The present application relates to one time programmable (OTP) memory cells, to memory arrays comprising such memory cells and to corresponding methods.
One time programmable memory cells and corresponding memory arrays provide non-volatile memory which may be programmed once with desired values to be stored, which values then remain stored also without power being supplied. Sometimes, such one time programmable memories are also referred to as programmable read only memories (“PROM”). Such memories use configurations where elements like fuses or anti-fuses are arranged in an array and accessible by wordlines and bitlines. Fuses or anti-fuses may be irreversibly modified by applying a programming voltage, for example through breakdown of an oxide, thus programming the memory. Reading the memory then generally occurs using lower voltages than the programming voltage.
Such memories are for example used in telecommunication applications, sensor applications, in read-out circuits, e.g. application specific integrated circuits (ASICs) for microelectromechanical systems (MEMS) or in radio frequency switches, but are not limited to these applications. Non-volatile memories may for example be used for storing calibration data from a post-manufacturing calibration or to store software code needed for a particular device.
Increasingly, there is a demand for higher storage densities of such memories, i.e. a higher number of memory cells per area. Furthermore, it is desirable that production of such memories be compatible with standard manufacturing techniques, for example CMOS process compatible. Finally, high reliability of such memories is desired.
A memory cell as defined in claim 1 or 10 is provided. The dependent claims define further embodiments, a memory array comprising such memory cells and a method for programming such a memory array.
According to an embodiment, a memory cell is provided, comprising:
According to another embodiment, a memory cell is provided, comprising:
According to a further embodiment, a memory array is provided, comprising:
According to another embodiment, a method for programming such a memory array is provided.
The above summary is merely intended to give a brief overview over some implementations and is not to be construed as limiting. In particular, other implementations may comprise other features than the ones discussed above.
In the following, various embodiments will be described in detail referring to the attached drawings. These embodiments are provided by way of example only and are not to be construed as limiting. For example, while embodiments may be shown and described as comprising a plurality of features or elements, in other embodiments some of these features or elements may be omitted, and/or replaced by alternative features or elements. Moreover, in addition to the features and elements explicitly shown and described, further features or elements, for example features or elements conventionally used in one time programmable memories like fuse or anti-fuse based memories may be provided.
Features from different embodiments may be combined to form further embodiments unless noted otherwise. Furthermore, variations or modifications described with respect to one of the embodiments may also be applied to other embodiments.
A fuse element, as used herein, is a component where by applying a programming voltage and/or current an electrical connection is irreversibly separated, corresponding to behavior of conventional fuses used in buildings, where a high current leads to an interruption of an electrical connection. An anti-fuse element, in contrast thereto, is an element where by applying programming current and/or voltage an electrical isolation like an oxide film is weakened and/or at least partially destroyed, thus establishing an electrical connection. The term “fusable element” will be used herein to refer both to fuse elements and anti-fuse elements.
Generally, as commonly used in the art, + signs after p or n indicate higher p- or n-type doping concentrations, and ++ signs indicate even higher concentrations, like degenerate doping to provide electrical contact regions.
Turning now to the figures,
Adjacent to element 13, a bipolar transistor 12, i.e. an npn transistor or a pnp transistor, is provided, which is used inter alia for reading and/or programming memory cell 10. In particular, a first electrical connection may be provided to element 13, and a second electrical connection may be provided to bipolar transistor 12, and for reading a voltage may be applied between the first and second connection. Depending on a state of element 13 (programmed or unprogrammed) a current flowing in response to the voltage may vary.
In some embodiments, for reading memory cell 10 bipolar transistor 12 may be open, i.e. essentially non-conducting between collector and emitter terminals thereof. Furthermore, in some embodiments, where a plurality of cells 10 are arranged in a memory array, transistors of cells not being read or at least some transistors like transistors of adjacent cells adjacent of a cell to be read to be opened may be closed, i.e. essentially conducting between collector and emitter terminals. Providing a bipolar transistor in some embodiments may lead to lower leakage currents than for example providing only a simple diode.
Furthermore, adjacent to highly p doped region 27, a highly n doped (n++) region 26 is provided. Regions 29, 27, 28 are separated by a shallow trench isolation (STI) generally labeled 23. Shallow trench isolation 23 may include or be formed as a n+ doped region. Surrounding shallow trench isolation 23, a p+ ring 21 is provided.
Bridging highly n doped region 26 and highly p doped region 27, a cobalt silicide (CoSi) film 25 is provided as an example for an electrically conducting layer. Other electrically conducting layers may also be used, e.g. metal films. Highly p doped region 27 and highly n doped region 26 bridged with electrically conducting layer 25 provide a kind of “carrier conversion” from minority carriers to majority carriers in region 29, which reduces leakage to substrate. A further electrically conducting layer 217, for example made of CoSi, is provided on highly p doped region 28. In other embodiments, layer 217 may be omitted, and contacting may be made e.g. via a polysilicon layer.
Furthermore, a thin oxide film 24 is provided at least on a part 22 of n+ region 29. While in the representation of
On top of oxide film 24, doped polysilicon 210 is provided followed by an electrically conducting layer 211, for example CoSi. Instead of CoSi, other conducting materials, for example metal layers, may be provided. Please note that in the top view of
Graphic symbol 214 denotes a capacitance between polysilicon 210 and n+ region 29 (in particular part 22 thereof), and a graphic symbol 218 denotes a capacitance between n+ region 29 and p substrate 20. Such a capacitance as capacitance 218 in general occurs at pn junctions like the pn junction formed by substrate 20 and n+ region 29.
Electrically conducting material 217 serves as a first contact area 215 via a metal layer 212, and electrically conducting material 211 serves as a second contact area 216. First and second contact areas 215, 216 may be used to access the memory cell of
In some embodiments, as illustrated in
The memory cell of
Next, programming the memory cell, i.e. bringing the cell from the unprogrammed state to the programmed state, will be discussed referring to
For programming the cell, a voltage exceeding a programming threshold is applied between contact areas 215 and 216, for example a pulse of about 8 V. This voltage has to be such to exceed a threshold for oxide 24. A curve 40 of
When starting the pulse, the voltage rises, and a current flows until the capacitors 214 and 218 are charged. Then, the voltage remains constant, while the current drops to a value close to 0 corresponding to leakage current through the (intact) oxide 24. Then, through breakdown effects, the oxide breaks down, leading to a large increase of current flow according to curve 50 of
This breakdown of oxide 24 is irreversible, such that after applying the programming pulse the cell remains in the programmed state.
For the selected cell 80, a current caused by the applied voltage flows in the forward direction via the pn junction formed by the highly doped p region and n+ region 29 and therefore is essentially fully applied over oxide 28, thus programming it.
For unprogrammed cells on the selected wordline of cell 80, as the bitline is floating no oxide damage occurs for the pulse length of the programming pulse (as e.g. shown in
For a programmed cell like cell 81 on the selected wordline, 8 V is applied to the wordline and the bitline is floating, which may lead to a low current flow, which, however, does not disturb the programming.
For a programmed cell 81 on a selected bitline, i.e. the bitline through cell 80, both wordline and bitline have 0 V applied, and therefore the pnp transistor 212 is open, i.e. no current may flow (0 V applied to base and emitter). Finally, programmed cell 81 on different wordlines and bitlines have a wordline voltage (at region 28, i.e. the emitter) of 0 V, even higher bitline voltage for example up to 8 V would lead to a reversed biasing and no current flow. By designing the width of the shallow trench isolations 23 accordingly, it may be ensured that no breakdown occurs at such voltages.
Next, reading of memory cells will be discussed referring to
This will be explained in more detail referring to
For cell 110, this biases the pn junction between highly p doped region 28 and n+ region 29 in forward direction, such that a current may flow. For a programmed cell, the isolation provided by oxide 24 is reduced or removed, such a higher current flows than in case of an unprogrammed cell.
For a programmed cell 111 on the same bitline as cell 110, wordline and bitline voltage are both 0 V, such that no current flows. The same applies to an unprogrammed cell on the same bitline.
A programmed cell on the same wordline provides some leakage current, as it is also biased in the forward direction.
Therefore, as shown above with the cell discussed with reference to
At least some embodiments are defined by the examples given below:
A memory cell, comprising:
The memory cell of example 1, wherein the fusable element comprises an anti-fuse element.
The device of example 2, wherein the anti-fuse element comprises an oxide film.
The device of example 3, wherein a thickness of the oxide film is between 2 nm and 3 nm.
The device of example 1, wherein the bipolar transistor comprises a pnp transistor.
The device of example 5, wherein a first p doped region of the pnp transistor is provided adjacent to the fusable element and separated from the fusable element by an isolation region.
The memory cell of example 6, wherein the isolation region comprises a shallow trench isolation.
The device of example 6, wherein a second p doped region of the pnp transistor is provided adjacent to an n doped region, wherein the second p doped region and the n doped region are coupled by an electrically conducting layer.
The device of example 1, wherein the bipolar transistor is coupled to a wordline terminal of the memory cell, and the fusable element is coupled to a bitline terminal of the memory cell.
A memory cell, comprising:
The memory cell of example 10, comprising a first isolation region between the first and second regions of the first polarity, and a second isolation region between the first region of the first polarity and the oxide.
The memory cell of example 10, wherein the first contact region comprises a polycrystalline semiconductor on the oxide and an electrically conducting layer on the polycrystalline semiconductor material.
The memory cell of example 10, wherein the first contact region is a bitline contact, and the second contact region is a wordline contact.
The memory cell of example 1, further comprising a further region of the second polarity adjacent to the second region of the first polarity, the further region of the second having a higher dopant concentration than the region of the second polarity, and an electrically conducting layer bridging the second region of the first polarity and the further region of the second polarity.
The memory cell of example 1, further comprising a p-doped ring region surrounding the region of the second polarity.
The memory cell of example 10, wherein the first polarity is a p polarity, and the second polarity is an n polarity.
A memory array, comprising:
A method for programming the memory arrangement of example 17, comprising, for programming a selected memory cell of the plurality of memory cells:
The method of example 18, wherein the third voltage is equal to the first voltage.
The method of example 18, wherein the second and third voltages are 0 V, and the first voltage is at least 8 V.
As can be seen from the above discussions of variations and modifications, the above-described embodiments are not to be construed as limiting, but serve merely as non-limiting examples.
Number | Date | Country | Kind |
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10 2016 115 939 | Aug 2016 | DE | national |
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Entry |
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Office Action, in the German language, from counterpart German Application No. 102016115939.5, dated Apr. 20, 2017, 9 pp. |
Number | Date | Country | |
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20180061756 A1 | Mar 2018 | US |