Patent Application
20220344240
The present disclosure relates generally to interconnect structures for electronic components, and more specifically to multilayer superconducting interconnect structures for use in electronic systems operating at deep cryogenic temperatures.
A typical electronic system is designed to operate at ambient or room temperatures, and includes electronic components integrated through circuit boards fabricated as a multilayer stack structure from dielectric layers and conductive layers. Electronic chips are mounted on either side of this multilayer stack structure and electrically interconnected through the conductive layers and conductive vias interconnecting these conductive layers. Cryogenic electronic systems operating at deep cryogenic temperatures (e.g., less than 10 Kelvin (10 K)) also require multilayer interconnect structures to electrically interconnect active and passive components forming the system. Deep cryogenic temperatures, however, present unique challenges to the configuration and fabrication of these multilayer interconnect structures and components attached to these structures.
In cryogenic electronic systems, the heat generated by the interconnect structures and components attached to these structures must be minimized. This is due to the sensitivity of active and passive components, such as superconducting and quantum devices, to temperature and the limitations and costs of providing cooling capacity to the system at deep cryogenic temperatures. The materials utilized in forming the interconnect structures for cryogenic systems are accordingly of critical importance. Superconducting materials are typically utilized for forming the conductive layers to reduce the joule heating generated in the conductive layers. Ideally, the interconnect structure also provides heat dissipation for components attached to this structure, but while this may be true for interconnect structures at room temperatures at deep cryogenic temperatures most materials experience a reduction in thermal conductivity as a function of temperature. Differences in the coefficient of thermal expansion (CTE) of different materials utilized in the interconnect structure may further limit suitable materials since such differences can result in mechanical stresses in the structure as temperature changes. All these limitations and requirements of interconnect structures in cryogenic systems make the design and fabrication of these structures difficult, and improved interconnect structures are accordingly needed.
In the drawings, which are not necessarily drawn to scale, like numerals may describe similar components in different views. Like numerals having different letter suffixes may represent different instances of similar components. The drawings illustrate generally, by way of example, but not by way of limitation, various embodiments discussed in the present document.
In the following description, for purposes of explanation, numerous examples and specific details are set forth in order to provide a thorough understanding of the present disclosure. It will be evident, however, to one skilled in the art that the present disclosure as expressed in the claims may include some or all of the features in these examples, alone or in combination with other features described below, and may further include modifications and equivalents of the features and concepts described herein.
Further, spatially relative terms, such as “beneath,” “below,” “lower,” “above,” “upper”, “on,” “over” and the like, may be used herein for ease of description to describe one element or feature in relation to another element or feature as illustrated in the figures. The spatially relative terms are intended to encompass different orientations of the described structures in use or operation in addition to the orientation depicted in the figures. The structures may be otherwise oriented, such as through a 90-degree rotation or at other orientations, and the spatially relative descriptors used herein may likewise be interpreted accordingly depending on the particular orientation.
In the cryogenic multilayer interconnect structure 100, the CTE of the molybdenum substrate 102 at room temperature, which is approximately 5 ppm/K in some embodiments, is a good match with the CTE of cryogenic electronic chips to be attached to the interconnect structure. As will be appreciated by those skilled in the art, a mismatch in the CTE of two different materials attached to one another may result in mechanical stresses being generated between the two materials as the materials experience a temperature change. These mechanical stresses result from forces generated between the two materials due to different rates of expansion as a function of temperature. These forces may include lateral forces in a plane of the two materials as well as forces normal to the planes of the materials and may damage the interconnection of the two materials. For example, a conventional circuit board may be formed from a woven glass and epoxy resin structure known as FR4, which has CTE at room temperature on the order of 14 ppm/K. Where a cryogenic electronic chip is a silicon-based chip, meaning the chip is formed in a silicon substrate, the CTE of this silicon substrate has a CTE on the order of 2.56 ppm/K. As a result, when such a silicon chip is attached to an FR4 based circuit board mechanical stresses between the circuit board and the chip can arise as the structure undergoes a temperature change and these stresses may cause warping, disconnection, or other damage to the structure.
In the interconnect structure 100, the molybdenum substrate 102 has a CTE that provides a good match to the materials in which cryogenic electronic chips to be attached to the structure are typically formed. For example, the molybdenum substrate 102 has a CTE that is a good match with the CTEs of cryogenic electronic chips including substrates of silicon, sapphire, and compound semiconductor substrates. Thus, utilization of the interconnect structure 100 in cryogenic applications improves the reliability of the system by reducing the likelihood of damage to components in the system as these components undergo temperature changes in the range from room temperature (i.e., 20° C. or 293 K) to deep cryogenic temperatures (i.e., less than 10 K). In one embodiment, the molybdenum layer forming the substrate 102 is a high purity molybdenum layer having a purity greater than 99.95%. This high purity of the molybdenum substrate 102 ensures the substrate has a CTE of a desired value and that is a good match with the CTE of cryogenic electronic chips to be attached to the substrate.
The multilayered molybdenum substrate 202A has a structure that enables a controlled CTE to be provided, and also has improved thermal conductivity characteristics through inclusion of the copper layers 206A, 208A. The characteristics of the molybdenum layer 204A and the copper layers 206A, 208A may be adjusted to provide the multilayered molybdenum substrate 202A having desired CTE and thermal conductivity characteristics. More specifically, each of the molybdenum layer 204A, first copper layer 206A and second copper layer 208A has a corresponding thickness in the vertical direction, as illustrated through a thickness T shown for the molybdenum layer 204A in
As used in the present description, the terms “matched” and “good match” mean the CTEs of the molybdenum substrates 102 and 202A, and other molybdenum substrates described herein according to further embodiments, are compatible with electronic components such as cryogenic electronic chips to be attached to the substrates. The CTE of each substrate 102, 202A provides a compatible CTE between the substrate and the cryogenic electronic chips attached to the substrate so that significant mechanical stresses are not generated between the two as the structure experiences a temperature change from room temperature to deep cryogenic temperatures.
In embodiments of the cryogenic multilayer interconnect structure 200A, the multilayered molybdenum substrate 202A is a copper clad molybdenum substrate (i.e., first and second conductive layers 206A, 208A are copper layers) and the characteristics of these layers are controlled to provide a coefficient of thermal expansion at room temperature of 5-8 ppm/K. This is a significantly lower CTE than other common conventional substrates such as an FR4 structure (14 ppm/K), a copper Cu structure (17 ppm/K) and an aluminum Al structure (24 ppm/K). A lower CTE is advantageous, for example, when silicon cryogenic electronic chips (i.e., chips having components formed in silicon) are to be attached, with silicon having a CTE at room temperature in the range of 2.56 ppm/K. The copper clad molybdenum substrate 202A having a CTE at room temperature of 5-8 ppm/K is much closer to the silicon CTE at room temperature in the range of 2.58 ppm/K. In this way the CTE of the copper clad multilayered molybdenum substrate 202A is said to be matched to the CTE of cryogenic electronic chips (i.e., silicon chips in this example) to be attached to the substrate.
In addition to the controlled CTE characteristics as described above, the multilayered molybdenum substrate 202A also advantageously allows the thermal conductivity of the substrate to be controlled. The purity of both the molybdenum layer 204A and the conductive layers 206A, 208A are necessary to achieve high thermal conductivity values for the substrate 202A at deep cryogenic temperatures. As mentioned above, the most suitable materials for thermal conduction at deep cryogenic temperatures are pure metals, such as aluminum (Al) and copper (Cu).
Where the conductive layers 206A, 208A are copper layers the lateral thermal conductivity of the substrate 202A is increased by an order of magnitude or more from approximately 60 W/mK for a pure molybdenum (Mo) substrate to approximately 1000 W/mK at 4.2 K where the substrate 202A is an approximately 20% Cu/60% Mo/20% Cu stack or multilayered structure, where the percentages indicate percentage thicknesses of the respective layers. As mentioned above, varying the thicknesses and the ratio of copper to molybdenum (Cu/Mo) (i.e., the ratio of the thickness of each Cu layer to the thickness of the Mo layer) allows for fine tuning the CTE and thermal conductivity values of the substrate 202A. The selection of the CTE and thermal conductivity values requires a tradeoff in that these parameters are mutually exclusive. Thus, if more copper is added to the substrate 202A (i.e., the thicknesses of the copper layers 206A, 208A are increased) to improve the thermal conductivity of the substrate, the CTE of the substrate will undesirably increase. Conversely, if less copper is added to the substrate 202A (i.e., the thicknesses of the copper layers 206A, 208A are decreased) then the CTE of the substrate will decrease but the thermal conductivity of the substrate will also undesirably decrease. In one embodiment, the multilayer molybdenum substrate 202A is a copper clad structure (layers 206A, 208A are copper) with each of these copper layers having a purity greater than 99.995% and the molybdenum layer 204A is a high purity molybdenum layer having a purity greater than 99.95%.
Different superconducting materials may be utilized in further embodiments of cryogenic multilayer interconnect structures according to the present disclosure. For example, in the cryogenic multilayer interconnect structures 100 and 200A of
A second superconducting layer 416 is formed on the second insulating layer 414 and patterned as required to form portions of the second superconducting layer utilized in the formation of the overall interconnect structure 400. In the example of
A first transmission line having an impedance of 1 ohm and a width of 400 micrometers (μm) is formed in superconducting layer 706 along with a second transmission line having an impedance of 20 ohms and a width of 17 μm. The superconducting layer 708 on the left includes a transmission line having an impedance of 50 ohms and a width of 10 μm and is coupled through vias on the right to the superconducting layer 710 which includes on the right a transmission line having an impedance of 20 ohms and a width of 17 μm. A transmission line having an impedance of 50 ohms and a width of 17 μm is formed in the uppermost superconducting layer 712 along with a ground plane portion on the right to which a conductive bump 716 and contact pad 714 extending through polyimide layer PL6 are coupled. In the interconnect structure 700 the molybdenum substrate 702 has a low CTE at room temperature and is thus advantageously utilized in cryogenic applications. The molybdenum substrate 702 will, however, has a moderate thermal conductivity at deep cryogenic temperatures and will accordingly not dissipate as much heat as in embodiments where the substrate includes a high thermal conductivity cladding layers, such as copper cladding layers, as discussed above in relation to the embodiments of
In
In the method of
Interconnect structures according to embodiments of the present disclosure as illustrated in
In various embodiments, the present disclosure includes systems, methods, and apparatuses for resilient data storage. The following techniques may be embodied alone or in different combinations and may further be embodied with other techniques described herein.
In one embodiment, a cryogenic multilayer interconnect structure comprises: a substrate including a molybdenum layer; a first insulating layer on the substrate; and a first superconducting layer on the first insulating layer.
In one embodiment of the cryogenic multilayer interconnect structure, the substrate includes only the molybdenum layer.
In one embodiment of the cryogenic multilayer interconnect structure, the molybdenum layer comprises a first molybdenum layer and a second molybdenum layer, and wherein the substrate further comprises a copper layer between the first molybdenum layer and the second molybdenum layer.
In one embodiment of the cryogenic multilayer interconnect structure, the first insulating layer comprises a polymer dielectric layer.
In one embodiment of the cryogenic multilayer interconnect structure, the polymer dielectric layer is one of a polyimide (Pl) layer, a polybenzoxazole (PBO) layer, and a benzocyclobuten (BCB) layer.
In one embodiment of the cryogenic multilayer interconnect structure, the first superconducting layer comprises a material selected from the group consisting of niobium (Nb), niobium nitride (NbN), niobium titanium nitride (NbTiN), titanium nitride (TiN), and aluminum (Al), and combinations thereof.
In one embodiment of the cryogenic multilayer interconnect structure, the substrate further comprises a first copper layer and a second copper layer with the molybdenum layer between the first copper layer and the second copper layer.
In one embodiment of the cryogenic multilayer interconnect structure, each of the first copper layer and the second copper layer has a purity greater than 99.995% and wherein the molybdenum layer is a high purity molybdenum layer having a purity greater than 99.95%.
In one embodiment of the cryogenic multilayer interconnect structure, each of the first copper layer, second copper layer, and molybdenum layer has a corresponding thickness, and wherein each of these thicknesses has a value selected to provide a desired thermal conductivity and to provide a compatible coefficient of thermal expansion between the substrate and electronic components to be attached to the substrate.
In one embodiment of the cryogenic multilayer interconnect structure, the substrate includes the first copper layer, molybdenum layer, and second copper layer has a coefficient of thermal expansion at room temperature of 5-8 ppm/K.
In one embodiment of the cryogenic multilayer interconnect structure, the substrate includes the first copper layer, molybdenum layer, and second copper layer is approximately 20% Cu/60% Mo/20% Cu stack, wherein the percentages indicate percentage thicknesses of the respective layers.
In one embodiment of the cryogenic multilayer interconnect structure, the substrate has a lateral thermal conductivity of 1000 W/mK at 4.2K.
In another embodiment, a cryogenic multilayer interconnect structure, comprises: a copper clad molybdenum substrate; a first dielectric layer on the copper clad molybdenum substrate; a first superconducting layer on the first dielectric layer; and electronic components configured to operate at cryogenic temperatures coupled to the first superconducting layer.
In one embodiment of the a cryogenic multilayer interconnect structure, the copper clad molybdenum substrate includes a molybdenum layer between first and second copper layers, and wherein each of the first and second copper layers and molybdenum layer has a corresponding thickness and each of these thicknesses has a value selected to provide a desired lateral thermal conductivity of the substrate and to provide a coefficient of thermal expansion of the substrate that is compatible with electronic components to be attached to the substrate.
In another embodiment, a method of forming a cryogenic multilayer interconnect structure, comprises: forming a first insulating layer over a first copper layer of a copper clad molybdenum substrate including the first copper layer and a second copper layer; forming a first superconducting layer over the first insulating layer; patterning the first superconducting layer; forming a second insulating layer over the first superconducting layer; forming openings in the second insulating layer to expose portions of the first superconducting layer; forming a second superconducting layer over the second insulating layer and in the openings to form vias in the openings that interconnect the first and second superconducting layers; and patterning the second superconducting layer.
In one embodiment of the method, forming the first insulating layer and forming the second insulating layer comprise depositing layers of one or more insulating material on the first copper layer and first superconducting layer.
In one embodiment of the method, depositing layers of one or more insulating material comprises spin coating the one or more insulating material on the first copper layer and the first superconducting layer.
In one embodiment of the method, the one or more insulating material is one of a polyimide (Pl) material, a polybenzoxazole (PBO) material, and a benzocyclobuten (BCB) material.
In one embodiment of the method, forming the first superconducting layer and the second superconducting layer comprise depositing a superconducting material on the first insulating layer and the second insulating layer, respectively.
In one embodiment of the method, depositing the superconductor material comprises sputtering or evaporation of the superconducting material.
In one embodiment of the method, the superconductor material comprises one of niobium (Nb) and a superconducting material including titanium (Ti).
In one embodiment of the method, patterning the first superconducting layer and the second superconducting layer comprises etching the first and second superconducting layers.
In one embodiment of the method, the method further comprises forming additional superconducting layers on additional insulating layers, and wherein the method further comprises forming conductive bumps on contact pads formed in one of the superconducting layers.
The various features and processes described above may be used independently of one another or may be combined in various ways. All possible combinations and subcombinations are intended to fall within the scope of this disclosure. In addition, certain method or process blocks may be omitted in some implementations. The methods and processes described herein are also not limited to any particular sequence, and the blocks or states relating thereto can be performed in other sequences that are appropriate. For example, described blocks or states may be performed in an order other than that specifically disclosed, or multiple blocks or states may be combined in a single block or state. The example blocks or states may be performed in serial, in parallel, or in some other manner. Blocks or states may be added to or removed from the disclosed example embodiments. The example systems and components described herein may be configured differently than described. For example, elements may be added to, removed from, or rearranged compared to the disclosed example embodiments.
Conditional language used herein, such as, among others, “can,” “could,” “might,” “may,” and the like, unless specifically stated otherwise, or otherwise understood within the context as used, is generally intended to convey that certain embodiments include, while other embodiments do not include, certain features, elements, and/or steps. Thus, such conditional language is not generally intended to imply that features, elements and/or steps are in any way required for one or more embodiments or are to be performed in any particular embodiment. The terms “comprising,” “including,” “having,” and the like are synonymous and are used inclusively, in an open-ended fashion, and do not exclude additional elements, features, acts, operations, and so forth. Also, the term “or” is used in its inclusive sense (and not in its exclusive sense) so that when used, for example, to connect a list of elements, the term “or” means one, some, or all of the elements in the list.
The above description illustrates various embodiments of the present disclosure along with examples of how aspects of the particular embodiments may be implemented. The above examples should not be deemed to be the only embodiments, and are presented to illustrate the flexibility and advantages of the particular embodiments as defined by the following claims. Based on the above disclosure and the following claims, other arrangements, embodiments, implementations and equivalents may be employed without departing from the scope of the present disclosure as defined by the claims.
