A low resistivity interface material is provided between a self-aligned vertical heater element and a contact region of a selection device. A phase change chalcogenide material is deposited directly on the vertical heater element. In an embodiment, the vertical heater element in l-shaped, having a curved vertical wall along the wordline direction and a horizontal base. In an embodiment, the low resistivity interface material is deposited into a trench with a negative profile using a PVD technique. An upper surface of the low resistivity interface material may have a tapered bird-beak extension.
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1. A phase change memory cell comprising:
a first selection device and a second selection device respectively associated with a first phase change memory cell and a second phase change memory cell, the first and the second selection devices disposed along a wordline direction;
a contact region on said selection devices;
an interface layer in direct contact with said contact region;
an l-shaped vertical heater element in direct contact with said interface layer, wherein said l-shaped vertical heater element includes a curved vertical wall and a horizontal base, wherein the vertical wall and the horizontal base of the l-shaped vertical heater element respectively have a height and a length that perpendicularly extend, and wherein said curved vertical wall of said l-shaped vertical heater element has a width extending perpendicular to a direction of the length of horizontal base and extending along said wordline direction; and
a phase change material in direct contact with said vertical heater element, wherein the first and the second selection devices are separated along the wordline direction by a trench isolation that extends into and terminates within a wordline under the first and the second selection devices.
10. A phase change memory array comprising:
a plurality of selection devices extending along a wordline direction;
a silicide contact region on each of said plurality of selection devices;
an interface material formed on an in direct contact with each of said silicide contact regions;
a plurality of l-shaped heater elements each comprising a curved vertical wall and a horizontal base, the vertical wall and the horizontal base of the l-shaped vertical heater element respectively having a height and a length that perpendicularly extend, the vertical wall having a width extending perpendicular to a direction of the length of horizontal base and extending along said wordline direction of said phase change memory array, and each l-shaped heater element being in direct contact with said interface material; and
a phase change material in direct contact with said plurality of l-shaped heater elements;
wherein said plurality of l-shaped heater elements are self-aligned with said phase change material extending along a bitline direction of said phase change memory array, wherein the plurality of selection devices are separated along the wordline direction by a trench isolation that extends into and terminates within a wordline under the plurality of selection devices.
12. A phase change memory array comprising:
a plurality of selection devices arranged in a plurality of rows along a wordline direction and in a plurality of columns along a bitline direction;
a contact region on each of said plurality of selection devices;
a plurality of interface materials each formed in direct contact with said contact region;
a plurality of l-shaped heater elements extending along said wordline direction and in direct contact with said plurality of interface materials, wherein each l-shaped vertical heater element includes a curved vertical wall and a horizontal base, wherein the vertical wall and the horizontal base of the l-shaped vertical heater element respectively have a height and a length that perpendicularly extend, and wherein the curved vertical wall of said l-shaped vertical heater element has a width extending perpendicular to a direction of the length of horizontal base and extending along said wordline direction; and
a phase change material in direct contact with said plurality of l-shaped heater elements,
wherein each row of said plurality of rows of selection devices is separated from an adjacent row of said plurality of rows of selection devices by a first trench isolation, and wherein each column of said plurality of columns of selection devices is separated from an adjacent column of said plurality of columns of selection devices by a second trench isolation that extends into and terminates within a wordline under the plurality of selection devices and is shallower than said first isolation.
2. The phase change memory of
4. The phase change memory of
6. The phase change memory of
7. The phase change memory of
8. The phase change memory of
9. The phase change memory of
11. The phase change memory array of
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Embodiments of the invention relate to a process for manufacturing a phase change memory cell with fully self-aligned vertical heater elements.
Phase change memories are formed by memory cells connected at the intersections of bitlines and wordlines and comprising each a memory element and a selection element. A memory element comprises a phase change region made of a phase change material, i.e., a material that may be electrically switched between a generally amorphous and a generally crystalline state across the entire spectrum between completely amorphous and completely crystalline states.
Typical materials suitable for the phase change region of the memory elements include various chalcogenide elements. The state of the phase change materials is non-volatile, absent application of excess temperatures, such as those in excess of 150° C., for extended times. When the memory is set in either a crystalline, semi-crystalline, amorphous, or semi-amorphous state representing a resistance value, that value is retained until reprogrammed, even if power is removed.
Selection elements may be formed according to different technologies. For example, they can be implemented by diodes, metal oxide semiconductor (MOS) transistors or bipolar transistors. Heater elements are supplied in connection with the selection elements in order to provide heat to the chalcogenide elements.
Embodiments of the invention relate to a phase change memory cell with fully self-aligned vertical heater elements and process for manufacturing the same.
Various embodiments described herein are described with reference to figures. However, certain embodiments may be practiced without one or more of these specific details, or in combination with other known methods and configurations. Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, configuration, composition, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. Thus, the appearances of the phrase “in one embodiment” or “an embodiment” in various places throughout this specification are not necessarily referring to the same embodiment of the invention. Furthermore, the particular features, configurations, compositions, or characteristics may be combined in any suitable manner in one or more embodiments.
Embodiments of the invention disclose a phase change memory cell including a self-aligned vertical heater element deposited directly on a low resistivity interface layer which is deposited directly on a silicide contact region of a selection element. A phase change material is deposited directly on the vertical heater element. The low resistivity interface layer decreases the resistance at the interface between the silicide contact region of the selection element and the heater element, thereby reducing voltage requirements and improving the ability to read and write the phase change material. As used herein, the term low resistivity means having a resistivity lower than that of the material used to form the heater element.
In an embodiment, the selection element is a vertical pnp bipolar junction transistor (BJT) and the vertical heater element is L-shaped, having a curved vertical wall extending along the wordline direction and a horizontal base orthogonal to the curved vertical wall. The self-aligned fabrication process allows for controlled alignment of the curved vertical wall to the bitline direction of the phase change memory cell, as well as the controlled alignment between the phase change material and heater element. The curved vertical wall and the horizontal base may have the same thickness.
The L-shaped vertical heater element is formed by performing an anisotropic etching operation to form a trench in a dielectric layer, following by an isotropic etching operation to create a negative profile in the trench sidewalls. A low resistivity interface layer is deposited within the anisotropically etched trench utilizing a unidirectional deposition technique such that the low resistivity interface layer does not deposit on the negative profile. In an embodiment, the deposited low resistivity interface layer includes an upper tapered bird-beak extension where the low resistivity interface layer is deposited on the anisotropically etched trench sidewall. A conformal conductive layer is then deposited over the structure, which is subsequently processed to form the L-shaped vertical heater element having a curved vertical wall and a horizontal base.
In one embodiment, a pnp-BJT array includes emitter pillars having a width and depth of F×F, with F being the lithographic node. For example, utilizing 193 nm immersion lithography, the width and depth of the emitter pillars is approximately 50 nm. In such an embodiment, the L-shaped vertical heater element may have a thickness of between 5-10 nm and a height between 50-150 nm. In an embodiment, the curved vertical wall portion has an aspect ratio of at least 5:1 height:width, with the width being measured at the midpoint.
Each row of emitter pillars 16 is separated from an adjacent row in the x-direction by shallow trench isolation 22. Likewise, each column of emitter pillars 16 is separated from adjacent emitter pillars 16 in the y-direction by shallow trench isolation 20. The shallow trench isolations 22 may be shallower than the shallow trench isolations 20. The deeper shallow trench isolations 20 may extend all the way into the p-type collector 12 while the shallow trench isolations 22 may extend only into the n-type wordline 14. Thus, the n-type wordline 14 is made up of a lower part 14b which is below the shallow trench isolations 22, and an upper part 14a which is above the bottom of shallow trench isolations 20.
The base contacts 18 are n+ base contacts, the emitters 16 are p-type, and the wordline is n-type. Silicide contact regions 26 are formed on top of p+ emitter regions 17 and n+ base regions 19. A BJT transistor is formed with an emitter 16, base contact 18, wordline 14, and collector 12. The wordline 14 is common to each row in the x-direction. The collector 12 is common to all the transistors. In certain embodiments, the polarities of the transistors may be reversed. In addition, the number of columns of emitters 16 between base contacts 18 can be more or less than four.
In an embodiment, each emitter pillar 16 has a width and depth of F×F, with F being the lithographic node. Emitters 16 are separated in the x-direction by shallow trench isolations 22 with a width of F, and in the y-direction by shallow trench isolations 20 with a width F. By way of example, the pnp-BJT array may be fabricated utilizing 193 nm immersion lithography, in which the width and depth of the pillars is approximately 50 nm, the height of the pillars along the x-direction is approximately 100 nm, and the height of the pillars along the y-direction is approximately 250 nm. The silicide 26 may comprise cobalt silicide, though other metal silicides may be used. Where dimensions of the pnp-BJT array are larger, titanium silicide may be preferred. Where dimensions of the pnp-BJT array are smaller, nickel silicide may be preferred. Though embodiments are not limited to such dimensions determined by the lithographic node F.
Dielectric layers 30 and 31 may be deposited utilizing conventional vapor deposition techniques such as chemical vapor deposition (CVD) to a thickness which is greater than the eventual height of the heater elements because some of the thickness will be removed in a subsequent planarization operation. In an embodiment, dielectric layers 30 and 31 are formed of two different materials in order to provide differential etch selectivities and indices of refraction for endpoint determination during chemical mechanical polishing (CMP). In an embodiment, dielectric layer 30 is a nitride, such as silicon nitride, between 50 and 200 nm thick, and dielectric layer 31 is an oxide, such as silicon oxide, between 20 and 100 nm thick, though other materials and thicknesses may be used.
Trenches 32 may be formed utilizing conventional lithographic techniques and anisotropic etching. This is followed by an isotropic etching operation. In an embodiment a wet buffered oxide etch utilizing known chemistries including fluorinated etchants (ex. HF) with buffers (ex. NH4F) or solvents is used. In an embodiment, the isotropic etchant has an etch selectivity of at least 5:1 or 10:1 to dielectric layer 30 and dielectric layer 31.
The expanded view in
As described above, embodiments of the present invention describe a two layer dielectric system including layers 30 and 31 so that the different etch selectivities can be taken advantage of to create an overhang and/or lip in layer 30 while layer 31 preserves the physical quality of the top surface of layer 30 thereby producing a negative profile. It is to be appreciated that additional embodiments exist in which only a single dielectric layer 30 is utilized to create the negative profile, or more than two dielectric layers are utilized.
In an embodiment, trenches 32 are formed with curved sidewalls 34 approximately directly above the center vertical axis of the emitter pillars 16 (and base pillars 18 not shown) in order to facilitate placement of the curved vertical wall 52 of heater element 50 directly above the center vertical axis of the emitter pillars 16. In such an embodiment, trenches 32 then have a width of 2 F, or approximately 100 nm utilizing 193 nm immersion lithography. Though it is to be appreciated that such alignment is not required for the self-alignment process in accordance with embodiments of the invention. As will become more evident in the following figures, the width of trenches 32 can be wider or narrower in order to tailor both the placement of the curved vertical wall component 52 of the heater element 50 on the underlying silicide 26 of the emitter pillars 16. A wider trench 32 will result in a heater element 50 with a longer horizontal base component 54 and low resistivity interface layer 44, with a narrower trench 32 resulting in a heater element 50 with a shorter or non-existent horizontal base component 54 and low resistivity interface layer 44.
As illustrated in
Low resistivity interface layer 44 is deposited utilizing a unidirectional deposition technique which does not deposit onto negative profiles. For example, low resistivity interface layer is deposited by a physical vapor deposition (PVD) technique such as sputtering. As shown in
A conformal conductive layer 36, which is subsequently processed to form heater elements 50, is then deposited over the pnp-BJT array as illustrated in
A conformal dielectric layer 38 is then deposited over the conformal conductive layer 36 as illustrated in
Conformal dielectric layer 38, conformal conductive layer 36, and low resistivity interface layer 44 are then anisotropically etched back to provide the structure in
A dielectric layer 56 is then blanket deposited over the pnp-BJT array and within the trenches 32 and planarized as shown in
As shown in
A phase change layer 60, such as a chalcogenide, and metallic cap layer 62 are then blanket deposited over the pnp-BJT array as shown in
As shown in
Turning to
System 1200 may include a controller 1210, an input/output (I/O) device 1220 (e.g. a keypad, display), static random access memory (SRAM) 1260, a memory 1230, and a wireless interface 1240 coupled to each other via a bus 1250. A battery 1280 may be used in some embodiments. It should be noted that the scope of the present invention is not limited to embodiments having any or all of these components.
Controller 1210 may comprise, for example, one or more microprocessors, digital signal processors, microcontrollers, or the like. Memory 1230 may be used to store messages transmitted to or by system 1200. Memory 1230 may also optionally be used to store instructions that are executed by controller 1210 during the operation of system 1200, and may be used to store user data. Memory 1230 may be provided by one or more different types of memory. For example, memory 1230 may comprise any type of random access memory, a volatile memory, a non-volatile memory such as a flash memory and/or a memory discussed herein.
I/O device 1220 may be used by a user to generate a message. System 1200 may use wireless interface 1240 to transmit and receive messages to and from a wireless communication network with a radio frequency (RF) signal. Examples of wireless interface 1240 may include an antenna or a wireless transceiver, although the scope of the present invention is not limited in this respect.
In the foregoing specification, various embodiments of the invention have been described. It will, however, be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of the invention as set forth in the appended claims. The proposed cell architecture can be exploited with several other types of selecting elements such as silicon diode, MOSFET selector, OTS material, ZnO-based diode, binary-oxide diodes placed below the heater element or on top of the chalcogenide layer. Depending on the type of selector chosen, multi-stack array are also feasible. The specification and drawings are, accordingly, to be regarded in an illustrative sense rather than a restrictive sense. It is intended that the appended claims cover all such modifications and variations as fall within the true spirit and scope of this present invention.
Zanderighi, Barbara, Pipia, Francesco
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
7422926, | Jun 03 2005 | STMICROELECTRONICS S R L | Self-aligned process for manufacturing phase change memory cells |
8168479, | Mar 04 2009 | Samsung Electronics Co., Ltd | Resistance variable memory device and method of fabricating the same |
20040042329, | |||
20060138467, | |||
20060202245, | |||
20070148814, | |||
20070254446, | |||
20070278470, | |||
20080012079, | |||
20080099753, | |||
20080185570, | |||
20090017577, | |||
20100308296, | |||
20110001114, | |||
CN101393965, | |||
CN1819295, | |||
TW200834908, | |||
TW200849480, |
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