuits 3a, 3b are arranged dispersedly in the long-side direction of the semiconductor chip CHP2 rather than concentrated at one position, it is possible to simplify the layout configuration of the routing wirings that electrically couple the input bump electrode IBMP and the input protection circuits 3a, 3b. That is, with the layout configuration in the present second embodiment, it is also possible to obtain the same effects as those obtained in the above-mentioned first embodiment.
In the above-mentioned first embodiment, as shown in
Because of this, in the present third embodiment, a technical idea to efficiently make use of the routing wiring that extends in the direction of the plane of the semiconductor chip CHP2 will be described. That is, in the present third embodiment, when the input protection circuits 3a to 3c are formed in a region that does not overlap the input bump electrodes IBMP in a planar view, the wiring layout to electrically couple the input bump electrodes IBMP and the input protection circuits 3a to 3c is devised. A plurality of devices in the present third embodiment will be described below.
First, a first device point in the present third embodiment will be described.
Here, the first device point in the present third embodiment is, for example, a method of coupling the uppermost layer wiring TM1 electrically coupled to the input bump electrodes IBMP1 to IBMP3 and also coupled to the input protection circuit 3, and the input bump electrodes IBMP1 to IBMP3. Specifically, as shown in
That is, there may be a case where another uppermost layer wiring other than the uppermost layer wiring TM1 is arranged in the lower layer of the input bump electrodes IBMP1 to IBMP3. In this case, if the positions where the openings CNT1 to CNT3 are formed for the input bump electrodes IBMP1 to IBMP3 are the same, the arrangement of another uppermost layer wiring may be blocked. Because of this, according to the first device point in the present third embodiment shown in
For example, as shown in
In
Subsequently, a second device point in the present third embodiment will be described.
Here, the input bump electrode IBMP1 and the uppermost layer wiring TM1 are coupled via a conductive material filled in the opening CNT1 and the input bump electrode IBMP2 and the uppermost layer wiring TM2 are coupled via a conductive material filled in the opening CNT2. Further, the input bump electrode IBMP3 and the uppermost layer wiring TM3 are coupled via a conductive material filled in the opening CNT3. This is the second device point in the present third embodiment.
That is, according to the second device point in the present third embodiment, the uppermost layer wirings TM1 to TM3 different from one another are coupled to the input bump electrodes IBMP1 to IBMP3 different from one another, respectively, and the positions where the openings CNT1 to CNT3 for the input bump electrodes IBMP1 to IBMP3 are formed are made to differ from one another. By forming the respective openings CNT1 to CNT3 to be coupled to the input bump electrodes IBMP1 to IBMP3 different from one another at different positions as described above, it is possible to efficiently couple the uppermost layer wirings TM1 to TM3 and the input bump electrodes IBMP1 to IBMP3, respectively, without the need to modify the wiring layout of the uppermost layer wirings TM1 to TM3.
Specifically, due to the second device point in the present third embodiment, the uppermost layer wirings include the uppermost layer wiring TM1 which is coupled to the input bump electrode IBMP1 via the opening CNT1, and passes under the input bump electrode IBMP2, and which is not coupled to the input bump electrode IBMP2, and the uppermost layer wiring TM2 which is coupled to the input bump electrode IBMP2 via the opening CNT2, and passes under the input bump electrode IBMP1, and which is not coupled to the input bump electrode IBMP1. Further, the uppermost layer wirings also include the uppermost layer wiring TM3 which passes under the input bump electrode IBMP1 and the input bump electrode IBMP2 and is not coupled to the input bump electrode IBMP1 or the input bump electrode IBMP2.
Next, a third device point in the present third embodiment will be described.
Here, the input bump electrode IBMP1 and the uppermost layer wiring TM1 are coupled via a conductive material filled in the opening CNT1 and the input bump electrode IBMP2 and the uppermost layer wiring TM2 are coupled via a conductive material filled in the opening CNT2. Then, the input bump electrode IBMP3 and the uppermost layer wiring TM3 are coupled via a conductive material filled in an opening CNT3b. Further, the input bump electrode IBMP3 is also coupled to the uppermost layer wiring TM1 via a conductive material filled in an opening CNT3a. That is, the third device point in the present third embodiment lies in that, for example, the coupling of an input bump electrode to a plurality of different uppermost layer wirings like the input bump electrode IBMP3 that is coupled to the plurality of the different uppermost layer wirings TM1, TM3. Specifically, to the input bump electrode IBMP3, two openings, CNT3a and CNT3b, are coupled. Then, the input bump electrode IBMP3 and the uppermost layer wiring TM1 are coupled via a conductive material filled in the opening CNT3a and the input bump electrode IBMP3 and the uppermost layer wiring TM3 are coupled via a conductive material filled in the opening CNT3b.
That is, the third device point in the present third embodiment lies in that the input bump electrode IBMP3 is caused to have a capability of coupling the uppermost layer wiring TM1 and the uppermost layer wiring TM3. That is, in the third device point, the input bump electrode IBMP3 functions as a wiring to couple the uppermost layer wiring TM1 and the uppermost layer wiring TM3. Due to this, it is no longer necessary to form another wiring to couple the uppermost layer wiring TM1 and the uppermost layer wiring TM3, and therefore, it is possible to make an attempt to simplify the wiring layout.
Incidentally, it is possible to adjust the configuration so that the input bump electrode (the input bump electrodes IBMP1, IBMP2) to be coupled to one opening and the input bump electrode (the input bump electrode IBMP3) to be coupled to a plurality of openings coexist in accordance with the wiring layout without the need to provide a plurality of openings to all of the input bump electrodes IBMP1 to IBMP3 as shown in
As described above, in the present third embodiment, the first device point to the third device point are applied to the wiring layout to electrically couple the input bump electrodes IBMP and the input protection circuits 3a to 3c. An example of a wiring layout that employs the first device point to the third device point will be described below.
First, in the lower layer of the input bump electrode IBMP1, the uppermost layer wirings TM1a, TM2a, TM3a are arranged and the input bump electrode IBMP1 is electrically coupled to the uppermost layer wiring TM1a via a conductive material filled in the opening CNT1.
Next, in the lower layer of the input bump electrode IBMP2, the uppermost layer wirings TM1b, TM2a, TM3a are arranged. Then, the input bump electrode IBMP2 is coupled to an opening CNT2a and an opening CNT2b, and via a conductive material filled in the opening CNT2a, the input bump electrode IBMP2 is also electrically coupled to the uppermost layer wiring TM1b and at the same time, via a conductive material filled in the opening CNT2b, the input bump electrode IBMP2 is electrically coupled to the uppermost layer wiring TM3a. That is, the input bump electrode IBMP2 is coupled to the two different uppermost layer wirings TM1b, TM3a and the third device point is used in the configuration of the input bump electrode IBMP2.
Subsequently, in the lower layer of the input bump electrode IBMP3, the uppermost layer wirings TM1b, TM2a are arranged and the input bump electrode IBMP3 is electrically coupled to the uppermost layer wiring TM2a via a conductive material filled in the opening CNT3. Here, the input bump electrode IBMP1 and the input bump electrode IBMP3 are focused on. Then, the position of the opening CNT1 coupled to the input bump electrode IBMP1 is different from the position of the opening CNT3 coupled to the input bump electrode IBMP3 and the uppermost layer wiring TM1a to be coupled to the input bump electrode IBMP1 and the uppermost layer wiring TM2a to be coupled to the input bump electrode IBMP3 are different. That is, in the configuration of the input bump electrode IBMP1 and the input bump electrode IBMP3, the second device point in the present third embodiment is used.
Next, in the lower layer of the input bump electrode IBMP4, the uppermost layer wirings TM1b, TM2b, TM2a are arranged and the input bump electrode IBMP4 is coupled to the uppermost layer wiring TM2b via a conductive material filled in an opening CNT4a and coupled to the uppermost layer wiring TM2a via a conductive material filled in an opening CNT4b. Therefore, in the configuration of the input bump electrode IBMP4 also, the third device point in the present third embodiment is used. Further, the input bump electrode IBMP3 and the input bump electrode IBMP4 are focused on. Then, the input bump electrode IBMP3 and the input bump electrode IBMP4 are coupled to the same uppermost layer wiring TM2a and the position where the opening CNT3 for the input bump electrode IBMP3 is formed is different from the position where the opening CNT4b for the input bump electrode IBMP4 is formed. Therefore, the first device point in the present third embodiment is used in this configuration as a result.
Subsequently, in the lower layer of the input bump electrode IBMP5, the uppermost layer wirings TM1b, TM2b, TM3b are arranged and the input bump electrode IBMP5 is electrically coupled to the uppermost layer wiring TM3b via a conductive material filled in an opening CNT5. The wiring layout example shown in
The technique disclosed in the present third embodiment is also effective when forming the input protection circuits 3a to 3c in a region that overlaps the input bump electrodes IBMP in a planar view as with the prior art. Then, it is obviously possible to obtain the same effects also when using the first embodiment and the second embodiment described above in combination.
In a fourth embodiment, an example will be described, in which the form of the input bump electrode and the form of the output bump electrode are not the same but made to differ in size from each other.
The technical idea described in the above-mentioned third embodiment relates to the coupling configuration between the input bump electrode and the uppermost layer wiring and the effective use of the first device point to the third device point described in the above-mentioned third embodiment is based on the assumption that the uppermost layer wirings are arranged in the lower layer of the input bump electrode. Taking into consideration the assumption, in the present fourth embodiment, attention is focused on the point that the first device point to the third device point in the above-mentioned third embodiment become a more useful technique as the number of uppermost layer wirings to be arranged in the lower layer of the input bump electrode increases. Because of this, in the present fourth embodiment, the configuration of the input bump electrode is devised in order to make use of the first device point to the third device point in the above-mentioned third embodiment more effectively. A technical idea in the present fourth embodiment will be described below.
The characteristic in the present fourth embodiment lies in that the size of the input bump electrode IBMP is not the same as that of the output bump electrode OBMP but greater than that of the output bump electrode OBMP. More specifically, when the length in the short-side direction of the input bump electrode IBMP is assumed to be a and the length in the short-side direction of the output bump electrode OBMP b, the length a of the input bump electrode IBMP is greater than the length b of the output bump electrode OBMP. The reason for thus increasing the size of the input bump electrode IBMP is as follows.
That is, making greater the length in the short-side direction of the input bump electrode IBMP means that the number of uppermost layer wirings to be arranged in the lower layer that overlaps the input bump electrode IBMP in a planar view can be increased. That is, by making greater the length in the short-side direction of the input bump electrode IBMP, the number of uppermost layer wirings that pass through the lower layer of the input bump electrode IBMP and extend in the direction of the long side LS1 is increased. This means that the number of uppermost layer wirings that pass through the lower layer of the input bump electrodes IBMP arranged along the long side LS1 is increased and as a result of that, the degree of freedom in coupling the input bump electrodes IBMP by uppermost layer wirings is increased. Further, that the number of uppermost layer wirings that pass through the lower layer of the input bump electrodes IBMP increases means that the potential to effectively make use of the first device point to the third device point described in the above-mentioned third embodiment increases. Because of this, according to the present fourth embodiment, by employing the characteristic configuration in which the length a of the input bump electrode IBMP is made greater than the length b of the output bump electrode OBMP, a remarkable effect is exhibited that the degree of freedom in wiring layout is increased.
As described above, the present fourth embodiment employs the characteristic configuration in which the length a of the input bump electrode IBMP is made greater than the length b of the output bump electrode OBMP from the standpoint that the first device point to the third device point in the above-mentioned third embodiment are made use of effectively by increasing the degree of freedom in wiring layout. That is, the plane area of the input bump electrode IBMP is made greater than that of the output bump electrode OBMP. By employing the characteristic configuration in the present fourth embodiment, secondary effects as shown below are also exhibited. The secondary effects will be described.
For example, a case is considered, where the size of the input bump electrode IBMP and the size of the output bump electrode OBMP are the same. In this case, the number of the input bump electrodes IBMP is smaller than that of the output bump electrodes OBMP, and therefore, the total area of the input bump electrodes IBMP is smaller than that of the output bump electrodes OBMP.
The input bump electrode IBMP and the output bump electrode OBMP formed in the semiconductor chip CHP2 function as a coupling terminal when mounting the semiconductor chip CHP2, which is an LCD driver, over the glass substrate of a liquid crystal display device. At this time, that the total area of the input bump electrode IBMP is smaller than that of the output bump electrode OBMP means that the joint area on the side of the input bump electrode IBMP is smaller than that on the side of the output bump electrode OBMP. Because of this, the joint area along the long side LS1 of the semiconductor chip CHP2 (total area of the input bump electrode IBMP) and that along the long side LS2 of the semiconductor chip CHP2 (total area of the output bump electrode OBMP) are different. As a result of that, when mounting the semiconductor chip CHP2 over the glass substrate, the balance between the joint strength at the long side LS1 of the semiconductor chip CHP2 and that at the long side LS2 of the semiconductor chip CHP2 is lost and there arises a possibility that the joint strength between the semiconductor chip CHP2 and the glass substrate is reduced.
In contrast to this, a case is considered, where the characteristic configuration in which the length a of the input bump electrode IBMP is made greater than the length b of the output bump electrode OBMP is employed as in the present fourth embodiment. In this case, the number of the input bump electrodes IBMP is smaller than that of the output bump electrodes OBMP, however, the size of one input bump electrode IBMP is greater than that of one output bump electrode OBMP. Consequently, the difference between the total area of the input bump electrodes IBMP and that of the output bump electrodes OBMP becomes smaller compared to the case where the size of the input bump electrode IBMP and that of the output bump electrode OBMP are the same in dimensions. That is, according to the characteristic configuration in the present fourth embodiment, it is possible to make smaller the difference between the joint area on the side of the input bump electrode IBMP and that on the side of the output bump electrode OBMP. As a result of that, the imbalance between the joint strength at the long side LS1 of the semiconductor chip CHP2 and that at the long side LS2 of the semiconductor chip CHP2 is relaxed when mounting the semiconductor chip CHP2 over the glass substrate, and therefore, the joint strength between the semiconductor chip CHP2 and the glass substrate is increased.
In the present fourth embodiment, the length in the Y direction (short-side direction of the semiconductor chip CHP2) is illustrated, however as to the length in the X direction (long-side direction of the semiconductor chip CHP2), it is desirable to make the same the length of the input bump electrode IBMP and that of the output bump electrode OBMP, or to make greater the length of the input bump electrode IBMP than that of the output bump electrode OBMP.
As described above, according to the characteristic configuration in the present fourth embodiment, it is possible to obtain the effect that the joint strength between the semiconductor chip CHP2 and the glass substrate is increased as well as the effect that the degree of freedom in wiring layout is increased.
The technique disclosed in the present fourth embodiment is not limited to the case in the third embodiment described above and can also be applied to the first and second embodiments described above.
In a fifth embodiment, a device structure formed in the lower layer of the input bump electrode will be described.
In a semiconductor substrate 1S, an element isolation region STI that separates elements is formed and in a region (within the semiconductor substrate 1S) in which the n-channel type MISFET Q1 is formed among active regions divided by the element isolation region STI, a p-type well PWL is formed and in a region (within the semiconductor substrate 1S) in which the p-channel type MISFET Q2 is formed, an n-type well NWL is formed.
The n-channel type MISFET Q1 has a gate insulating film GOX over the p-type well PWL formed within the semiconductor substrate 1S, and over the gate insulating film GOX, a gate electrode G1 is formed. The gate insulating film GOX is formed from, for example, a silicon oxide film and the gate electrode G1 is formed from, for example, a laminated film of a polysilicon film PF and a cobalt silicide film CS, in order to reduce resistance.
However, the gate insulating film GOX is not limited to the silicon oxide film, but can be modified in various ways, and the gate insulating film GOX may be formed from, for example, a silicon oxynitride film (SiON). That is, it may have a structure in which nitrogen is segregated at the interface between the gate insulating film GOX and the semiconductor substrate 1S. The silicon oxynitride film has a significant effect for suppressing the occurrence of interface state in the film and reducing electron trap compared to the silicon oxide film. As a result, it is possible to improve the hot-carrier resistance of the gate insulating film GOX and the insulation resistance. In addition, it is difficult for impurities to penetrate through the silicon oxynitride film, compared to the silicon oxide film. Because of this, by using a silicon oxynitride film as the gate insulating film GOX, it is possible to suppress the variations in the threshold voltage resulting from the diffusion of impurities in the gate electrode to the side of the semiconductor substrate 1S. In order to form a silicon oxynitride film, for example, it is only required to perform heat treatment on the semiconductor substrate 1S in an atmosphere containing nitrogen, such as NO, NO2, and NH3. It is also possible to obtain the same effect by performing heat treatment on the semiconductor substrate 1S in an atmosphere containing nitrogen after forming the gate insulating film GOX including a silicon oxide film on the surface of the semiconductor substrate 1S, and segregating nitrogen to the interface between the gate insulating film GOX and the semiconductor substrate 1S.
Further, it may also be possible to form the gate insulating film GOX from, for example, a high-k dielectric film having the dielectric constant higher than that of the silicon oxide film. Conventionally, from the standpoint that the insulation resistance is high, the electrical/physical stability at the interface between silicon and silicon oxide is excellent, etc., a silicon oxide film is used as the gate insulating film GOX. However, it has been demanded for the gate insulating film GOX to be extremely thin accompanying the miniaturization of element. If such a thin silicon oxide film is used as the gate insulating film GOX, a so-called tunneling current is generated by electrons that flow through the channel of MISFET, tunneling the barrier wall formed by the silicon oxide film and flowing to the gate electrode.
Because of this, a material having a dielectric constant higher than that of the silicon oxide film is used and a high-k dielectric film begins to be used recently, which has the same capacitance but is capable of increasing the physical film thickness. With a high-k dielectric film, it is possible to increase the physical film thickness with the same capacitance, and therefore, the leak current can be reduced. In particular, although the silicon nitride film has a dielectric constant higher than that of the silicon oxide film, it is desirable to use a high-k dielectric film having a dielectric constant higher than that of the silicon nitride film in the present fifth embodiment.
For example, as a high-k dielectric film having a dielectric constant higher than that of the silicon nitride film, a hafnium oxide film (HfO2 film) is used, which is one of hafnium oxides, however, instead of the hafnium oxide film, other hafnium-based insulating films, such as a HfAlO film (hafnium aluminate film), a HfON film (hafnium oxynitride film), a HfSiO film (hafnium silicate film), and a HfSiON film (hafnium silicon oxynitride film) can be used. Further, hafnium-based insulating films that have introduced oxides therein, such as tantalum oxide, niobium oxide, titanium oxide, zirconium oxide, lanthanum oxide, and yttrium oxide, can also be used. Because the hafnium-based insulating film has a dielectric constant higher than that of the silicon oxide film and the silicon oxynitride film, like the hafnium oxide film, the same effect when the hafnium oxide film is used can be obtained.
On the side wall on both sides of the gate electrode G1, a sidewall SW is formed and within the semiconductor substrate 1S under the sidewall SW, a shallow n-type impurity diffusion region EX1 is formed as a semiconductor region. The sidewall SW is formed by, for example, an insulating film, such as a silicon oxide film. Then, outside the shallow n-type impurity diffusion region EX1, a deep n-type impurity diffusion region NR is formed and on the surface of the deep n-type impurity diffusion region NR, the cobalt silicide film CS is formed.
The sidewall SW is formed so that the source region and the drain region, which are the semiconductor region of the n-channel type MISFET Q1, have an LDD structure. That is, the source region and the drain region of the n-channel type MISFET Q1 are formed by the shallow n-type impurity diffusion region EX1 and the deep n-type impurity diffusion region NR. At this time, the impurity concentration of the shallow n-type impurity diffusion region EX1 is lower than that of the deep n-type impurity diffusion region NR. Because of this, by forming the source region and the drain region under the sidewall SW as the shallow n-type impurity diffusion region EX1, it is possible to suppress electric field under the end part of the gate electrode G1 from concentrating.
Next, the p-channel type MISFET Q2 has the gate insulating film GOX over the n-type well NWL formed within the semiconductor substrate 1S and over the gate insulating film GOX, a gate electrode G2 is formed. The gate insulating film GOX is formed by, for example, a silicon oxide film, and the gate electrode G2 is formed by, for example, a laminated film of the polysilicon film PF and the cobalt silicide film CS to reduce resistance. At this time, in the p-channel type MISFET Q2 also, the gate insulating film GOX is not limited to a silicon oxide film but it may also be possible to use a silicon oxynitride film or a high-k dielectric film having a dielectric constant higher than that of a silicon oxide film, like the n-channel type MISFET Q1.
On the side wall on both sides of the gate electrode G2, the sidewall SW is formed and within the semiconductor substrate 1S under the sidewall SW, a shallow p-type impurity diffusion region EX2 is formed as a semiconductor region. The sidewall SW is formed by, for example, an insulating film, such as a silicon oxide film. Then, outside the shallow p-type impurity diffusion region EX2, a deep p-type impurity diffusion region PR is formed and on the surface of the deep p-type impurity diffusion region PR, the cobalt silicide film CS is formed.
The sidewall SW is formed so that the source region and the drain region, which are the semiconductor region of the p-channel type MISFET Q2, have an LDD structure. That is, the source region and the drain region of the p-channel type MISFET Q2 are formed by the shallow p-type impurity diffusion region EX2 and the deep p-type impurity diffusion region PR. At this time, the impurity concentration of the shallow p-type impurity diffusion region EX2 is lower than that of the deep p-type impurity diffusion region PR. Because of this, by forming the source region and the drain region under the sidewall SW as the shallow p-type impurity diffusion region EX2 of low concentration, it is possible to suppress the electric field under the end part of the gate electrode G2 from concentrating.
As described above, over the semiconductor substrate 1S, the n-channel type MISFET Q1 and the p-channel type MISFET Q2 are formed. For example, a contact interlayer insulating film CIL including a silicon oxide film is formed so as to cover the n-channel type MISFET Q1 and the p-channel type MISFET Q2 and a contact hole is formed so as to penetrate through the contact interlayer insulating film CIL. The contact hole is formed so as to reach the source region and the drain region of the n-channel type MISFET Q1 and the source region and the drain region of the p-channel type MISFET Q2 and a plug PLG1 is formed within the contact hole. The plug PLG1 is formed by filling the contact hole with a barrier conductive film including, for example, a titanium/titanium nitride film (a titanium film and a titanium nitride film formed over the titanium film) and a tungsten film.
Specifically, the contact interlayer insulating film CIL is formed by a laminated film of an ozone TEOS film formed by the thermal CVD method using ozone and TEOS as a raw material and a plasma TEOS film formed by the plasma CVD method using TEOS as a raw material. It may also be possible to form, for example, an etching stopper film including a silicon nitride film in the lower layer of the ozone TEOS film.
The contact interlayer insulating film CIL is formed by a TEOS film because the TEOS film is a film excellent in the coverage for the backing step. The backing that forms the contact interlayer insulating film CIL is the semiconductor substrate over which MISFET is formed and which has bumps and dips. That is, because MISFET is formed over the semiconductor substrate 1S, on the surface of the semiconductor substrate 1S, a gate electrode is formed, and therefore, the backing has bumps and dips. Consequently, unless a film is excellent in coverage for a step with bumps and dips, it is not possible to flatten the fine bumps and dips, resulting in the occurrence of voids etc. Because of this, a TEOS film is used as the contact interlayer insulating film CIL. This is because, in a TEOS film that uses TEOS as a raw material, before TEOS, which is a raw material, becomes a silicon oxide film, it forms an intermediate, facilitating movement on the surface of a film being formed, and therefore, the coverage properties for the backing step are improved.
The titanium/titanium nitride film constituting a barrier conductive film is a film provided to prevent tungsten constituting the tungsten film from diffusing into silicon and also to prevent fluorine from attacking the contact interlayer insulating film CIL and the semiconductor substrate 1S to inflict damage on them in the CVD method in which WF6 (tungsten fluoride) is subjected to reduction processing when the tungsten film is formed.
Next, over the contact interlayer insulating film CIL in which the plug PLG1 is formed, a multilayer wiring is formed. The structure of the multilayer wiring will be described below. As shown in
Subsequently, over the plug PLG2 formed in the interlayer insulating film IL1, a second layer wiring L2 is formed. The second layer wiring L2 is formed by, for example, a laminated film including a titanium nitride film, an aluminum film, and a titanium nitride film. Then, over the interlayer insulating film IL1 over which the second layer wiring L2 is formed, an interlayer insulating film IL2 that covers the second layer wiring L2 is formed. The interlayer insulating film IL2 is formed by, for example, a silicon oxide film. In the interlayer insulating film IL2, a plug PLG3 that reaches the second layer wiring L2 is formed. This plug PLG3 is also formed by embedding a barrier conductive film including a titanium/titanium nitride film and a tungsten film.
Next, over the plug PLG3 formed in the interlayer insulating film IL2, a third layer wiring L3 is formed. The third layer wiring L3 is formed by, for example, a laminated film including a titanium nitride film, an aluminum film, and a titanium nitride film. Then, over the interlayer insulating film IL2 over which the third layer wiring L3 is formed, an interlayer insulating film IL3 that covers the third layer wiring L3 is formed. The interlayer insulating film IL3 is formed by, for example, a silicon oxide film. In the interlayer insulating film IL3, a plug PLG4 that reaches the third layer wiring L3 is formed. This plug PLG4 is also formed by embedding a barrier conductive film including a titanium/titanium nitride film and a tungsten film.
Subsequently, over the plug PLG4 formed in the interlayer insulating film IL3, a fourth layer wiring L4 is formed. The fourth layer wiring L4 is formed by, for example, a laminated film including a titanium nitride film, an aluminum film, and a titanium nitride film. Then, over the interlayer insulating film IL3 over which the fourth layer wiring L4 is formed, an interlayer insulating film IL4 that covers the fourth layer wiring L4 is formed. The interlayer insulating film IL4 is formed by, for example, a silicon oxide film. In the interlayer insulating film IL4, a plug PLG5 that reaches the fourth layer wiring L4 is formed. This plug PLG5 is also formed by embedding a barrier conductive film including a titanium/titanium nitride film and a tungsten film.
The multilayer wiring is formed as described above. In the present fifth embodiment, the multilayer wiring is formed by an aluminum film, however, it may also be possible to form the multilayer wiring by a copper film. That is, the first layer wiring L1 to the fourth layer wiring L4 may be formed by a conductive film containing copper as its main component, such as a damascene wiring. That is, after a groove is formed in each of the interlayer insulating film IL1 to the interlayer insulating film IL4, a conductive film containing copper as its main component is formed inside and outside the groove. Then, it is also possible to obtain a structure in which a conductive film is embedded within the groove by polishing the conductive film outside the groove by the chemical mechanical polishing (CMP) method etc. Specifically, the multilayer wiring may be formed from copper (Cu) or copper alloy (alloy of copper (Cu) and aluminum (Al), magnesium (Mg), titanium (Ti), manganese (Mn), iron (Fe), zinc (Zn), zirconium (Zr), niobium (Nb), molybdenum (Mo), ruthenium (Ru), palladium (Pd), silver (Ag), gold (Au), indium (In), lanthanoid-based metal, actinoid-based metal, etc.).
Further, the interlayer insulating films IL1 to IL4 may be formed by a low dielectric constant film having a dielectric constant lower than that of a SiOF film. Specifically, the interlayer insulating films IL1 to IL4 may be formed by either of a SiOC film having vacancies, a MSQ film having vacancies (methylsilsesquioxane, a silicon oxide film formed by an application step and having a Si—C bond, or a silsesquioxane containing carbon), a HSQ film having vacancies (hydrogen silsesquioxane, a silicon oxide film formed by an application step and having a Si—H bond, or silsesquioxane containing hydrogen). The size (diameter) of a vacancy is, for example, about 1 nm.
Next, over the plug PLG5 formed in the interlayer insulating film IL4, the uppermost layer wirings TM1, TM2, TM3 are formed. The uppermost layer wirings TM1, TM2, TM3 are formed by, for example, a laminated film including a titanium nitride film, an aluminum film, and a titanium nitride film. Then, over the interlayer insulating film IL4 over which the uppermost layer wirings TM1, TM2, TM3 are formed, an interlayer insulating film (surface protection film) IL5 is formed so as to cover the uppermost layer wirings TM1, TM2, TM3. The interlayer insulating film IL5 is formed by, for example, a laminated film including a silicon oxide film and a silicon nitride film formed over the silicon oxide film.
Further, in the interlayer insulating film IL5, the opening CNT1 that reaches the uppermost layer wiring TM1 is formed and a conductive material is filled in the opening CNT1. The input bump electrode IBMP1 is formed over the interlayer insulating film IL5 in which the opening CNT1 is formed. The input bump electrode IBMP1 is formed by an under bump metal (UBM) film, which is a backing film, and a gold film formed over the UBM film. The UBM film may be formed by using, for example, the sputtering method and formed by, for example, a single layer film, such as a titanium film, a nickel film, a palladium film, a titanium/tungsten alloy film, a titanium nitride film, and a gold film, or a laminated film thereof. Here, the UBM film is a film having a barrier function to suppress or prevent metal elements of the gold film from moving to the side of the multilayer wiring or conversely, the metal elements of the multilayer wiring from moving to the side of the gold film, in addition to a function to improve adhesion between the input bump electrode IBMP1 and the surface protection film (interlayer insulating film IL5).
The semiconductor device in the present fifth embodiment is formed as described above. At this time, the three uppermost layer wirings TM1, TM2, TM3 are formed in the lower layer that overlaps the input bump electrode IBMP1 in a planar view as a result.
Subsequently, for example, a structure in which two openings are coupled to one input bump electrode IBMP will be described.
In a sixth embodiment, a step of mounting the semiconductor chip CHP2 constituting an LCD driver over a mounting substrate (glass substrate) will be described. First, by using the normal semiconductor manufacturing technique, a semiconductor element, such as MISFET, is formed over the semiconductor substrate and then, a multilayer wiring is formed over the semiconductor substrate over which the semiconductor element is formed. Then, after forming an uppermost layer wiring formed in the uppermost layer of the multilayer wiring, a surface protection film that covers the uppermost layer wiring is formed. Then, an opening that reaches the uppermost layer wiring is formed in the surface protection film and the opening is filled and at the same time, a bump electrode (input bump electrode and output bump electrode) is formed over the surface protection film. Then, by dicing the semiconductor substrate, it is possible to obtain the individual semiconductor chips CHP2 as shown in
Next, a step of mounting the semiconductor chip CHP2 formed as described above over a mounting substrate (glass substrate) by adhesion will be described.
In this step, the semiconductor chip CHP2 and the electrodes 10a formed over the glass substrate 10 are aligned using a camera C. By this alignment, the accurate position of the semiconductor chip CHP2 is grasped by the camera C recognizing an alignment mark formed in the semiconductor chip CHP2.
Subsequently, as shown in
Subsequently, as shown in
In a seventh embodiment, a plane layout of output bump electrodes, uppermost layer wirings, and an output protection circuit will be described.
As shown in
Here, the opening CNT7 of the output bump electrode OBMP2 is provided at a position close to the internal circuit rather than to the side of the long side LS2. Due to this, an uppermost layer wiring TM7 (power supply wiring) (reference potential Vss) and an uppermost layer wiring TM8 (power supply wiring) (external power supply potential Vcc) can be routed around the outer circumference of the semiconductor chip CHP2. That is, it is possible to effectively use the region at the top part of the output protection circuit 4 and at the lower part of the output bump electrode OBMP2. As described above, in the semiconductor chip CHP2 in the present seventh embodiment, the output bump electrode OBMP1 and the output bump electrode OBMP2 are also devised to reduce the chip size.
That is, the characteristic in the present seventh embodiment is that the output bump electrodes OBMP2 arranged at the position close to the long side LS2 and the output bump electrodes OBMP1 arranged at the position farther from the long side LS2 than the output bump electrodes OBMP2 are provided as the output bump electrodes arranged in a staggered manner. Then, under the output bump electrode OBMP1, the uppermost layer wiring TM5 is formed and under the output bump electrode OBMP2, the uppermost layer wiring TM6 is formed. At this time, the output bump electrode OBMP1 is coupled to the uppermost layer wiring TM5 via the opening CNT6 formed in the insulating film and the output bump electrode OBMP2 is coupled to the uppermost layer wiring TM6 via the opening CNT7 formed in the insulating film. It is characteristic that the position at which the opening CNT6 is formed is a position closer to the long side LS2 than the center of the output bump electrode OBMP1 and the position at which the opening CNT7 is formed is a position farther from the long side LS2 than the center of the output bump electrode OBMP2.
Unlike the input bump electrodes IBMP shown in the third embodiment described above, all of the positions of the openings CNT7 of the output bump electrodes OBMP2 are the same and all of the positions of the openings CNT6 of the output bump electrodes OBMP1 are the same. That is, the input bump electrodes IBMP are formed linearly and the positions of some openings (for example, the openings CNT1 to CNT3 in
With the technique disclosed in the present seventh embodiment as described above, it is possible to reduce the size in the short-side direction of the semiconductor chip CHP2.
The technique disclosed in the present seventh embodiment can also be applied to the other embodiments described above.
In an eighth embodiment, a case is illustrated, where a dummy region where no semiconductor element is formed is arranged in a region that overlaps the input bump electrodes IBMP1, IBMP2 in a planar view.
For example, in the fifth embodiment described above, the example is shown, where the internal circuit IU is arranged in the region that overlaps the input bump electrodes IBMP1, IBMP2 in a planar view, however, this is not limited, the region that overlaps the input bump electrodes IBMP1, IBMP2 in a planar view may be a dummy region where no semiconductor element is formed. The dummy region is a region of a semiconductor substrate defined by the element isolation region STI, which does not contribute to the circuit operation of the semiconductor device.
In
As described above, in the present eighth embodiment also, as in the fifth embodiment described above, it is possible to cause a plurality of wiring layers to pass through the lower layer of the input bump electrodes IBMP1, IBMP2, and therefore, it is possible to increase the degree of freedom in wiring layout.
Further, the dummy pattern DP is provided in a region that overlaps the input bump electrodes IBMP1, IBMP2 in a planar view, and therefore, the flatness of each wiring layer can be improved.
The technique disclosed in the present eighth embodiment can also be applied to the other embodiments described above.
The invention made by the inventors of the present invention is described based on the embodiments as described above, however, the present invention is not limited to the embodiments and it is obvious that there can also be various modifications within the scope not departing from its gist.
In the present embodiments, the drive device (LDC driver) for liquid crystal display is illustrated, however, this is not limited and the present invention can also be applied to other drive devices for display, such as an organic EL. Further, the present invention is not limited to a drive device but can be applied to other semiconductor devices. In particular, it is preferable to apply the present invention to a case where a semiconductor chip is in the form of a rectangle.
The present invention can be used widely in the manufacturing industry that manufactures semiconductor devices.
Number | Date | Country | Kind |
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2009-173356 | Jul 2009 | JP | national |
This is a continuation of U.S. patent application Ser. No. 14/028,755, filed Sep. 17, 2013, abandoned, which is a Divisional of U.S. patent application Ser. No. 12/793,431, filed Jun. 3, 2010, now U.S. Pat. No. 8,564,127, which claims priority to Japanese Patent Application No. 2009-173356 filed on Jul. 24, 2009. The contents of the aforementioned applications are incorporated by reference in their entirety.
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Official Action dated Oct. 15, 2013 issued in Japanese counterpart application (No. JP 2009-173356) with English translation. |
Official Action dated May 14, 2014 issued in Chinese counterpart application (No. 201010227707.8) with English translation. |
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Number | Date | Country | |
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20150255452 A1 | Sep 2015 | US |
Number | Date | Country | |
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Parent | 12793431 | Jun 2010 | US |
Child | 14028755 | US |
Number | Date | Country | |
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Parent | 14028755 | Sep 2013 | US |
Child | 14712689 | US |