Patent Application
20060255385
The present application claims priority from French Application for Patent No. 05 03571 filed Apr. 11, 2005, the disclosure of which is hereby incorporated by reference.
1. Technical Field of the Invention
The present invention relates to integrated circuits, and notably integrated memory devices of the “one-time-programmable” type, also known by those skilled in the art as OTP memory.
2. Description of Related Art
The OTP memory is well known to those skilled in the art. It comprises fusible elements, such as capacitors, that are made to break down electrically, in other words the dielectric of the capacitor is damaged in an irreversible manner, such that the latter then behaves like a resistor of low value. Such memories conventionally comprise access transistors of the field-effect type, and the fabrication of such memories requires special precautions so as not to damage the access transistors during the irreversible programming of the memory cells of the memory.
There is a need in the art to provide a solution to the problem of access transistor damage and embodiments of the present invention propose a totally different architecture of irreversibly electrically programmable or one-time-programmable memories, which does not involve the use of field-effect transistors in the memory matrix or memory array.
There is also a need in the art to provide a memory cell or dot with a very high area density, for example of the order of 0.25 μm2 per bit, in a 65 nm CMOS technology, as compared with 100 μm2 per bit currently.
There is still further a need in the art to provide a memory architecture that offers a low programming voltage and high read speed.
According to a first aspect of the invention, an integrated circuit is thus provided comprising a memory device of the irreversibly electrically programmable type and comprising at least one memory cell.
According to a general characteristic of this aspect of the invention, the memory device is formed within and on a first part of a semiconductor substrate and the memory cell comprises a bipolar transistor buried in the first part of the substrate, together with a dielectric region formed from a dielectric material capable of being subject to irreversible breakdown in the presence of a breakdown voltage difference that is applied to it. This dielectric region is disposed on top of the substrate and has a first surface, for example its lower surface, in electrical contact with a first electrode of the transistor, and a second surface opposite to the first, for example its upper surface. The memory device furthermore comprises programming means capable of applying the breakdown voltage difference between the second surface of the dielectric region and the control electrode of the transistor so as to make the p-n junction of the transistor, formed between the first electrode and the control electrode, conduct.
According to one embodiment of the invention, the dielectric region is situated on top of an insulating layer covering the first part of the substrate and the memory cell comprises a metal interconnect (commonly called “contact” by those skilled in the art) passing through the insulating layer between the first surface of the dielectric region and the first electrode of the bipolar transistor.
The integrated circuit also advantageously comprises at least one active component, for example a CMOS component, and for example, more generally, a CMOS core formed within and on a second part of the same substrate, this second part also being covered by the insulating layer.
In other words, the invention is noteworthy in the sense that it allows the fabrication of OTP memories, referred to as “embedded” memories according to a terminology usually employed by those skilled in the art, in other words memories that are for example fabricated in conjunction with other components by the same technological process, and that are to be integrated together within the same substrate of, for example, an application specific integrated circuit (ASIC).
According to one embodiment of the invention, the bipolar transistor of the memory cell is formed from a multilayer of three semiconductor regions situated within the first part of the substrate, in other words that part within which the OTP memory is fabricated. The metal interconnect (contact) passes through the insulating layer between the first surface of the dielectric region and the upper semiconductor region of the multilayer. The cell programming means comprise a first electrically conducting connection means in contact with the middle semiconductor region of the multilayer and a second electrically conducting means in contact with the second surface, for example the upper surface, of the dielectric region.
According to one variant of the invention in which the memory device comprises a matrix of memory cells, a continuous dielectric layer, formed from the dielectric material capable of being subject to electrical breakdown, is provided. This continuous dielectric layer extends over the bipolar transistors of all the cells and incorporates the dielectric regions of the cells.
More precisely and according to one embodiment of this variant, the continuous dielectric layer, formed from the dielectric material capable of being subject to electrical breakdown, extends over a first part of the insulating layer that covers the first part of the substrate. The lower surface of this continuous dielectric layer is locally in contact with the respective metal interconnects of the memory cells. The dielectric region associated with a memory cell is then formed from the region of this dielectric layer situated locally in contact with the corresponding metal interconnect.
The continuous dielectric layer can be planar and can lie on the first part of the insulating layer.
According to another variant of the invention, in which the memory device comprises a matrix of memory cells, a discontinuous dielectric layer, formed from the dielectric material capable of being subject to electrical breakdown, is provided. The various portions of the discontinuous dielectric layer respectively extend over the bipolar transistors of the various cells and respectively incorporate the dielectric regions of the cells.
More precisely, and according to one embodiment of this variant, each memory cell comprises a capacitor extending over a first part of the insulating layer covering the first part of the substrate. This capacitor has a lower electrode in contact with the metal interconnect of the memory cell, an upper electrode and the corresponding portion of the discontinuous layer situated between the two electrodes. The dielectric region associated with the memory cell is then formed from the region of the portion of dielectric layer situated on top of the metal interconnect.
According to one embodiment of the invention, compatible with one or the other of the variants that have just been presented, the matrix of memory cells comprises first groups of cells all running in a first direction, for example parallel to the rows of the matrix, and second groups of cells all running in a second direction, for example parallel to the columns of the matrix. The memory device then comprises:
parallel semiconductor wells all running in the first direction and respectively associated with the first groups of cells, each well containing the control electrodes of the bipolar transistors of all the memory cells of the corresponding first group of cells
first metallizations in respective electrical contact with the wells, and
second metallizations all running in the second direction and respectively associated with the second groups of cells, each second metallization being in electrical contact with the second surfaces of the dielectric regions of the cells of the corresponding second group.
The cell programming means comprise the corresponding first metallization, the corresponding well and the corresponding second metallization.
According to one embodiment, compatible notably with the variant of the invention using a continuous dielectric layer, the first electrically conducting connection means of the cells of each first group comprise the corresponding first metallization and the corresponding well, while the second electrically conducting connection means of the cells of each second group comprise the corresponding second metallization.
According to one embodiment of the invention, in particular compatible with the variant using the discontinuous dielectric layer, the first electrically conducting connection means of the cells of each first group comprise the corresponding first metallization and the corresponding well, while the second electrically conducting connection means of the cells of each second group comprise the corresponding second metallization and the upper electrode of the corresponding capacitor.
The second metallizations advantageously form part of a metallization level of the integrated circuit, for example the first metallization level.
It will therefore be noted here that the invention is noteworthy, in particular, in the sense that it can be easily integrated into a conventional design of an integrated circuit.
By way of example, the first metallizations and the associated wells can form word lines of the matrix of memory cells, while the second metallizations can form bit lines.
Those skilled in the art will know how to adjust the breakdown voltage difference as a function of the technology used. By way of example, this breakdown voltage difference is greater than 3 volts, for example greater than or equal to 3.3 volts.
According to another aspect of the invention, a programming method is provided for a memory device such as was previously defined. According to this method, the breakdown voltage difference is applied between the second surface of the dielectric region and the control electrode of the transistor of the memory cell to be programmed so as to make the p-n junction of the transistor, formed between the first electrode and the control electrode, conduct.
By way of example, a breakdown voltage can be applied to the second surface of the dielectric region and ground potential to the control electrode of the transistor. Alternatively, the breakdown voltage could be applied to the control electrode of the transistor of the memory cell to be programmed and ground potential to the second surface of the dielectric region.
During the programming of a memory cell of the matrix, a de-programming voltage difference is applied for example between the second surface of the dielectric region and the control electrode of the transistor of each other memory cell, in other words of a memory cell that must not be programmed, which voltage difference is chosen so as to turn off the conduction of the upper p n junction of the bipolar transistor of this other memory cell.
The de-programming voltage difference is for example equal to zero volts or to the inverse of the breakdown voltage difference.
A more complete understanding of the method and apparatus of the present invention may be acquired by reference to the following Detailed Description when taken in conjunction with the accompanying Drawings wherein:
In
The rows WL0 and WL1 form word lines of the memory, whereas the columns BL0 and BL1 form bit lines of the memory.
Row and column decoders of conventional structure, which are known per se, are of course associated with this memory array.
Each cell CELij of the memory array comprises a fusible element ZD which is, as will be seen below, composed of a dielectric region and a bipolar transistor TR.
In the example described here, the bipolar transistor TR of each memory cell is a pnp transistor controlled on its control electrode (base) by the corresponding word line.
Furthermore, the fusible element ZD is connected between the corresponding bit line and the emitter of the transistor TR, whereas the collector of the transistor TR is, in this example, biased at ground potential.
An exemplary embodiment of such a device is illustrated in
Each memory cell, for example the cell CEL10, comprises a bipolar transistor TR10 formed in a first part of a substrate SB, here of the p-conductivity type.
The bipolar transistor TR10 is consequently formed, in this example, from a multilayer of three semiconductor regions, namely an upper semiconductor region, a middle semiconductor region and a lower semiconductor region. The upper semiconductor region ZS10, of the p-conductivity type, in this example is overdoped (P+) with respect to the lower semiconductor region ZI10 of the multilayer, which is a part of the substrate SB. The middle semiconductor region ZM10 is of the n-conductivity type.
The transistor TR10 is here therefore a pnp bipolar transistor formed from an upper p-n junction between the upper region ZS and the middle region ZM and from a lower n-p junction between the middle region ZM and the lower region ZI.
The respective upper regions ZS of the various memory cells are isolated from one another by insulating regions STI which are here, by way of example, insulating regions of the “shallow trench” type.
The biasing of the substrate SB is provided by a metal contact (not shown here for reasons of simplification) coming into contact with an overdoped region P+ referenced ZP.
In fact, as can be seen in
Thus, as illustrated in
These wells are biased by the contacts (of n+ type not shown in the figures) and the metallizations WLi.
Furthermore, as can also be seen in
The part of the substrate SB in which the memory array OTP is fabricated is covered by an insulating layer CIS, for example a layer of silicon dioxide.
Metal interconnects, or contacts, Wij are fabricated in a conventional manner known per se through this insulating region CIS. They are for example formed from tungsten.
These metal interconnects Wij allow electrical connections to be formed between the respective upper semiconductor regions ZSij of the multilayers of the bipolar transistors of the memory cells and the lower surface SI of a continuous and plane dielectric layer CD which lies on the upper surface of the insulating layer CIS.
The metal tracks or metallizations BLj are situated on the dielectric layer CD.
These metal tracks are fabricated in a conventional manner known per se within a metallization level of the integrated circuit, for example the first metallization level.
These metal tracks can for example be made of copper.
As illustrated in
The dielectric material forming the dielectric layer CD is a material capable of being subject to electrical breakdown, in other words of being irreversibly damaged so as to transform this dielectric region into a resistive region of low resistance.
As will be seen in more detail hereinbelow, this breakdown of a dielectric region is obtained by applying a breakdown voltage difference between the upper surface of the dielectric region and the middle semiconductor region of the multilayer of the bipolar transistor of the associated cell.
The phenomenon of breakdown of a dielectric disposed between two electrodes is well known to those skilled in the art. More precisely, when a high voltage is applied across the terminals of a capacitor formed from two electrodes separated by a dielectric oxide, defects are generated. When the density of defects reaches a critical value, a current will be established within the chain of defects and, by way of the heating effect, a conducting filament will be formed within the dielectric materials, thus changing this insulating material into a resistive one.
Several dielectric materials may be used for such an application. By way of non-limiting examples, silicon dioxide (SiO2), phosphosilicate glass (PSG), silicon nitride (Si3N4), alumina (Al2O3) or borosilicate glass (BSG) will be mentioned. Such materials can be deposited as thin films, for example by a low-temperature process of the plasma-enhanced chemical vapor deposition (PECVD deposition) type.
The thickness of the dielectric material layer depends on the choice of material and on the breakdown voltage used. By way of example, for SiO2 and for a breakdown voltage greater than or equal to 3.3 volts, a thickness of the order of 50 angstroms could be chosen.
Now, reference will more particularly be made to
In order to effect this selective programming, the breakdown voltage VPP, which is much higher than the power supply voltage of the integrated circuit, is applied to the bit line BL0 and also to the word line WL1.
In addition, ground potential (0 volts) is applied to the word line WL0 and to the bit line BL1.
Ground potential is also applied to the substrate SB so as to bias the lower regions of the multilayers of the bipolar transistors of the memory cells at ground potential.
The application of these various voltages is effected by means of conventional design, such as for example voltage sources and logic selection means which have been represented schematically by the block BLC in
As regards the cell CEL00, the breakdown voltage VPP is therefore applied to the upper surface of the dielectric region ZD00, while ground potential is applied to the middle region ZM00 of the transistor TR00.
The application of the breakdown voltage to the upper surface of the dielectric region ZD00 leads to the creation of an electric field across this dielectric region, which has the effect of causing the potential of the metal interconnect W00, and consequently of the region P+ of the transistor TR00, to rise. When this potential exceeds the threshold voltage of the p-n diode of the transistor TR00, formed between the region P+ and region N of this transistor, this diode becomes conducting since the n-type middle region ZM is at ground potential. Consequently, the potential of the lower surface of the dielectric region ZD00 goes to ground. The breakdown voltage difference is then present across the terminals of the dielectric material, which causes its irreversible breakdown as illustrated in
In contrast, the dielectric regions ZD01, ZD11 and ZD10 of the other memory cells are not subject to breakdown.
For example, with regard to the cell CEL01, ground potential is applied to the bit line BL1 and to the word line WL0. Consequently, there is no voltage difference across the terminals of the dielectric material.
The same is true as regards the dielectric region ZD10 of the cell CEL10 since the same voltage VPP is applied to the upper surface of the dielectric region and to the corresponding well N.
As far as the cell CEL11 is concerned, since ground potential is applied to the upper surface of the dielectric region ZD11 and since the voltage VPP is applied to the corresponding well N, the upper p-n diode of the transistor TR11 does not conduct. The dielectric material of the dielectric region ZD11 does not therefore see a breakdown voltage difference across its terminals.
In order to read the contents of a memory cell, the bit lines are pre-charged up to the supply voltage Vdd, for example 1 volt, and instead of applying the voltage VPP to the bit line of the cell CEL00, the read voltage Vdd is applied and the cell is selected by applying ground potential to the word line WL0. The value of the read current will of course depend on the dielectric insulating nature (dielectric not subject to breakdown) or conducting nature (dielectric subject to breakdown and becoming a resistance of low impedance).
It will therefore be noted that this aspect of the invention allows a cell to be programmed with a relatively low voltage and allows a very fast read operation to be obtained by reason of the bipolar behavior of the transistor (high read current).
In
More precisely, in
In actual fact, the fabrication of the OTP matrix only requires the production of one additional low-cost mask and one additional step for the deposition of the dielectric layer CD.
More precisely, following the fabrication of the CMOS core together with the bipolar transistors of the memory cells of the OTP memory array, and once the various metal interconnects W have been formed within the insulating layer CIS, the “CMOS core” part of the integrated circuit is masked, then the dielectric layer CD is deposited before depositing an etch stop layer CAR, for example a layer of silicon nitride, over the whole integrated circuit.
Subsequently, in a conventional manner known per se, the inter-level dielectric layer DIL is fabricated within which trenches are formed that are filled with material, for example with copper, so as to form the various bit lines BL.
Following the fabrication of this first metallization level M1, the other metallization levels of the integrated circuit are then be fabricated, as required, in a conventional manner.
However, here again in this variant, it can be seen that a portion of dielectric material capable of being subject to electrical breakdown has been formed between the copper bit line BL and the underlying metal interconnect W made of tungsten.
In this variant embodiment, the dielectric layer, formed from the dielectric material capable of being subject to electrical breakdown, is a discontinuous layer. More precisely, each memory cell, for example the cell CEL10, comprises a capacitor CPC10 extending over the insulating layer CIS. This capacitor CPC10 has a lower electrode EI10 in contact with the metal interconnect W10 and an upper electrode ES10. These electrodes can for example be made of titanium. The dielectric region ZD10 is then formed from a region of the portion of the discontinuous dielectric layer CD10 sandwiched between the two electrodes of the capacitor. The metallization BL0 has a part that fills the orifice of the capacitor situated above the upper electrode ES10.
In this
The programming principle of such a memory array is identical to that described hereinabove. In this respect, in the left-hand part of
The invention is not limited to the embodiments and implementation examples which have just been described and can also be applied notably in the case where the bipolar transistor of each memory cell is an npn transistor. In this case, in order to program the cell, ground potential (0 volts) is applied to the corresponding bit line and the breakdown voltage VPP is applied to the middle p-type semiconductor region of the transistor, which makes the upper p-n junction of the transistor conduct and allows the breakdown voltage difference to be applied across the terminals of the dielectric region of the cell.
Although preferred embodiments of the method and apparatus of the present invention have been illustrated in the accompanying Drawings and described in the foregoing Detailed Description, it will be understood that the invention is not limited to the embodiments disclosed, but is capable of numerous rearrangements, modifications and substitutions without departing from the spirit of the invention as set forth and defined by the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 0503571 | Apr 2005 | FR | national |
