Semiconductor-on-insulator (SOI) technology was first commercialized in the late 1990s. The defining characteristic of SOI technology is that the semiconductor region in which circuitry is formed is isolated from bulk substrate by an electrically insulating layer. This insulating layer is typically silicon-dioxide. The reason silicon-dioxide is chosen is that it can be formed on a wafer of silicon by oxidizing the wafer and is therefore amenable to efficient manufacturing. The advantageous aspects of SOI technology stem directly from the ability of the insulator layer to electronically isolate the active layer from bulk substrate. As used herein and in the appended claims, the region in which signal-processing circuitry is formed on an SOI structure is referred to as the active layer of the SOI structure.
SOI technology represents an improvement over traditional bulk substrate technology because the introduction of the insulating layer isolates the active devices in an SOI structure which improves their electrical characteristics. For example, the threshold voltage of a transistor is desirously uniform, and is set in large part by the characteristics of the semiconductor material underneath the transistor's gate. If this region of material is isolated, there is less of a chance that further processing will affect this region and alter the threshold voltage of the device. Additional electrical characteristic improvements stemming from the use of the SOI structure include fewer short channel effects, decreased capacitance for higher speed, and lower insertion loss if the device is acting as a switch. In addition, the insulating layer can act to reduce the effects on active devices from harmful radiation. This is particularly important for integrated circuits that are used in space given the prevalence of harmful ionizing radiation outside the earth's atmosphere.
SOI wafer 100 is shown in
SOI devices are imbued with the ability to enhance and preserve the electrical characteristics of their active devices as described above. However, the introduction of the insulator layer creates a significant problem in terms of the device's ability to dissipate heat. Due to the increasing miniaturization of the devices in integrated circuits, a greater number of heat generating devices must be pressed into a smaller and smaller area. In modern integrated circuits, the heat generation density of circuitry 104 can be extreme. The introduction of insulator layer 102 exacerbates this problem because the thermal conductivity of insulator layer 102 is generally much lower than that of a standard bulk substrate. As mentioned previously, silicon-dioxide is the ubiquitous insulator layer in modern SOI technology. At a temperature of 300 degrees Kelvin (K), silicon-dioxide has a thermal conductivity of roughly 1.4 Watts per meter per Kelvin (W/m*K). A bulk silicon substrate at the same temperature has a thermal conductivity of roughly 130 W/m*K. The nearly 100-fold reduction in heat dissipation performance exhibited by SOI technology is highly problematic. A high level of heat in an integrated circuit can shift the electrical characteristics of its devices outside an expected range causing critical design failures. Left unchecked, excess heat in a device can lead to permanent and critical failures in the form of warping or melting materials in the device's circuitry.
The problem of heat dissipation in SOI devices has been approached using variant solutions. One approach involves the deposition of heat channeling pillars from the insulator layer 102 up through active layer 103. In some cases, these heat channeling pillars are formed of metal since metal generally has a much higher thermal conductivity as compared to silicon-dioxide. In some approaches, these pillars are formed of polysilicon so that they do not interfere with the electrical performance of the circuit, while at the same time they provide a thermal path up and away from insulator layer 102. In other approaches, a hole is cut through insulator layer 102 and heat channeling pillars are deposited into the holes. The result of this configuration is to provide a thermal dissipation channel from active layer 103 through holes in insulator layer 102 down to substrate 101. This heat is then dissipated through substrate 101.
Another approach to the problem of heat dissipation in SOI devices involves operating on the wafer from the backside.
In one embodiment of the invention, a semiconductor structure is disclosed. The structure comprises a patterned layer consisting of an excavated region and a pattern region, a strain layer located in the excavated region and on the pattern region, an active layer located above the strain layer, a field effect transistor formed in the active layer, and a handle layer located above the active layer. The field effect transistor comprises a source, a drain, and a channel. The channel lies completely within a lateral extent of the pattern region. The source and the drain each lie only partially within the lateral extent of the pattern region. The strain layer alters a carrier mobility of the channel.
In another embodiment of the invention, another semiconductor structure is disclosed. The structure comprises an active layer bonded to a handle layer. The handle layer is on a first side of the active layer. The structure also comprises a patterned layer on a second side of the active layer. The pattern layer consists of an excavated region and a pattern region. The structure also comprises a strain layer located on the pattern region and in the excavated region. The strain layer exhibits a strain on a device in the active layer. The device is a field effect transistor having a source, a drain, and a channel, the channel being between the source and the drain. The pattern region fully encompasses the channel and only partially encompasses the source and the drain.
In another embodiment of the invention, another semiconductor structure is disclosed. The structure comprises an etched patterned layer formed on a back side of semiconductor structure, a strain layer formed on the etched patterned layer, a handle layer bonded to a front side of the semiconductor structure, an active layer located between the patterned layer and the handle layer, and a field effect transistor formed in the active layer. The field effect transistor comprises an active area. The field effect transistor comprises a channel. A portion of the etched patterned layer has a lateral extent beyond the channel. The field effect transistor has a lateral extent beyond the portion. The strain layer is in contact with the active area.
Reference now will be made in detail to embodiments of the disclosed invention, one or more examples of which are illustrated in the accompanying drawings. Each example is provided by way of explanation of the present technology, not as a limitation of the present technology. In fact, it will be apparent to those skilled in the art that modifications and variations can be made in the present technology without departing from the spirit and scope thereof. For instance, features illustrated or described as part of one embodiment may be used with another embodiment to yield a still further embodiment. Thus, it is intended that the present subject matter covers such modifications and variations as are within the scope of the appended claims and their equivalents.
Embodiments of the present invention provide for the production of SOI devices that have improved heat dissipation performance while preserving the beneficial electrical device characteristics that accompany SOI architectures. In addition, devices with the aforementioned benefits can be manufactured in accordance with the present invention with very little modification to manufacturing processes that are used most often in the semiconductor industry. This is a huge advantage given that compatibility with existing manufacturing processes avoids the need for the nearly insurmountable fixed production cost investments that can face novel semiconductor solutions. Embodiments of the invention achieve this result through the utilization of back side processing, the removal of portions of the SOI buried insulator layer, and the deposition of thermal dissipation layers in variant configurations on the back side of the SOI structure.
An SOI structure that is in accordance with the present invention can be described with reference to
Selecting a material for thermal dissipation layer 200 that is both electrically insulating and thermally conductive preserves the beneficial electrical characteristics provided by SOI technology while greatly diminishing the heat dissipation problems faced by traditional SOI devices using silicon-dioxide insulator layers. As an example, the thermal conductivity of pure synthetic diamond at 300 K is roughly 3,300 W/m*K and the thermal conductivity of beryllium oxide is 260 W/m*K. This is in comparison to the non-thermally conductive silicon-dioxide layer in a traditional SOI structure which—as mentioned previously—has a thermal conductivity of 1.4 W/m*K. As used herein and in the appended claims, a layer of material has high thermal conductivity if its thermal conductivity is greater than 50 W/m*K. Both diamond and beryllium-oxide provide a greater than 100-fold improvement in heat dissipation performance over the traditional SOI structure. In specific embodiments of the invention, insulator layer 102 is at least partially removed, and another very thin insulator layer is deposited before a layer of thermally conductive material is deposited to form thermally conductive layer 200. The extreme thinness of the insulating layer enhances the structure's ability to dissipate heat from active layer 103 to the thermally conductive material layer. For example, the deposited insulating layer can comprise a thin layer of the same material as the original insulator layer. The benefit of a thermally conductive and electrically nonconductive material is realized by the preservation of the electronic characteristics of active devices in active layer 103 without being limited by the poor heat dissipation characteristic of traditional SOI structures.
The structure displayed in
Another advantageous aspect of back side processing is that it allows for the addition of thermal dissipation layer 200 at a later stage of semiconductor processing, which in turn allows for the use of materials for thermal dissipation layer 200 that could not otherwise be applied. In contrast to traditional approaches, back side processing allows for the addition of thermal dissipation layer 200 after semiconductor processing of active layer 103 is complete. Certain phases of the semiconductor production process require temperatures in excess of 1000° C. Certain materials cannot withstand these temperatures and are therefore generally considered to be inadequate for usage as a thermal spreading layer located in place of thermal dissipation layer 200. However, the use of back side processing allows for the usage of more fragile materials for thermal dissipation layer 200.
An integrated circuit that is in accordance with the present invention can be described with reference to
The benefits and drawbacks of the removal of insulator layer 102 may be balanced by the formation of specific patterns for excavated insulator region 300. For example, excavated insulator region 300 may be made coextensive with a lowest layer of metal wiring in active layer 103. As shown in
Another semiconductor-on-insulator structure that is in accordance with the present invention can be described with reference to
In specific embodiments of the present invention, excavated insulator region 300 will be laterally coextensive with portions of the active devices in active layer 103. As shown in
In specific embodiments of the present invention, metal contact 404 is disposed in a first portion of excavated insulator region 300. Additionally, thermal dissipation layer 200 is disposed in a second portion of said excavated insulator region 300, and is also disposed on a side of metal contact 404. Such a configuration can be seen in
Any of the embodiments discussed above in regards to the use of excavated insulator region 300 to pattern the alignment of thermal dissipation layer 200 with portions of active layer 103 may be used independently or in combination. In addition, the pattern removal of insulator material to form excavated insulator region 300 can be combined with the patterned deposition of thermal dissipation layer 200. For example, thermal dissipation layer 200 could be disposed on the entire back side of the SOI structure, could only be disposed in excavated insulator region 300, or could be disposed in a portion of excavated insulator region 300. Methods of patterning thermal dissipation layer 200 are discussed below.
Embodiments of the invention where either the excavated insulator region 300 or additionally the thermal dissipation layer 200 are patterned exhibit advantageous characteristics. Although thermal dissipation layer 200 is electrically insulating there are certain advantages that accrue from leaving the original insulator material behind in certain regions. For example, it is possible for thermal dissipation layer 200 to comprise a material that is less electrically insulating than the original oxide. The material could be selected to minimize cost and maximize thermal conductivity in sacrifice of its electrically insulating capacity. In portions of active layer 103 where electrical conductivity was important, the original insulator could be left and excavated insulator region 300 could be located elsewhere. In this way, patterning allows for another degree of freedom in selecting an optimal material for thermal dissipation layer 200.
Patterning excavated insulator region 300 provides another benefit in that in can limit the creation of interface states in active layer 103. Even if thermal dissipation layer 200 is a good electrical insulator, the original insulator will generally be in better physical contact with active layer 103 because removal of the original insulator causes the creation of dangling bonds that will not be reconnected when thermal dissipation layer 200 is applied. This will result in the creation of interface states that can cause problems for circuitry in active layer 103. Patterning excavated insulator region 300 can advantageously limit the creation of these interface states in key areas of active layer 103 by allowing the original insulator to remain in contact with these key areas.
Another SOI structure that is in accordance with the present invention can be described with reference to
Another SOI structure that is in accordance with the present invention can be described with reference to
Methods of producing an integrated circuit that are in accordance with the present invention can be described with reference to
In specific embodiments of the present invention, the preparation of SOI wafer in step 700 is followed in step 701 by forming active circuitry in the active layer of the SOI wafer. The circuitry formed during this step and in this layer can include but is not limited to technologies such as CMOS, BiCMOS, SiGe, GaAs, InGaAs, and GaN. The circuitry can comprise: various active devices such as diodes and transistors; various passive devices such as resistors, capacitors, and inductors; and routing circuitry such as metal wires and vias. Various photolithographic and chemical deposition steps can be conducted to formulate this circuitry.
In specific embodiments of the invention, the formation of active circuitry in step 701 is followed by back side processing of the SOI wafer. In specific embodiments of the present invention, back side processing begins with the attachment or permanent bonding of a second handle wafer to the SOI wafer above the active layer in step 702. Processes used to induce a permanent bond to a handle wafer include permanent organic or inorganic adhesives, oxide frit bonding, galvanic bonding, molecular fusion bonding, any form of electromagnetic bonding, and other known methods for producing permanent wafer bonds.
Following the permanent bonding of the handle wafer to the SOI structure, the SOI wafer substrate can be removed in step 703. The substrate could be removed using mechanical and chemical means independently or in combination. For example, mechanical grinding can be used to thin the substrate material from an original thickness of approximately 800 micro-meters (pm) to approximately 20 μm. If the substrate is silicon, the final thickness of substrate material may be removed with a wet etch such as KOH or TMAH. The final thickness of substrate material may also be removed using a dry plasma etch. The substrate can be removed with a high precision or etch rate ratio. The etch rate ratio refers to the ratio of the rate of desired substrate material that was removed from the back of the wafer to the rate of additional material that was removed which should not have been removed. In specific embodiments of the invention, the insulator layer is a buried-oxide that acts as an etch stop since the etch rate ratio can be extremely high for the removal of all the substrate up to the buried oxide.
In specific embodiments of the present invention, the removal of the SOI substrate in step 703 is followed by additional back side processing that can formulate any of the structures disclosed previously. In a specific embodiment of the invention, removal of the SOI substrate is followed by removal of the SOI insulator layer to form an excavated insulator region in step 704. As mentioned previously, the insulator layer may be removed altogether, merely thinned overall and left thinner than its original thickness, or may be removed in such a way that the excavated insulator layer forms any of several patterns as described above. These patterns can be formed using standard photolithographic techniques or selective chemical vapor deposition. Thinning the insulator layer must be done carefully to avoid damaging the active layer. Although only a mono-layer—on the order of 1 nm—of insulator material is needed, thinning may be limited by the uniformity of the original insulator. For example, traditional methods for insulator removal would not be able to leave a final layer of less than 5 nm if the initial layer had variations of greater than 5 nm to begin with. Additionally, these patterns can be configured to capitalize on beneficial tradeoffs in the degree to which circuitry in the active layer is shielded and the degree to which the resultant SOI structure efficiently dissipates heat as described above.
In specific embodiments of the invention, the removal of insulator material from the back side of the SOI wafer in step 704 is followed by the deposition of a thermal dissipation layer on the back side of the SOI wafer in the excavated insulator region in step 705. The deposition of this thermal dissipation layer can be conducted so as to create any of the structures disclosed previously. This step could likewise follow immediately after the removal of substrate material. In addition, this step could be conducted during the deposition of metal contacts where—for example—metal contacts were disposed in two or more steps, or after the deposition of metal contacts if holes were later opened in the thermal dissipation layer to expose the metal contacts for electrical connections. The addition of this thermal dissipation layer in step 705 could be achieved through chemical vapor deposition, sputtering, or some other method. In addition, a patterned deposition of the thermal dissipation layer in accordance with previously disclosed structures could be achieved through the use of standard photolithography processing or selective chemical vapor deposition. As described above, in specific embodiments of the invention, the thermal dissipation layer deposited in this step will be electrically insulating and thermally conductive.
In specific embodiments of the invention, the deposition of a thermal dissipation layer on the back side of the SOI wafer in step 705 is followed by passivating the interface states on the back of the SOI wafer. In embodiments of the invention where the entire insulator is removed in step 704, this can be highly advantageous because the thermal dissipation layer deposited in step 705 will likely have a high interface state density. The deposited films tend to have very high interface state densities unless they are annealed out at high temperatures above 800° C. Since this temperature is higher than standard wafers can handle after active circuitry has been developed, high temperature annealing is not an option at this juncture. However, the interface states can be passivated using a low-temperature anneal. In specific embodiments of the invention, this low-temperature anneal will take place in a range of temperatures from 400-450° C. and will be accomplished in a hydrogen-containing atmosphere of either pure hydrogen gas or forming gas. Forming gas is a non-explosive N2 and H2 mixture. This passivation step may result in a thermal dissipation layer that is much thinner than could otherwise be achieved. For example, this layer could be 5 nm to 20 nm thick and have a uniformity of about +/−5% using conventional chemical vapor deposition equipment or sputtering equipment. This step would therefore allow the deposition of a very thin insulating layer and therefore very efficient thermal conduction from the active layer. In these embodiments, the thermal dissipation layer would comprise a layer of efficiently deployed insulator material that enhanced the thermal dissipation performance of the SOI structure. In specific embodiments of the invention, a layer of highly thermally conductive material is deposited on the back of this thin layer of insulator material and the thermal dissipation layer comprises both the thin insulator material layer and the thermally conductive material layer.
In specific embodiments of the invention, the removal of the entire insulator layer in step 704 can be followed by the deposition of a thin layer of the same insulator material that was removed in step 704 followed by the low temperature anneal passivation step described in the previous paragraph. For example, the removed insulator material could be silicon-dioxide and the deposited and low-temperature annealed material could also be silicon-dioxide. Silicon-dioxide is an advantageous material to use because it has low interface state characteristics. The reason silicon-dioxide would be removed and then deposited is that the process of deposition and low temperature annealing could create a more uniform and thinner layer of insulator material than can be achieved through the partial etch-back of the original layer using methods disclosed above.
In specific embodiments of the invention, the deposition of thermal dissipation layer on the back side of the SOI wafer in step 705 is followed by the removal of the thermal dissipation layer in selected areas to allow electrical contact to active circuitry in the active layer during subsequent processing. In one embodiment, the excavation of portions of the thermal dissipation layer may be located where regions of the lowest level of metal are present to expose that metal for electrical contact. Alternatively, the thermal dissipation layer may be selectively removed under active silicon regions to allow direct contact to active structures. In addition to the thermal dissipation layer, other dielectric layers may be required to be removed to expose various conductors for electrical contact. The removal of the thermally conductive layer may be selectively accomplished using the well-known means of photolithography and dry or wet etch using suitable chemistries.
In specific embodiments of the invention, the removal of areas of the thermal dissipation layer from the back side of the SOI wafer is followed by the deposition of metal contacts in step 706. These metal contacts are deposited in a first portion of the excavated insulator region formed in step 704 or step 705. The metal contacts are able to rapidly dissipate heat from the active circuitry. In specific embodiments of the invention, the metal contacts may provide both thermal channels for heat dissipation from active circuitry as well as contacts for signal or power connections to external devices. These metal contacts may comprise ball bonds, solder bumps, copper posts, or other die contact materials. The metal contacts could additionally be configured to attach to a circuit board, or a low-temperature co-fired ceramic substrate. The structure produced in this step will thereby have contacts to the SOI structure's active layer on the bottom side of the structure, which is the opposite orientation in standard SOI devices.
Methods of producing an integrated circuit that are in accordance with the present invention can be described with reference to
In specific embodiments of the present invention, deposition of the thermal dissipation layer in step 805 can be followed by the attachment or permanent bonding of a second, permanent handle wafer to the SOI structure below the active layer in step 806. The effect of this back side processing step is to alter the direction from which contacts can be made to active circuitry in the SOI structure. Once this second handle wafer is permanently bonded to the back side of the SOI wafer, the original handle wafer can be easily removed in step 807 due to the fact that it was bonded using a temporary and easily reversible process. Processes used to induce a permanent bond to a top side handle wafer include permanent organic adhesives, oxide frit bonding, galvanic bonding, molecular fusion bonding, any electromagnetic bonding method, and other known methods for producing permanent wafer bonds. Some bonding methods, such as molecular fusion bonding, may require a high degree of flatness to both surfaces being bonded. If the insulator material was selectively removed, that may introduce non-planarity to the surface of the wafer which makes bonding more difficult. In that case, chemical-mechanical polishing may be used to planarize the surface of the wafer prior to the bonding step to improve the efficacy of the bonding.
The structure produced in step 806 will have the SOI structure's active layer exposed on its top side and further processing can allow direct connection to active circuitry from the top side. The second, permanent, handle wafer that is bonded in step 806 can consist entirely of an electrically insulating, but thermally conducting material. In addition, the second handle wafer could consist of such a material disposed on a substrate material. This second configuration could save costs as the substrate material will provide the necessary stability to the final SOI device while not using as much of what may be a very costly thermally conductive material. It is possible for the thermally conductive material on the second, permanent, handle wafer to consist of the same material deposited to form the thermal dissipation layer in step 805. Alternatively, the permanent handle wafer that is bonded in step 806 can consist of a conductive material or a semiconductor material, such as silicon or high-resistivity silicon.
Embodiments of the present invention provide for the production of active devices in SOI structures having strain inducing materials in close contact to their channels. Embodiments of the present invention allow for the introduction of such strain inducing materials at a later stage in the device fabrication process than the usual stages at which strain inducing layers are applied. This allows for the increased effectiveness of the strain inducing layers while at the same time decreasing the risk of damage to the SOI structure during the intermittent manufacturing stages. In addition, devices with the aforementioned benefits can be manufactured in accordance with the present invention with very little modification to manufacturing processes that are used most often in the semiconductor industry. This is a huge advantage given that compatibility with existing manufacturing processes avoids the need for the nearly insurmountable fixed production costs investments that can face novel semiconductor solutions. Embodiments of the invention achieve this result through the utilization of back side processing, the possible removal of portions of the SOI insulator layer, and the deposition of strain inducing layers in variant configurations on the back side of the SOI structure.
The introduction of mechanical tensile or compressive strain in the material comprising the channel of an active device can increase the mobility of the charge carriers in such active device. In general, inducing tensile strain increases the mobility of electrons and inducing compressive strain increases the mobility of holes. An n-type active device, such as an n-type metal-oxide semiconductor (NMOS) will therefore be able to operate at a higher frequency if tensile strain is induce in its channel because the charge carriers in an NMOS device are electrons. Likewise, a p-type active device, such as a p-type metal-oxide semiconductor (PMOS) will be able to operate at a higher frequency if compressive strain is induced in its channel because the charge carriers in a PMOS device are electrons.
An SOI structure that is in accordance with the present invention can be described with reference to
The configuration illustrated in
In specific embodiments of the invention, the strain inducing layer is applied using lithography processes or other manufacturing methods—such as those discussed below with reference to FIG. 11—that allow for the patterned deposition of strain inducing layers.
In specific embodiments of the invention, a uniform strain inducing layer is applied to the bottom of the SOI structure during back side processing. These embodiments are of particular utility in situations where a specific-carrier-type active device predominates the circuitry in active layer 103. For example, if the active devices in active circuit layer 103 were predominately NMOS transistors, a uniform tensile strain layer could be applied to the back side of the SOI structure. Thereby, the NMOS transistors would be enhanced and the potential debilitating alteration in the mobility of carriers in any PMOS transistors would be outweighed by the benefits provided by the enhancement of the more numerous NMOS transistors.
In specific embodiments of the invention, the strain inducing layer or strain inducing layers are applied directly to the back of active layer 103. This is achieved by an additional back side processing step of removing insulator layer 102 before strain inducing layer 902 is deposited. These embodiments share the beneficial characteristic of allowing for deposition of the strain inducing layer at a later stage in the semiconductor device processing sequence. However, in these embodiments the strain inducing layer is even closer to active layer 103. Therefore, less overall stress is required which can enhance the electrical characteristics and yield of the resulting semiconductor device while still enhancing the mobility of charge carriers in the channels of its active devices. In specific embodiments of the invention, when strain inducing layer 902 is deposited directly on active layer 103, the strain inducing layer 902 is comprised of electrically insulating materials to preserve the beneficial characteristics of SOI structures. Materials that both induce strain and can act as electrical insulators include silicon nitride, aluminum nitride, silicon carbide, and diamond-like carbon.
In specific embodiments of the present invention, different patterns are applied to induce strain in active layer 103. These patterns can create bi-axial strain or uni-axial strain in a direction parallel or perpendicular to the flow of charge carriers. These patterns can be formed by the application of multiple at-least-partially vertically coextensive strain inducing layers as described above. Likewise, these patterns can be formed by the application of a strain inducing layer deposited in an excavated insulator region as described above. Variant patterns that can induce tensile or compressive strain can be described with reference to
An SOI structure that is in accordance with the present invention can be described with reference to
In specific embodiments of the invention, excavated insulator region 300 could be formed to only expose a subset of active devices in active layer 103. For example, excavated insulator region 300 is removed in a pattern which only exposes the channel of n-type devices such as NMOS 900 and a tensile strain inducing layer is then deposited on the back of the SOI structure. Likewise, in specific embodiments of the present invention, the polarity of the pattern and the strain type of the deposited material could be swapped as compared to the previous embodiment. In specific embodiments of the invention, the strain inducing layer underlying the remaining insulator region could be removed through an etching procedure. Although in these embodiments only one type of device will be strained this will still lead to advantageous performance, especially in designs that are more heavily performance-dependent on a certain type of semiconductor material.
In specific embodiments of the present invention the material in contact with the back side of the SOI structure that induces strain in the active devices can also serve as a thermal dissipation layer. As such, any thermal dissipation layers in the first section of this description could be replaced with a layer that additionally induces strain. In addition, combinations of this embodiment with those embodiments wherein the strain inducing layer is patterned to be in contact with sources of heat such as the channels of active devices produce advantageous results. In a specific embodiment, the strain inducing layer will be deposited on the channels of active devices and will serve as both a strain and thermal dissipation layer, and it will also isolate the device in the way that a standard insulator layer does for SOI devices. Materials that can provide all of these advantageous characteristics by being electrically isolating, thermally conductive, and strain inducing include aluminum nitride, silicon carbide, and diamond-like carbon. In a specific embodiment of the invention, insulator layer 102 can be completely removed and replaced with a patterned thermal spreading layer that can dissipate heat while at the same time providing a pattern for a strain inducing layer as described with reference to
Methods of producing an integrated circuit that are in accordance with the present invention can be described with reference to
In specific embodiments of the invention the removal of substrate material in step 1200 is followed by the removal of insulator material in step 1201. This removal can involve any of the methods discussed with reference to step 704 in
In specific embodiments of the invention, the insulator layer removal in step 1201 can remove the insulator material in certain patterns as described above. This can be followed by deposition of a strain layer in step 1203 so that the strain layer is deposited in an excavated insulator region formed in step 1201. For example, the insulator material could be removed only under those portions of the circuit on which a strain was meant to be induced such as only under the n-type devices. In that case the strain inducing layer would be tensile and only the n-type devices would be beneficial strained while the p-type devices were left in a nominal state. As another example, the insulator material could be left below the n-type device channels, and in a corresponding negative pattern below the p-type device channels so that a single strain inducing layer could produce both tensile and compressive strains on the active layer as needed. The patterned removal of insulator material in step 1201 could also be followed by step 1203 and 1205 in sequence to deposit different kinds of strain inducing layers in different portions of the excavated insulator region as described above.
In specific embodiments of the invention, the deposition of a strain inducing layer on the back side of the SOI structure in step 1203 is followed by the patterned removal of portions of the deposited strain inducing layer in step 1204. This step will therefore form an excavated strain layer region. In step 1205, a second strain layer is deposited on the back side of the SOI structure. As a result, this second strain layer will fill in the excavated strain layer region. In step 1206, the additional strain layer that did not fill in the excavated strain layer region can be removed to form an even back surface for the SOI structure. This approach has certain advantageous aspects as compared to other embodiments because only the removal of the strain layer in step 1204 needs to be patterned. The removal of the second strain layer in step 1206 can involve mechanical grinding to a uniform level or a controlled etch aided by a difference in the chemical compositions of the first and second strain layers. In addition, the actual deposition of strain inducing layers can be uniform in both steps 1203 and 1205. Considering the fact that some forms of deposition such as chemical vapor deposition are not always amenable to detailed lithographic patterning, this approach is advantageous in that it can achieve detailed patterning in a more efficient manner.
The relative configuration of the strain layers and the devices in the active layer 103 affects device performance. It was noted previously that the efficacy of the strain layer increases with the proximity of the strain layer to the active layer such that placing the strain layer on the back side of the wafer after layer transfer provides significant benefits over approaches in which the strain layer is overlain over the active devices from the top side. However, the interplay between the strain layer, the pattern on which the strain layer is deposited, and the active layer is influenced by numerous other factors than just the proximity of the active layer and the strain layer.
As the focus of the following disclosure is the relationship between the strain layer, pattern, and active layer, the materials providing the pattern will be referred to as “the patterned layer” despite the fact that the layer may be formed by multiple physical layers of material and can be formed using any of the methods described above. For example, as described above, the final back side strain layer can be deposited on a patterned layer that is itself deposited on the back of insulator layer 102, on a patterned layer that is deposited directly on the back of active layer 103 after insulator layer 102 has been removed, or on the back of insulator layer 102 after insulator layer 102 has been patterned or thinned. The patterned layer can be any appropriate thickness, width, or alignment relative to the active layer. In situations where the patterned layer includes additional material deposited on the back side of the device, the additional material can be a semiconductor, metal, or insulator material. As another specific example, the patterned layer could be formed using the methods described in commonly assigned U.S. patent application Ser. No. 14/453,595 which is incorporated by reference herein.
The following discussion of the relationship of the configuration and composition of the pattern layer and induced strain in the active devices applies to any of the patterns and strain layers discussed above with reference to
Additional conventions that will be useful for describing the relationship of the strain layer pattern and active layer can be described with reference to semiconductor structure cross section 1300 in
A salient feature of active layer 1301 in cross section 1300 is active device 1304. Active device 1304 can be a field effect transistor. Channel region 1306 can be flanked by a source and drain as shown. Notably, portion 1305 of patterned layer 1302 remains in place over the channel region 1306 of active device 1304 such that the channel region lies completely within a lateral extent of the patterned region. Channel region 1306 can extend into and out of the plane of cross section 1300 and can be a single finger of a multi-finger transistor. A cross section of each finger could be represented by cross section 1300. In such a situation, the patterned layer 1302 is overlaid with the gate of the transistor with identical location, length, and spacing along the fingers. The pattern of patterned layer 1302 could be inverted such that the excavated regions of patterned layer 1302 still contained patterned layer material and regions such as that occupied by portion 1305 would be excavated. As described above, such approaches would allow an opposite strain polarity to be exerted on active device 1304 with the same type of strain layer material 1303.
Dimension 1310 is of particular importance in terms of the interplay of the strain layer 1303 to the degree of strain delivered to the active device 1304. Edge effects that occur at the point where the pattern of the patterned layer 1302 transfers from an excavated to a patterned portion significantly decrease the strain induced in the active layer 1301 by strain layer 1303. Therefore, the point at which the pattern transitions needs to be kept outside of the channel region 1306, and dimensions 1310 should be nonzero. However, the benefit of placing these edge effects outside of channel region 1306 decrease asymptotically with an increase in dimension 1310. In addition, increasing dimension 1310 too much will diffuse the strain imparted by any given combination of a patterned layer and strain layer to both the channel and the source and drain regions of the device. Although strain that can beneficially effect the channel does not have any major deleterious effects on a localized level when it is applied to the source and drain of a device, the overall strain in the wafer can cause specific problems such that a more specific application of strain to the channel is usually desirable. Therefore, minimizing dimension 1310 to a reasonable level such as 0.25 μm is advisable.
The fact that the maxima in
As shown in chart 1601, increasing dimension 1311 provides a significant increase in the degree of strain delivered to channel 1306 of the active device 1304 up until roughly 25 μm on either side of the device. Notably, this effect is dependent upon the length of the channel, and the simulations used to generate chart 1601 assumed a device length of less than 1 μm. As dimension 1311 is increased, there is more area in which the strain layer can exert a differing force between the portions of active device 1304 that are covered by the patterned layer and those that are not. As a result, the strain in the active device increases. However, after a certain point, this effect exhausts itself as the increase in dimension 1311 has an effect that is too physically remote from channel 1306 to alter the strain therein. Also, dimension 1311 cannot be increased indefinitely without having a deleterious effect on the semiconductor structure as a whole. At a certain point, the effect of strain layer will being to have a wafer-wide effect and may start to cause bowing in the entire wafer which can lead to serious defects in the semiconductor device as a whole. In specific approaches, another strain layer can be added to the back side of the device to serve as a counter-strain layer. The counter-strain layer can exert an opposite strain force on the active layer as compared to the strain layer to cancel global wafer strain while maintaining the efficacy of the strain layer on a localized level. Regardless, it is beneficial to limit dimension 1311 to prevent globalized wafer strain from approaching problematic levels in the first place.
The simulations used to generate chart 1601 show a factor of 10 relationship between the length of channel 1306 and dimension 1311 as the point at which the advantage of increasing dimension 1311 significantly diminishes. Therefore, in some embodiments, for a channel length of less than 1 μm, dimension 1311 should be greater than 10 μm to adequately capture the benefits to the strain induced in the channel. However, dimension 1311 should be kept close to 10 μm so as to prevent wafer-wide warping.
Although embodiments of the invention have been discussed primarily with respect to specific embodiments thereof, other variations are possible. Various configurations of the described system may be used in place of, or in addition to, the configurations presented herein. For example, although the devices were discussed often with reference to silicon substrates and oxide insulator layers the invention will function with any form of semiconductor-on-insulator wafers, structures, or devices. For example, the invention will function in combination with silicon-on-sapphire structures. In addition, the invention can function or operate upon circuitry using any form of technology such as CMOS, bipolar, BiCMOS, SiGe, Ga, As, InGaAs, GaN and any other form of semiconductor technology or compound semiconductor technology. As mentioned above, the insulator layer does not need to be fully removed. The insulator layer could be left intact and a thermal dissipation layer, strain layer, or patterned layer could then be disposed on the surface of the insulator layer. In addition, the entire insulator layer can be thinned instead of being fully removed, or an excavated insulator region can be formed which contains a residual thinned insulator layer. In addition, multiple strain layers and pattern layers can be placed on the back side of the device to create different strain patterns and/or to counteract the induced strain of lower layers to limit the effect of global strain. In addition, there may be additional layers of materials disposed between those layers mentioned herein. Semiconductor processing is a highly detailed field, and layers were only mentioned herein if they were absolutely necessary to describe the invention to avoid confusion. For example, there may be layers of passivation disposed on the active layer to prevent the circuitry from reacting with its environment. In addition, the use of the word “layer” such as when describing an active layer or an insulator layer does not preclude such layers being comprised of more than one material. For example, there may be layers of glass or some other insulator below metal lines in active circuitry in addition to a silicon-dioxide insulator beneath the entire active layer of an SOI structure. However, the term insulator layer can cover the entire structure of the glass and silicon-dioxide insulator.
Those skilled in the art will appreciate that the foregoing description is by way of example only, and is not intended to limit the invention. Nothing in the disclosure should indicate that the invention is limited to systems that require a particular form of semiconductor processing or to integrated circuits. Functions may be performed by hardware or software, as desired. In general, any diagrams presented are only intended to indicate one possible configuration, and many variations are possible. Those skilled in the art will also appreciate that methods and systems consistent with the present invention are suitable for use in a wide range of applications encompassing any related to the dissipation of heat from electronic or photonic devices.
While the specification has been described in detail with respect to specific embodiments of the invention, it will be appreciated that those skilled in the art, upon attaining an understanding of the foregoing, may readily conceive of alterations to, variations of, and equivalents to these embodiments. These and other modifications and variations to the present invention may be practiced by those skilled in the art, without departing from the spirit and scope of the present invention, which is more particularly set forth in the appended claims.
This patent application is a continuation-in-part of U.S. application Ser. No. 12/836,559, filed Jul. 14, 2010, which claims the benefit of U.S. Provisional Application No. 61/225,914, filed Jul. 15, 2009, the contents of which are incorporated herein by reference.
Number | Date | Country | |
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61225914 | Jul 2009 | US |
Number | Date | Country | |
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Parent | 12836559 | Jul 2010 | US |
Child | 14540268 | US |