This invention relates generally to silicidation reactions and the products thereof, and more particularly to the full silicidation of silicon in a recess.
Integrated circuit designs are continually being scaled down in efforts to reduce power consumption and increase speed. With each passing generation, devices tend to get smaller and more densely packed, raising a variety of problems for integration. One of the problems for integration is the small volumes provided for conductive elements. In order to achieve acceptable circuit speeds, it is important that such elements are provided with very high conductivity.
Other problems relate to difficulties in lining or filling high aspect ratio trenches or vias. For example, elongated trenches are used for damascene metallization; isolated holes or vias are used for forming vertical contacts; stacked trenches above the substrate and deep trenches within the substrate are used for memory cell capacitor formation; etc. Depositing within such vias becomes more challenging with higher aspect ratios with each passing generation. Voids can easily form during deposition or subsequent processing, leading to lower device yields.
In accordance with one aspect of the invention, a method is provided for forming a metal silicide structure in an integrated circuit. The method includes providing a recess within a partially fabricated integrated circuit. Silicon is deposited into the recess. A mixture of metals is deposited over the recess and in contact with the silicon, where the mixture of metals includes at least two metals having opposing diffusivities relative to silicon. The mixture of metals and the silicon are reacted in the recess to form a metal silicide within the recess.
In accordance with another aspect of the invention, a method is provided for forming a recessed access device for an integrated circuit. The method includes etching a trench in a semiconductor structure. The trench is lined with a dielectric layer, and the lined trench is at least partially filled with silicon. A metal layer is deposited over the trench and in contact with the silicon. The silicon in the trench is fully reacted in a silicidation reaction with the metal layer.
In accordance with another aspect of the invention, an integrated circuit is provided, including a metal silicide structure. A metal silicide fills at least a lower portion of a recess without voids. The metal silicide includes a mixture of at least a first metal having a greater diffusivity in silicon than silicon has in the first metal. The metal silicide also includes a second metal having a lesser diffusivity in silicon than silicon has in the second metal.
In accordance with another aspect of the invention, a memory device is provided. The device includes a recessed access device in a memory array, including a recess within a semiconductor substrate, a thin dielectric layer lining the recess, and a metal silicide filling at least a lower portion of the trench without voids.
The invention will be better understood from the detailed description of the preferred embodiments and from the appended drawings, which are meant to illustrate and not to limit the invention.
While the preferred embodiments of the present invention are illustrated in combination with a pitch doubling technique, it should be understood that the circuit design of these preferred embodiments may be incorporated into any integrated circuit. In particular, they may be advantageously applied to form any device having an array of electrical devices, including logic or gate arrays and volatile or non-volatile memory devices, such as DRAMs, RAMs, or flash memory. The integrated circuits formed by the methods described herein can be incorporated in any of a number of larger systems, such as motherboards, desktop or laptop computers, digital cameras, personal digital assistants, or any of a number of devices for which memory is useful.
The design and functioning of one memory device, a DRAM, laid out according to one embodiment of the present invention, is illustrated in the figures, and described in greater detail below.
Four elongate word lines 12a, 12b, 12c, 12d are also shown in
In general, pitch doubling may be performed by the following sequence of steps, as is well understood by those skilled in the art. First, photolithography may be used to form a pattern of lines in a photoresist layer overlying a layer of an expendable material and a substrate. This photolithographic technique achieves a pitch between adjacent lines of 2 F, as disclosed above, which pitch is limited by the optical characteristics of photolithography. In one embodiment, F is within the range of 60 to 100 nm. This range is typical for state-of-the-art photolithographic techniques used to define features. In one photolithography system, F equals approximately 86 nm, while, in another system, F equals approximately 78 nm.
The width of each line defined by photolithography is typically also defined as F, as would be well understood by those skilled in the art. The pattern may then be transferred by an etching step (preferably anisotropic) to the lower layer of expendable material, thereby forming placeholders, or mandrels in the lower layer. The photoresist lines can then be stripped, and the mandrels can be isotropically etched to increase the distance between neighboring mandrels. Preferably, the distance between the neighboring mandrels is increased from F to 3 F/2. Alternatively, the isotropic “shrink” or “trim” etch could have been performed at the level of the resist. A conformal layer of spacer material may then be deposited over the mandrels. This layer of material covers both horizontal and vertical surfaces of the mandrels. Spacers, i.e., material extending from sidewalls of another material, are therefore formed on the sides of the mandrels by preferentially etching the spacer material from the horizontal surfaces in a directional spacer etch. The remaining mandrels are then selectively removed, leaving behind only the spacers, which together may act as a mask for patterning. Thus, where a given pitch, 2 F, formerly included a pattern defining one feature and one space, the same width now includes two features and two spaces defined by the spacers. As a result, the smallest feature size achievable with a given photolithographic technique is effectively decreased. This method of pitch doubling, which may be repeated for further reduction in the size of the features, will be discussed in greater detail below with reference to
Of course, as would be well known in the art, the extent of the shrink/trim etch and the thicknesses of the deposited spacers may be varied to achieve a variety of feature and pitch sizes. In the illustrated embodiments, whereas the photolithographic technique may resolve a pitch of 2 F, the features, i.e. word lines 12 in the instant example, have a pitch of F. The word lines 12 are defined by a width of about F/2, and adjacent word lines 12a, 12b or 12c, 12d are separated by the same width, F/2. Meanwhile, as a byproduct of the pitch-doubling technique, the separation between the spaced-apart word lines 12b, 12c is 3 F/2. In a preferred embodiment, an isolation trench is filled with an insulator and lies within this separation between these word lines 12b, 12c; however, in other embodiments, this isolation trench need not be present.
For every distance of 3 F, there are two word lines, yielding what may be referred to as an effective pitch of 3 F/2. More generally, the word lines preferably have an effective pitch between 1.25 F and 1.9 F. Of course, the particular pitch used to define the word lines is only an example. In other embodiments, the word lines may be fabricated by more conventional techniques, and pitch doubling need not be used. In one embodiment, for example, the word lines may each have a width of F and may be separated by F, 2 F, 3 F or some other width. In still other embodiments, the word lines need not be formed in pairs either. For example, in one embodiment, only one word line need pass through each active area.
The entire length of the word lines 12 is not visible in
In one embodiment, the word lines 12 comprise a p-type semiconductor, such as silicon doped with boron. In other embodiments, the word lines 12 may comprise an n-type semiconductor, metal silicide, tungsten or other similarly behaving material, as is well-known to those of skill in the art. In some embodiments, the word lines 12 may comprise a variety of materials, in a layered, mixed or chemically bonded configuration.
The horizontal lines seen in
As with the word lines 12, the entire length of the digit lines 14 is also not visible in
In one embodiment, the digit lines 14 comprise a conducting metal, such as tungsten, copper, or silver. In other embodiments, other conductors or semiconductors may be used, as is well-known to those of skill in the art.
The other features visible in
In another embodiment, the active areas may comprise one source and one drain, wherein the source is formed near the digit line, and the drain is separated from the source by a word line. In such an embodiment, the memory device may be configured similarly to the memory device 10 in
As illustrated, a digit line 14 runs proximal to, and preferably above (see
The functioning of memory device 10 is briefly discussed with reference to
As shown in
In one embodiment, at least a portion of digit line 14b is located above the upper surface of source 20. As illustrated in
In one embodiment, one side of every storage capacitor 24 forms a reference electrode 30, while the lower electrode 26 is electrically coupled to an associated drain 18. The word lines 12a, 12b function as gates in the field effect transistors they pass through, while the digit line 14b functions as a signal for the sources to which it is electrically coupled. Thus, the word lines 12a, 12b preferably control access to the storage capacitors 24 coupled to each drain 18, by allowing or preventing the signal (representing a logic “0” or a logic “1”) carried on the digit line 14b to be written to or read from the storage capacitors 24. Thus, each of the two capacitors 24 connected to an associated drain 18 can contain one bit of data (i.e., a logic “0” or logic “1”). In a memory array, the combination of the digit line and word line that are selected can uniquely identify the storage capacitor 24 to or from which data should be written or read.
Turning back then to
Axis B represents the longitudinal axis of digit line 14b. In the illustrated embodiment, the digit line 14b forms a substantially straight line. Just as the active areas 16 are preferably parallel, the digit lines 14a, 14b also preferably form generally parallel axes. Thus, in a preferred embodiment, axis A of every active area 16 forms a similar angle with every axis B of the digit lines 14, at least in the region of each memory cell.
In a preferred embodiment, illustrated in
The angling of the active areas 16 relative to the digit lines 14 facilitates the location of the contact plugs 28 extending between drains 18 and associated storage capacitors 24. Since these contact plugs 28 extend from the top surface of the drains 18 in the preferred embodiment (illustrated in
Of course, the angle, θ, may have any of a number of values chosen to maximize the pitch of the electrical devices. As will be readily apparent to one of skill in the art, different angles will yield different pitches between adjacent active areas. In one embodiment, the angle, θ, is preferably between 10° and 80° degrees. In a more preferred embodiment, the angle, θ, is between 20° and 60°. In a still more preferred embodiment, the angle, θ, is between 40° and 50°.
Turning to
Next, in a step not illustrated in the figures, the hard mask layer 42 is patterned using a photoresist layer formed over the hard mask layer 42. The photoresist layer may be patterned to form a mask using conventional photolithographic techniques, and the hard mask layer 42 may then be anisotropically etched through the patterned photoresist to obtain a plurality of hard mask columns 44 extending in the y-dimension (as defined by
With reference to
After laying the spacer material over the vertical and horizontal surfaces of the memory device 10, an anisotropic etch may be used to preferentially remove the spacer material from the horizontal surfaces in a directional spacer etch. Thus, the spacer material is formed into spacers 48, i.e., material extending from the sidewalls of another material. As shown in
With reference to
The spacers 48 that are now exposed at the top surface of the memory device 10 may be stripped using any of a number of processes. In the illustrated embodiment, a process may be used that selectively strips polysilicon relative to silicon nitride. For example, in one embodiment, a selective wet etch may be used. The trenches formed where the spacers 48 have been etched are further deepened by a secondary etch that selectively etches the temporary layer 40 as well as the substrate 11. These trenches are also preferably formed using a directional process, such as, for example, ion milling or reactive ion etching.
After formation of these trenches 50, the hard mask layer 42 is selectively stripped, by any of a number of methods well known to those of skill in the art. In
After a series of doping steps to define the drains and sources of transistors, the undoped polysilicon in the trenches 50 is etched back until the top of the gate layer 52 resides beneath the top surface of the substrate 11. This stage of the process is shown in
Preferably, however, the gate electrodes in the arrays are formed of a more highly conductive material than traditional polysilicon gates. This is due to the fact that the recessed gates 12 (see
With reference to
Preferably, the gate layer 52 is fully silicided to maximize lateral conductivity. Full reaction also assures silicide formation down to the bottom of the trenches 50. In the illustrated recessed access devices (RADs), the channel extends across not only the bottom of the gate, but also along the gate's sidewalls. Accordingly, incomplete silicidation would result in different work functions along the length of the RAD channel. Furthermore, full silicidation ensures similar gate work functions across the array, from array to array across a wafer, and from wafer to wafer. It has been found difficult, however, to achieve full silicidation within the tight confines of the illustrated trenches 50, with a single metal to form the conductive material 56. Either nickel or cobalt, for example, tends to form voids in the high-aspect ratio trenches 50. Other metals have demonstrated similar difficulties for full silicidation for recessed access devices. The skilled artisan will appreciate that full silicidation can be challenging for material within other types of recesses, such as contact openings or vias, stacked container shapes for capacitors, capacitor trenches, etc.
Without wanting to be bound by theory, the voiding appears to be caused by diffusion during the silicidation reaction, in combination with the tight confines of the high aspect ratio trenches 50. Silicon diffuses more readily in cobalt than cobalt does into silicon. Accordingly, silicon tends to migrate during the reaction, leaving voids in the trenches 50. Furthermore, a high temperature phase transformation anneal to may convert the silicide from CoSi to the more stable CoSi2. Nickel, on the other hand, diffuses more readily into silicon than silicon does into nickel and so also has a tendency to create voids during the reaction in which NiSi is converted into the NiSi2 phase.
Accordingly, the metal layer 55 preferably comprises a mixture of metals, where at least two of the metals in the mixture have opposing diffusivities relative to silicon. For example, the metal layer 55 can comprise a mixture of nickel and cobalt, such that the directions of diffusion tend to balance each other and minimize the risk of voiding. In this example, the cobalt preferably comprises less than 50 at. % of the mixed metal 55, and more preferably the mixture comprises about 70-90 at. % Ni and about 10-30 at. % Co. Such a mixture of nickel and cobalt has been found to more readily accomplish full silicidation of the gate layer without voiding, thus increasing signal propagation speeds along the word line. In contrast to partial silicidation, fully silicided word lines are not only more conductive, but also will ensure consistent work function along the length of the channel. Full silicidation will also demonstrate better consistency from device to device across an array, from array to array, or wafer to wafer, since partial silicidation will tend to leave inconsistent compositions depending upon local temperature variations, etc.
In one example, a sputtering target comprising 80% Ni and 20% Co is sputtered over the polysilicon 52 to produce the metal layer 55. The substrate is then subjected to a silicidation anneal. While a high temperature (e.g., 800° C.) anneal is possible for a shorter time, preferably the anneal is conducted at lower temperatures for a longer time. For example, the substrate is annealed at 400-600° C. for 25-35 minutes. In experiments, the silicidation anneal was conducted in a batch furnace under an N2 environment at 500° C. for 30 minutes.
In view of the disclosure herein, the skilled artisan can readily select other suitable mixtures of metals for full silicidation within trenches. Examples of metals that diffuse more readily in silicon than silicon does in that metal include Ni, Pt and Cu. Examples of metals in which silicon diffuses more readily than the metal diffuses in silicon include Co, Ti and Ta.
Referring now to
Of course, in other embodiments, the pitch-multiplication may take place by any of a variety of processes well-known to those skilled in the art.
The silicided layers 56 of the illustrated embodiment thus fill lower portions of the trenches 50, preferably filling greater than 50% of the trench heights, more preferably filling greater than 75% of the trench height. In the illustrated embodiment, about 70-90 at % of metal in the metal silicide 56 is nickel and about 10-30 at % of metal in the metal silicide is cobalt.
As will be appreciated by the skilled artisan, in a preferred embodiment, the logic in the periphery is preferably simultaneously defined as certain of the above steps are completed, thereby making the chip-making process more efficient. In particular, the silicon and metal deposition steps to define recessed word lines preferably simultaneously define gate electrodes over the substrate for the CMOS transistors in the periphery.
Referring to
With reference to
With reference to
Subsequently, as shown in
With reference to
Referring to
As shown in
Referring now to
Referring now to
As shown in
The skilled artisan will appreciate that various doping steps for CMOS transistors, including source/drain, channel enhancement, gate electrode, lightly doped drain (LDD) and halo doping, are omitted in the description herein for simplicity.
The embodiment of
Although not shown, it will be understood that conventional DRAM fabrication techniques may be used to create the other circuit elements shown in
As a result of the device layout and its method of manufacture, the completed memory device 10 shown in
Furthermore, the use of a mixture of metals facilitates full silicidation of the silicon buried within trenches 50 without the harmful formation of voids. Accordingly, a high conductivity can be achieved for the relatively small volume word lines.
While certain embodiments of the inventions have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the invention. Indeed, the novel methods and devices described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the methods and devices described herein may be made without departing from the spirit of the invention. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the invention.
This application is a divisional of U.S. patent application Ser. No. 11/219,303, filed Sep. 1, 2005, entitled “SILICIDED RECESSED SILICON,” which is incorporated herein by reference. This application is also related to U.S. application Ser. No. 11/219,349, filed on Sep. 1, 2005, entitled “MEMORY CELL LAYOUT AND PROCESS FLOW” and U.S. application Ser. No. 11/219,304, filed Sep. 1, 2005, entitled “PERIPHERAL GATE STACKS AND RECESSED ARRAY GATES.”
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 11219303 | Sep 2005 | US |
Child | 11614802 | US |