WO2006086337A1 - A low temperature method for fabricating high-aspect ratio vias and devices fabricated by said method - Google Patents

A low temperature method for fabricating high-aspect ratio vias and devices fabricated by said method Download PDF

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Publication number
WO2006086337A1
WO2006086337A1 PCT/US2006/004176 US2006004176W WO2006086337A1 WO 2006086337 A1 WO2006086337 A1 WO 2006086337A1 US 2006004176 W US2006004176 W US 2006004176W WO 2006086337 A1 WO2006086337 A1 WO 2006086337A1
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WO
WIPO (PCT)
Prior art keywords
substrate
conductive
solution
cavities
vias
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PCT/US2006/004176
Other languages
French (fr)
Inventor
Robert L. Borwick
Philip A. Stupar
Jeffrey F. De Natale
Chialun Tsai
Zhimin J. Yao
Kathleen Garrett
John White
Leslie Warren
Morgan Tench
Original Assignee
Rockwell Scientific Licensing, Llc
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Priority claimed from US11/167,014 external-priority patent/US7538032B2/en
Application filed by Rockwell Scientific Licensing, Llc filed Critical Rockwell Scientific Licensing, Llc
Publication of WO2006086337A1 publication Critical patent/WO2006086337A1/en

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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/70Manufacture or treatment of devices consisting of a plurality of solid state components formed in or on a common substrate or of parts thereof; Manufacture of integrated circuit devices or of parts thereof
    • H01L21/71Manufacture of specific parts of devices defined in group H01L21/70
    • H01L21/768Applying interconnections to be used for carrying current between separate components within a device comprising conductors and dielectrics
    • H01L21/76898Applying interconnections to be used for carrying current between separate components within a device comprising conductors and dielectrics formed through a semiconductor substrate
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L23/00Details of semiconductor or other solid state devices
    • H01L23/48Arrangements for conducting electric current to or from the solid state body in operation, e.g. leads, terminal arrangements ; Selection of materials therefor
    • H01L23/481Internal lead connections, e.g. via connections, feedthrough structures
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2924/00Indexing scheme for arrangements or methods for connecting or disconnecting semiconductor or solid-state bodies as covered by H01L24/00
    • H01L2924/0001Technical content checked by a classifier
    • H01L2924/0002Not covered by any one of groups H01L24/00, H01L24/00 and H01L2224/00

Definitions

  • This invention is directed to a method for fabricating high-aspect ratio through- wafer vias.
  • embodiments of the invention are directed to methods for the low temperature fabrication of through-wafer vias having small diameters.
  • the invention is also directed to devices fabricated using such methods.
  • some techniques stack, bond and thin multiple wafers into a 'single' wafer and form the vias through only a single thin layer of the stacked wafers at a time, thereby reducing the aspect ratio and diameter required of an individual via.
  • This approach involves wafer thinning to reduce the required etch depth, and hence enable smaller via diameters to be achieved.
  • two wafers to be stacked are bonded and one portion (top or bottom) of the stacked wafers is thinned.
  • the thinning requires a significantly reduced thickness of the wafer (typically 10-25 ⁇ m). At this thickness, vias can be etched through the thinned layer while maintaining small diameter and small separation between neighboring vias.
  • the via could be etched to a limited depth prior to the bonding, and then its bottom surface exposed in the thinning operation after bonding.
  • the reduced layer thickness is necessary due to the aspect ratio limitations of the etch process.
  • the advantages of this approach include the ability to use well-developed fabrication processes. However, disadvantages arise from the need for sequential processing of each successive layer and the complexity of intermediate testing. Further, although this allows for via depth greater than one wafer, the thinning of the stacked wafers reduces their integrity and makes them more susceptible to breakage during use and damage from handling. Further still, many current bonding techniques involve high temperatures, high voltage and/or high pressure. Each of these poses difficulties if the stacking includes prefabricated integrated circuits with multi-level interconnects as the process could damage the circuitry.
  • Embodiments of the present invention are directed to a method for forming small diameter vias at low temperatures, and devices fabricated using such methods.
  • through-substrate vias are fabricated by forming a through- substrate via hole; forming an insulated layer on the interior surface of the via; and depositing conductive material into the via by means of a flowing solution plating technique.
  • the flow of this solution may be facilitated by the use of plating chemistries wherein the plating reaction releases a gas that pushes the conductive material solution through the via to facilitate plating the via with the conductive material, hi preferred embodiments, the fabrication of the substrate is conducted at low temperatures.
  • the substrate fabricated by using such methods has first and second surfaces, comprising a first plurality of substantially cylindrical cavities formed into the first surface to first depths and having first diameters; a second plurality of substantially cylindrical cavities formed into the second surface to second depths greater than said first depths and having second diameters greater than said first diameters; and said first and second plurality of cavities being coated with an insualting layer and a conductive material and being mutually aligned to form a plurality of continuous conductive vias through said substrate.
  • a feature of embodiments of the invention is the formation of small diameter through-substrate vias.
  • An advantage of this feature is that a higher density of vias can oe rorme ⁇ on a single suDstrate, tnus allowing more circuitry to be included on a single substrate.
  • a further feature of embodiments of the invention is that the through-substrate vias can be fabricated at low temperatures. An advantage to this feature is that the formation of the vias does not damage circuitry contained within the substrate. [0014] A still further feature of embodiments of the invention is that the activation of the isolation layer provides for conformal layers of conductive material. An advantage to this feature is that the substrate is uniformly coated with conductive material which enhances the performance of the chips.
  • Another feature of embodiments of the invention is that it provides a method for forming small-diameter, fine-pitch vias in relatively thick substrates to enable parallel layer processing, known-good-die testing, and either die-level or wafer-level assembly.
  • An advantage to this feature is that the use of a thicker wafer maintains the mechanical integrity of the wafer to minimize breakage during processing and use.
  • a further advantage to this feature is that it avoids the need for sequential bonding and thinning operations and offers capabilities not possible in conventional technologies.
  • Figure 1 is a block diagram of a process for forming high aspect ratio, through- wafer vias in accordance with an embodiment of the invention.
  • Figure 2 is a schematic of the process for forming high aspect ratio, through- wafer vias in accordance with the embodiment of Figure 1.
  • Figure 3 is an enlarged cross-sectional view of the etched vias formed in accordance with the process of Figure 1.
  • Figure 4 is a schematic of the etching process to form the vias in accordance with the embodiment of Figure 1.
  • IJ Figure 5 is a photomicrograph of a portion of the isolation layers formed during the deposition of the materials onto the wafer which have been exposed by removing the surrounding wafer material.
  • Embodiments of the present invention are directed to a process for fabricating high aspect ratio through-wafer vias at low temperatures.
  • the fabrication process produces high performance silicon chips or CMOS assemblies having high density via interconnects.
  • a first cavity is etched into the first surface of a wafer 10.
  • a second cavity is etched into the second surface of the wafer 12.
  • a first material is deposited onto the wafer such that it uniformly coats the wafer 14, including uniformly coating the interior walls of the cavities.
  • a second material is deposited onto the wafer such that the second material uniformly coats the wafer 16, including the interior walls of the cavity.
  • the wafer 20 also referred to as a substrate, comprises a first surface 24, a second surface 26 and a depth d.
  • the circuitry is disposed in a first portion of the wafer 27 nearer the second surface than the first surface.
  • the circuitry will depend, of course, on the purpose of the final product.
  • the wafer is made from silicon.
  • the wafer can be formed from any suitable material, including, but not limited to, gallium arsenide or indium phosphate.
  • Figure 2 depicts a series of cross-sectional views of the wafer during various stages of the overall process generally described in Figure 1.
  • alignment marks 30 are etched on the first 24 and second 26 surface of the wafer 20.
  • the alignment marks facilitates alignment of the wafer during the creation of different layers to ensure proper formation of the chip.
  • a first cavity 32 is etched into the first surface 24.
  • the first cavity also known as a via, has a first diameter 34, and extends a first depth 36 into the wafer 20.
  • the first cavity has a diameter of 4 ⁇ m and extends to a first depth between 50 ⁇ m - 80 ⁇ m.
  • the first diameter 34 can range between 0.5 ⁇ m - 300 ⁇ m, and the first cavity can extend to a first depth between 10 ⁇ m - 200 ⁇ m. Generally, the first depth 36 does not extend laterally into the portion of the wafer 27 containing the circuitry, and will extend in depth to below the portion of the wafer containing active circuitry.
  • a second cavity 38 also known as a via, having a second diameter 40, is etched coaxially with the first cavity 32 into the second surface 26 of the wafer and extends a second depth 42 into the wafer 20.
  • the second cavity 38 has a diameter of 8 ⁇ m to 20 ⁇ m and extends to a second depth of 200 ⁇ m.
  • the second diameter 40 can range from .5 ⁇ m to 300 ⁇ m, and the second cavity can extend to a second depth ranging from 50 ⁇ m - 1500 ⁇ m.
  • the second cavity 38 is etched to a second depth such that it communicates with the first cavity 32 to form a continuous aperture 39 through the entire thickness of the wafer.
  • Figure 3 depicts a cross section of the continuous aperture 39 formed by the first cavity 32 and the second cavity 38.
  • Embodiments of the invention produce high aspect ratio first and second cavities having small diameters.
  • the high aspect ratio cavities are achieved via an etching process known as the Bosch process for Deep Reactive Ion Etching ("DRIE") in Si, • although any etching process which can produce high aspect ratio, small diameter cavities would also be suitable.
  • DRIE Deep Reactive Ion Etching
  • the DRIE process utilizes alternating etch and passivation steps.
  • an etchant such as, sulfur hexafluoride SF 6 is used to etch a portion of the cavity into the wafer.
  • an insulating layer is subsequently deposited using a separate gas composition, including species such as octafluorocyclobutane C 4 F 8 .
  • the process then repeats until the desired depth is achieved.
  • the etching process is conducted at temperatures below 100 °C.
  • the etching process is conducted at temperatures below 400 0 C. As discussed above, low temperatures are any temperatures that do not damage the existing circuitry.
  • Etching via the Bosch process allows for etching with high selectivity and achieves substantially vertical side walls. Indeed, the Bosch process produces a high aspect ratio via of 40: 1. This high aspect ratio facilitates the production of smaller diameter cavities as it reduces the amount of lateral blooming during etching and reduces side wall scalloping.
  • a first material 44 is deposited onto the wafer.
  • the first material 44 is a dielectric or a non-electrically conductive material, such as parylene, silicone dioxide derived from precursors such as tetra-ethyl ortho silicate ("TEOS"), aluminum oxide or other inorganic oxides or insulating organic films.
  • TEOS tetra-ethyl ortho silicate
  • the first material 44 forms an isolation layer that is conformal and uniformly covers the sidewalls of the cavities. The uniform coverage of the sidewalls with the first material 44, or isolation layer, electrically isolates the cavities from the substrate and from the other cavities.
  • the first material 44 is deposited via vapor-deposition.
  • the vapor- deposition is conducted at temperatures below room temperature, for example, below 25 0 C, although temperatures between 2O 0 C and 200 0 C are also suitable.
  • the first material is parlyene. Parylene vapor-deposition is conformal and thus, produces uniform coverage of the wafer, including the interior walls of the small diameter cavities. The achievement of uniform, conformal coverage by the parylene vapor-deposition has been confirmed in deep cavities, for example, cavities ranging from 350-450 ⁇ m.
  • Figure 5 depicts a portion of a dissolved wafer which exposes the cavity shells formed from parylene. As illustrated in Figure 5, the shape of the cavity shell is fully formed and evinces the coverage of the parylene throughout the interior of the cavity of a given depth.
  • ALD atomic layer deposition
  • PECVD TEOS plasma enhanced chemical vapor deposition tetraethyl silicon dioxide
  • Bosch passivation coating As these techniques are well known to those skilled in the art, a detailed discussion regarding these techniques will not be set forth.
  • a second material 46 comprising an electrically conductive material, is deposited onto the first material 44.
  • the first material 44 is activated prior to the deposition of the second material 46.
  • the first material 44 is activated prior to the deposition of the second material 46.
  • Activating the first material for example, an isolation layer, makes the first material more conducive to receive the second material 46.
  • the second material 46 is deposited onto the activated first material 44.
  • the second material 46 uniformly covers the wafer, including the interior walls of the cavities, and metallizes the wafer.
  • the parylene is activated via the application of an oxygen plasma.
  • the parylene is exposed to the oxygen plasma for approximately 3-5 minutes.
  • the exposure to the oxygen plasma roughens the surface of the parlyene and causes hydrophobic surfaces to become hydrophilic.
  • the transformation of the surface from hydrophobic to hydrophilic causes the surface to become a wetable surface that will spread aqueous materials applied to the surface and uniformly coat the surface with the applied materials.
  • the application of the second material 46 to the activated parylene surface will cause the second material to spread and uniformly coat the wafer, including the interior walls of the cavities, hi some embodiments, the second material completely fills the cavities as illustrated in Figure 2.
  • Activation by other suitable plasmas may also be used, including, but not limited to, an argon plasma.
  • activation of the isolation layer is achieved by the application of a seed layer that causes a reaction with the second material 46 when it is applied to the wafer.
  • a seed layer that causes a reaction with the second material 46 when it is applied to the wafer.
  • a two-part tin-palladium (Sn/Pd) technique is used to deposit a seed layer onto the first material.
  • the seed layer facilitates plating of the metal conductor (such as nickel) onto the insulating material.
  • tin is adsorbed on the parylene by bathing the wafer with the parylene in a solution of stannous chloride (tin) and hydrochloric acid.
  • the 94- solution causes the tin ions Sn to be adsorbed onto the surface of the insulator, e.g., parylene.
  • the wafer is bathed in a solution of palladium chloride and hydrochloric acid which reduces the solution and causes the deposition of palladium on the surface.
  • the reduced solution leaves a monolayer of palladium on the tin.
  • the second material 46 such as nickel, will react with the monolayer of palladium and plate the wafer.
  • Other techniques for applying a seed layer can be used and are well known by those skilled in the art.
  • the seed layer can be applied using a solution containing a metal acetate.
  • a solution containing a metal acetate, such as palladium acetate is bathed over the substrate and through the vias to cause coating on the interior surfaces of the vias.
  • the application of heat to the coating causes the deposition of a thin metal layer on the interior surface of the vias.
  • the above described seed deposition and plating techniques can be applied in the plating of any structure, for example, a circuit board, and is not limited to the plating of vias and wafers.
  • the second material 46 is deposited on the activated first material.
  • Various techniques can be used to deposit the second material 44. However, for effective metallization of the cavities, it is preferable for the second material 46 to be deposited uniformly, including uniform deposition into the cavities. In preferred embodiments, flowing solution plating techniques are used. For instance, in one embodiment, an electroless deposition process is used to deposit the second material 46.
  • the second material 46 is nickel, but other materials may be used. The wafer is bathed in a nickel solution such that the nickel flows over the wafer and fills the cavities.
  • the nickel solution reacts with the activated parylene and causes the release of hydrogen.
  • the release of the hydrogen pushes the nickel - through the cavities and allows the cavities to remain clear, thereby allowing the nickel to plate the entire cavity through the wafer despite the small diameters.
  • the process is complete when hydrogen is no longer released.
  • the nickel plating is performed at 85 0 C.
  • Other flowing solution techniques can also be used where the solution flow is created by other sources. For instance, the flow of the solution can be created by a mechanical agitation of the solution, or pressurization of the solution.
  • the deposition of the second material can include, but is not limited to, chemical vapor deposition and atomic layer deposition techniques to deposit conductive materials (which may include metals, ceramics, or polymers).
  • conductive materials which may include metals, ceramics, or polymers.
  • any final connections required to be made via interconnects formed by the cavities are completed and the wafers are then ready for use.
  • embodiments of this invention can be combined with other circuit chips and systems.
  • embodiments of the invention can be used for compact electronic circuits with multiple stacking layers and circuitry, or a MEMS wafer-scale packaging, such as an RF switch.
  • Still other uses includes an enhanced three-dimensional electronic imager having wide dynamic range and pixel level image processing due to the density of the vias on the wafer.
  • Yet another application includes a vertically interconnected sensor array which provides signal processing in conjunction with infrared sensor systems, use with an arrayed acoustic sensing system, LADAR, and microprocessor circuits in which latency across the chip presents an issue.
  • the wafers having high aspect ratio through-wafer vias are intended to be used as stand alone wafers or in combination with other types of wafers or systems.
  • the foregoing is intended to cover all modifications and alternative constructions falling within the spirit and scope of the invention as expressed in the appended claims, wherein no portion of the disclosure is intended, expressly or implicitly, to be dedicated to the public domain if not set forth in the claims.

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Abstract

Embodiments of the present invention are directed to a process for forming small diameter vias at low temperatures, wherein through- substrate vias are formed, preferably by sequentially etching from both major surfaces into the substrate, and conductive material is deposited into the vias by means of a flowing solution plating technique; preferably, the conductive material releases a gas that pushes the conductive material through the via to facilitate plating the via with the conductive material .

Description

A LOW TEMPERATURE METHOD FOR FABRICATING HIGH-ASPECT RATIO VIAS AND DEVICES FABRICATED BY SAID METHOD
Related Applications
[0001] This Application is related to U.S. Patent Application Serial No. 60/651,951 entitled "A Low Temperature Method for Fabricating High- Aspect Ratio Vias and Devices Fabricated by Said Method", filed on February 9, 2005 and is incorporated herein by reference, and further claims the benefit of U.S. Application Serial No. 11/167,014, entitled "A Low Temperature Method for Fabricating High-Aspect Ratio Vias and Devices Fabricated by Said Method", filed on June 23, 2005.
Field of the Invention
[0002] This invention is directed to a method for fabricating high-aspect ratio through- wafer vias. In particular, embodiments of the invention are directed to methods for the low temperature fabrication of through-wafer vias having small diameters. The invention is also directed to devices fabricated using such methods.
Background
[0003] The fabrication of integrated circuit chips has become a sophisticated process that can allow complex circuitry to be densely packaged onto a single wafer, also known as a substrate. Originally, most chips were fabricated in a simple planar design. As the need for greater density of circuitry on a single substrate grew, the early simple planar chip designs proved inadequate. Indeed, the planar designs limited the amount of circuitry that could be placed on a single substrate, and further limited the implementation of multi-technology circuits such as Si CMOS and SiGe, or integrated. device circuits such as a MEMS device and a related control circuit.
[0004] To overcome some of the limitations resulting from the planar design, designers began stacking chips to form three-dimensional designs. Vias extending through the wafer create three-dimensional interconnects which facilitate connection to the circuitry throughout the chip, thereby allowing the implementation of more advanced circuits and device architectures, and increasing the computing capacity of the chip. For example, three-dimensional designs increase the physical space available on the chip, thereby allowing a higher density of complex circuitry to be placed within a given die area. Furthermore, a three-dimensional design with through-wafer vias can enable advanced micro-electronic chip stacking or the stacking of various types of micro-components directly onto the chip. Multiple components on a single chip allow, for example, increased processing of image data and signal processing.
[0005] Although three-dimensional chips using through-wafer vias have proven useful, they are currently limited. In one approach, through- wafer vias have been formed in thick substrates. At thicknesses in excess of 200-400 microns, the wafers retain mechanical durability and can be easily handled and processed without the need for sequential stacking and thinning operations. In the thick wafer approach, wafers are etched and the formed vias are electrically insulated and metalized. Once the vias have been formed and metalized, the three-dimensional circuits are assembled by stacking (either at wafer- level or die-level).
[0006] Although this approach provides some advantages, for example, the ability to process the circuit layers in parallel, test for functionality, and assemble the 3D stack in an efficient manner, and addresses the mechanical integrity of the wafer, it introduces other limitations, hi particular, one limitation is the inability to fabricate small-diameter, fine-pitch vias. Indeed, due to current etching techniques, the formation of high-aspect ratio (ratio of depth to diameter) vias results in a large diameter-to-pitch (pitch is the center to center measurement between vias) ratio for the vias. This limits the etch depth of the vias, and also reduces the amount of available space on the wafer for other uses. Current techniques typically produce vias having diameters of about 4 μm with a depth of about 20 μm (low temperature techniques) and 100 μm diameters with a depth of about 500 μm (high temperatures techniques), rendering an aspect ratio of about 1:5 for both high temperature and low temperature techniques. Both dry etching and wet etching have been demonstrated for the thick wafer processing, and both suffer from constraints on via size and separation, hi addition, it is very difficult to reliably deposit electrical isolation layers and metallic conductors using low process temperature in the high aspect ratio vias. In current systems the larger diameter vias are tolerated as ensuring the deposition of conformal isolation and conductive layers becomes increasingly difficult with smaller diameter vias.
[0007] To reduce the vias diameters, some techniques stack, bond and thin multiple wafers into a 'single' wafer and form the vias through only a single thin layer of the stacked wafers at a time, thereby reducing the aspect ratio and diameter required of an individual via. This approach involves wafer thinning to reduce the required etch depth, and hence enable smaller via diameters to be achieved. In this approach, two wafers to be stacked are bonded and one portion (top or bottom) of the stacked wafers is thinned. The thinning requires a significantly reduced thickness of the wafer (typically 10-25 μm). At this thickness, vias can be etched through the thinned layer while maintaining small diameter and small separation between neighboring vias. Alternatively, the via could be etched to a limited depth prior to the bonding, and then its bottom surface exposed in the thinning operation after bonding. In either process, the reduced layer thickness is necessary due to the aspect ratio limitations of the etch process. The advantages of this approach include the ability to use well-developed fabrication processes. However, disadvantages arise from the need for sequential processing of each successive layer and the complexity of intermediate testing. Further, although this allows for via depth greater than one wafer, the thinning of the stacked wafers reduces their integrity and makes them more susceptible to breakage during use and damage from handling. Further still, many current bonding techniques involve high temperatures, high voltage and/or high pressure. Each of these poses difficulties if the stacking includes prefabricated integrated circuits with multi-level interconnects as the process could damage the circuitry.
[0008] Furthermore, many current via fabrication techniques, such as thermal oxidation and polysilicon deposition, are performed at high temperatures because conformal depositions, such as the insulation or conductive layers, require higher temperatures for successful deposition into the vias. However, these higher temperature processes cannot be used for circuit wafers, such as CMOS, as the higher temperatures can damage or destroy the circuitry. Rather, these techniques are generally limited to microelectromechanical system ("MEMS") applications without integrated circuitry. For circuitry applications, to use low temperature techniques such as electroplating with thin wafers, the vias must normally have large diameters to achieve uniform internal coverage by insulating or conductive layers, small diameter vias require thinning the wafers.
[0009] A need exists in the industry to fabricate high aspect ratio, small diameter through- wafer vias in relatively thick substrates to enable parallel layer processing, known-good-die testing, and either die-level or wafer-level assembly. A further need exists in the industry for fabricating through-wafer, small diameter vias at low temperatures. A still further need exists for a process to uniformly coat small diameters vias.
Summary of the Disclosure
[0010] Embodiments of the present invention are directed to a method for forming small diameter vias at low temperatures, and devices fabricated using such methods. In preferred embodiments, through-substrate vias are fabricated by forming a through- substrate via hole; forming an insulated layer on the interior surface of the via; and depositing conductive material into the via by means of a flowing solution plating technique. The flow of this solution may be facilitated by the use of plating chemistries wherein the plating reaction releases a gas that pushes the conductive material solution through the via to facilitate plating the via with the conductive material, hi preferred embodiments, the fabrication of the substrate is conducted at low temperatures. [0011] The substrate fabricated by using such methods has first and second surfaces, comprising a first plurality of substantially cylindrical cavities formed into the first surface to first depths and having first diameters; a second plurality of substantially cylindrical cavities formed into the second surface to second depths greater than said first depths and having second diameters greater than said first diameters; and said first and second plurality of cavities being coated with an insualting layer and a conductive material and being mutually aligned to form a plurality of continuous conductive vias through said substrate.
[0012] A feature of embodiments of the invention is the formation of small diameter through-substrate vias. An advantage of this feature is that a higher density of vias can oe rormeα on a single suDstrate, tnus allowing more circuitry to be included on a single substrate.
[0013] A further feature of embodiments of the invention is that the through-substrate vias can be fabricated at low temperatures. An advantage to this feature is that the formation of the vias does not damage circuitry contained within the substrate. [0014] A still further feature of embodiments of the invention is that the activation of the isolation layer provides for conformal layers of conductive material. An advantage to this feature is that the substrate is uniformly coated with conductive material which enhances the performance of the chips.
[0015] Another feature of embodiments of the invention is that it provides a method for forming small-diameter, fine-pitch vias in relatively thick substrates to enable parallel layer processing, known-good-die testing, and either die-level or wafer-level assembly. An advantage to this feature is that the use of a thicker wafer maintains the mechanical integrity of the wafer to minimize breakage during processing and use. A further advantage to this feature is that it avoids the need for sequential bonding and thinning operations and offers capabilities not possible in conventional technologies.
Brief Description of the Drawings
[0016] The detailed description of embodiments of the invention will be made with reference to the accompanying drawings, wherein like numerals designate corresponding parts in the figures.
[0017] Figure 1 is a block diagram of a process for forming high aspect ratio, through- wafer vias in accordance with an embodiment of the invention.
[0018] Figure 2 is a schematic of the process for forming high aspect ratio, through- wafer vias in accordance with the embodiment of Figure 1.
[0019] Figure 3 is an enlarged cross-sectional view of the etched vias formed in accordance with the process of Figure 1.
[0020] Figure 4 is a schematic of the etching process to form the vias in accordance with the embodiment of Figure 1. [002 IJ Figure 5 is a photomicrograph of a portion of the isolation layers formed during the deposition of the materials onto the wafer which have been exposed by removing the surrounding wafer material.
Detailed Description of Preferred Embodiments
[0022] Embodiments of the present invention are directed to a process for fabricating high aspect ratio through-wafer vias at low temperatures. The fabrication process produces high performance silicon chips or CMOS assemblies having high density via interconnects.
[0023] With reference to Figure 1, in preferred embodiments, to form a via, a first cavity is etched into the first surface of a wafer 10. After the first cavity is formed, a second cavity is etched into the second surface of the wafer 12. Once the first and second cavities are formed, a first material is deposited onto the wafer such that it uniformly coats the wafer 14, including uniformly coating the interior walls of the cavities. Finally, a second material is deposited onto the wafer such that the second material uniformly coats the wafer 16, including the interior walls of the cavity.
[0024] With reference to Figure 2, the wafer 20, also referred to as a substrate, comprises a first surface 24, a second surface 26 and a depth d. In preferred embodiments, the circuitry is disposed in a first portion of the wafer 27 nearer the second surface than the first surface. The circuitry will depend, of course, on the purpose of the final product. In preferred embodiments, the wafer is made from silicon. However, the wafer can be formed from any suitable material, including, but not limited to, gallium arsenide or indium phosphate.
[0025] Figure 2 depicts a series of cross-sectional views of the wafer during various stages of the overall process generally described in Figure 1. Referring to Figure 2, prior to fabricating the vias, alignment marks 30 are etched on the first 24 and second 26 surface of the wafer 20. The alignment marks facilitates alignment of the wafer during the creation of different layers to ensure proper formation of the chip. Once the alignment marks have been etched into the wafer 20, a first cavity 32 is etched into the first surface 24. The first cavity, also known as a via, has a first diameter 34, and extends a first depth 36 into the wafer 20. In preferred embodiments, the first cavity has a diameter of 4 μm and extends to a first depth between 50 μm - 80 μm. In preferred embodiments, the first diameter 34 can range between 0.5 μm - 300 μm, and the first cavity can extend to a first depth between 10 μm - 200 μm. Generally, the first depth 36 does not extend laterally into the portion of the wafer 27 containing the circuitry, and will extend in depth to below the portion of the wafer containing active circuitry. [0026] A second cavity 38, also known as a via, having a second diameter 40, is etched coaxially with the first cavity 32 into the second surface 26 of the wafer and extends a second depth 42 into the wafer 20. The second cavity 38 has a diameter of 8 μm to 20 μm and extends to a second depth of 200 μm. In preferred embodiments, the second diameter 40 can range from .5 μm to 300 μm, and the second cavity can extend to a second depth ranging from 50 μm - 1500 μm.
[0027] The second cavity 38 is etched to a second depth such that it communicates with the first cavity 32 to form a continuous aperture 39 through the entire thickness of the wafer. Figure 3 depicts a cross section of the continuous aperture 39 formed by the first cavity 32 and the second cavity 38.
[0028] Embodiments of the invention produce high aspect ratio first and second cavities having small diameters. The high aspect ratio cavities are achieved via an etching process known as the Bosch process for Deep Reactive Ion Etching ("DRIE") in Si, • although any etching process which can produce high aspect ratio, small diameter cavities would also be suitable.
[0029] Overall, as is well known by those skilled in the art, the DRIE process utilizes alternating etch and passivation steps. With reference to Figure 4, an etchant, such as, sulfur hexafluoride SF6 is used to etch a portion of the cavity into the wafer. To passivate the side wall of the cavity and prevent further lateral etching, an insulating layer is subsequently deposited using a separate gas composition, including species such as octafluorocyclobutane C4F8. The process then repeats until the desired depth is achieved. As this process is well known by those skilled in the art, a more detailed description will not be set forth. In preferred embodiments, the etching process is conducted at temperatures below 100 °C. In still other preferred embodiments, the etching process is conducted at temperatures below 400 0C. As discussed above, low temperatures are any temperatures that do not damage the existing circuitry. [0030] Etching via the Bosch process allows for etching with high selectivity and achieves substantially vertical side walls. Indeed, the Bosch process produces a high aspect ratio via of 40: 1. This high aspect ratio facilitates the production of smaller diameter cavities as it reduces the amount of lateral blooming during etching and reduces side wall scalloping.
[0031] With reference again to Figure 2, once the continuous aperture 39 has been formed, a first material 44 is deposited onto the wafer. In preferred embodiments, the first material 44 is a dielectric or a non-electrically conductive material, such as parylene, silicone dioxide derived from precursors such as tetra-ethyl ortho silicate ("TEOS"), aluminum oxide or other inorganic oxides or insulating organic films. The first material 44 forms an isolation layer that is conformal and uniformly covers the sidewalls of the cavities. The uniform coverage of the sidewalls with the first material 44, or isolation layer, electrically isolates the cavities from the substrate and from the other cavities. [0032] To uniformly deposit the first material 44, in preferred embodiments, the first material is deposited via vapor-deposition. In preferred embodiments, the vapor- deposition is conducted at temperatures below room temperature, for example, below 250C, although temperatures between 2O0C and 2000C are also suitable. [0033] As stated above, in some embodiments, the first material is parlyene. Parylene vapor-deposition is conformal and thus, produces uniform coverage of the wafer, including the interior walls of the small diameter cavities. The achievement of uniform, conformal coverage by the parylene vapor-deposition has been confirmed in deep cavities, for example, cavities ranging from 350-450 μm. Figure 5 depicts a portion of a dissolved wafer which exposes the cavity shells formed from parylene. As illustrated in Figure 5, the shape of the cavity shell is fully formed and evinces the coverage of the parylene throughout the interior of the cavity of a given depth. [0034] In addition to parylene vapor-deposition, other techniques that provide for uniform and conformal coverage are also suitable, such as atomic layer deposition ("ALD") using an aluminum oxide non-conductive ceramic, plasma enhanced chemical vapor deposition tetraethyl silicon dioxide ("PECVD TEOS"), and Bosch passivation coating. As these techniques are well known to those skilled in the art, a detailed discussion regarding these techniques will not be set forth. [0035] After the first material 44 has been deposited onto the wafer, a second material 46, comprising an electrically conductive material, is deposited onto the first material 44. In preferred embodiments, prior to the deposition of the second material 46, the first material 44 is activated. Activating the first material, for example, an isolation layer, makes the first material more conducive to receive the second material 46. Once the first material is activated, the second material 46 is deposited onto the activated first material 44. The second material 46 uniformly covers the wafer, including the interior walls of the cavities, and metallizes the wafer.
[0036] Various techniques for activating the first material and depositing the second material can be used. For instance, in one embodiment, assuming a first material of parylene, the parylene is activated via the application of an oxygen plasma. The parylene is exposed to the oxygen plasma for approximately 3-5 minutes. The exposure to the oxygen plasma roughens the surface of the parlyene and causes hydrophobic surfaces to become hydrophilic. The transformation of the surface from hydrophobic to hydrophilic causes the surface to become a wetable surface that will spread aqueous materials applied to the surface and uniformly coat the surface with the applied materials. Thus, the application of the second material 46 to the activated parylene surface will cause the second material to spread and uniformly coat the wafer, including the interior walls of the cavities, hi some embodiments, the second material completely fills the cavities as illustrated in Figure 2. Activation by other suitable plasmas may also be used, including, but not limited to, an argon plasma.
[0037] hi another embodiment, activation of the isolation layer is achieved by the application of a seed layer that causes a reaction with the second material 46 when it is applied to the wafer. For instance, in one embodiment, a two-part tin-palladium (Sn/Pd) technique is used to deposit a seed layer onto the first material. In this example, the seed layer facilitates plating of the metal conductor (such as nickel) onto the insulating material. In this two-part process, tin is adsorbed on the parylene by bathing the wafer with the parylene in a solution of stannous chloride (tin) and hydrochloric acid. The
94- solution causes the tin ions Sn to be adsorbed onto the surface of the insulator, e.g., parylene. Next, the wafer is bathed in a solution of palladium chloride and hydrochloric acid which reduces the solution and causes the deposition of palladium on the surface. The reduced solution leaves a monolayer of palladium on the tin. The second material 46, such as nickel, will react with the monolayer of palladium and plate the wafer. Other techniques for applying a seed layer can be used and are well known by those skilled in the art. For example, the seed layer can be applied using a solution containing a metal acetate. In this technique, a solution containing a metal acetate, such as palladium acetate, is bathed over the substrate and through the vias to cause coating on the interior surfaces of the vias. The application of heat to the coating causes the deposition of a thin metal layer on the interior surface of the vias. The above described seed deposition and plating techniques can be applied in the plating of any structure, for example, a circuit board, and is not limited to the plating of vias and wafers.
[0038] After the first material 44 has been activated, the second material 46 is deposited on the activated first material. Various techniques can be used to deposit the second material 44. However, for effective metallization of the cavities, it is preferable for the second material 46 to be deposited uniformly, including uniform deposition into the cavities. In preferred embodiments, flowing solution plating techniques are used. For instance, in one embodiment, an electroless deposition process is used to deposit the second material 46. In this embodiment, the second material 46 is nickel, but other materials may be used. The wafer is bathed in a nickel solution such that the nickel flows over the wafer and fills the cavities. Assuming activation of the parylene based on the approaches discussed previously, the nickel solution reacts with the activated parylene and causes the release of hydrogen. The release of the hydrogen pushes the nickel - through the cavities and allows the cavities to remain clear, thereby allowing the nickel to plate the entire cavity through the wafer despite the small diameters. The process is complete when hydrogen is no longer released. In this embodiment, the nickel plating is performed at 850C. Other flowing solution techniques can also be used where the solution flow is created by other sources. For instance, the flow of the solution can be created by a mechanical agitation of the solution, or pressurization of the solution. In addition to flowing plating techniques, the deposition of the second material, can include, but is not limited to, chemical vapor deposition and atomic layer deposition techniques to deposit conductive materials (which may include metals, ceramics, or polymers). [0039] With reference again to Figure 2, once the second material has been deposited on the wafer, the wafer is polished on the first and second surfaces 24, 26. In an alternative embodiment, removal of the seed layer on the planar surfaces of the wafer can provide selective plating only in the interior surfaces of the via holes, which would eliminate the need for a surface polishing. Li either approach, a subsequent surface plating using a noble material (such as Au) can reduce surface oxide formation and facilitate subsequent electrical interconnection to the via. Any final connections required to be made via interconnects formed by the cavities are completed and the wafers are then ready for use. Although the foregoing described the invention with preferred embodiments, this is not intended to limit the invention. Indeed, embodiments of this invention can be combined with other circuit chips and systems. For instance, embodiments of the invention can be used for compact electronic circuits with multiple stacking layers and circuitry, or a MEMS wafer-scale packaging, such as an RF switch. Still other uses includes an enhanced three-dimensional electronic imager having wide dynamic range and pixel level image processing due to the density of the vias on the wafer. Yet another application includes a vertically interconnected sensor array which provides signal processing in conjunction with infrared sensor systems, use with an arrayed acoustic sensing system, LADAR, and microprocessor circuits in which latency across the chip presents an issue. [0040] As seen from the foregoing, the wafers having high aspect ratio through-wafer vias are intended to be used as stand alone wafers or in combination with other types of wafers or systems. In this regard, the foregoing is intended to cover all modifications and alternative constructions falling within the spirit and scope of the invention as expressed in the appended claims, wherein no portion of the disclosure is intended, expressly or implicitly, to be dedicated to the public domain if not set forth in the claims.

Claims

WE CLAIM:
1. A process for fabricating a through-substrate via, the substrate having a first surface and a second surface, comprising: forming a through-substrate via hole into the substrate; forming an isolation material onto the substrate between the substrate and the conductive material, said isolation material being electrically insulating, continuous and substantially conformal; and depositing conductive material into the via hole such that it is electrically continuous across its length.
2. A process as claimed in claim 1, further comprising: preparing the isolation material for receiving the conductive material such that the conductive material reacts with the isolation material to plate the via; and formation of the conductive material by means of a solution plating technique.
3. A process as claimed in claim 1 , wherein forming the through-substrate via, forming isolation material, and depositing conductive material are performed at a low temperature range.
4. A process as claimed in claim 3, wherein said low temperature range is less than 100 °C.
5. A process as claimed in claim 3, wherein said low temperature is less than 400 0C.
6. A process as claimed in claim 1, wherein said isolation material is formed onto said substrate via deposition by vapor-deposition of organic materials, atomic layer deposition, plasma enhanced chemical vapor deposition, or polymer passivation coatings derived from substrate etch processing.
7. A process as claimed in claim 2, wherein the isolation material is parylene; and the isolation material is prepared by activating it with a plasma.
8. A process as claimed in claim 2, wherein the isolation material is prepared by activating it with a seed layer which reacts with the conductive material.
9. A process as claimed in claim 8, wherein the seed layer is applied by: absorbing tin onto the isolation material by bathing the substrate in a solution of stannous chloride and hydrochloric acid; and bathing the substrate in a solution of palladium chloride and hydrochloric acid to deposit palladium on the substrate's surface.
10. A process as claimed in claim 1, further comprising: forming a plurality of vias into the substrate; and plating said plurality of vias by the solution plating technique.
11. A process as claimed in claim 1, wherein the depth of the vias is greater than 100 μm.
12. A process as claimed in claim 1, wherein said through-substrate via is formed by: etching a first cavity into the first surface of the substrate with a first diameter; and etching a second cavity into the second surface of the substrate with a second diameter, wherein the first and second cavities form a single continuous aperture through the substrate.
13. A process as claimed in claim 12, wherein said first and second cavities extend to depths in the range of 20 μm - 200 μm and 100 μm - 350 μm, respectively.
14. A process as claimed in claim 13, wherein said first and second diameters are in the range of 2 μm - 8 μm and 6 μm - 25 μm, respectively, .
15. A process as claimed in claim 1, wherein the conductive material is nickel.
16. A process as claimed in claim 1, wherein said flowing solution plating technique comprises an electroless deposition process.
17. A process as claimed in claim 12, wherein said first and second cavities are etched by a deep reactive ion etching process.
18. A process as claimed in claim 2, wherein the reaction to deposit the conductive material releases a gas that pushes the conductive material solution through the via to facilitate plating the via with the conductive material.
19. A process as claimed in claim 2, wherein a solution flow is generated by mechanical agitation to facilitate plating with the conductive material.
20. A substrate having first and second surfaces, comprising: a first plurality of substantially cylindrical cavities formed into the first surface to first depths and having first diameters; a second plurality of substantially cylindrical cavities formed into the second surface to second depths greater than said first depths and having second diameters greater than or equal to said first diameters; and said first and second plurality of cavities being coated with a conductive material and being mutually aligned to form a plurality of continuous conductive vias through said substrate.
21. A substrate as claimed in claim 20, further comprising circuitry residing nearer the first surface than the second surface, said first plurality of conductive vias form connections to said circuitry.
22. A substrate as claimed in claim 20, wherein said first plurality of conductive cavities is essentially solid and said second plurality of conductive cavities is essentially hollow.
23. A substrate as claimed in claim 20, wherein said first diameters and said second diameters are substantially equal.
24. A substrate as claimed in claim 20, wherein said first diameters are less than said second diameters.
25. A substrate as claimed in claim 20, the substrate being integrated with a plurality of substrates to form a multi-layer stack of wafers, the wafers being stacked and bonded together.
26. A multi-layered wafer stack as claimed in claim 25, wherein said bonding provides electrical interconnection between individual wafer layers.
27. A multi-layered wafer stack as claimed in claim 25, further comprising circuitry in at least one wafer, said first plurality of cavities form connections to said circuitry.
28. A substrate as claimed in claim 20, wherein at least one of said plurality of conductive cavities is partially solid.
29. A substrate as claimed in claim 20, wherein at least one of said second plurality of conductive cavities is partially solid.
30. A substrate as claimed in claim 25, further comprising circuitry, said circuitry residing on each of the plurality of wafers.
31. A substrate as claimed in claim 20, wherein said first and second diameters are in the range of .5 μm - 300 μm.
32. A substrate as claimed in claim 25, wherein each wafer comprises a thickness of greater than 50 μm.
33. A substrate as claimed in claim 20, further comprising a thickness defined between said first surface and said second surface.
34. A substrate as claimed in claim 33, wherein said thickness is greater than 50 μm.
35. A substrate as claimed in claim 20, wherein said first and second depths extend to depths in the range of 10 μm - 200 μm and 50μm - 1500 μm, respectively.
36. A substrate as claimed in claim 20, said first and second plurality of cavities being coated with an isolation material, said isolation material being prepared for receiving conductive material such that the conductive material reacts with the isolation material to plate the via.
37. A substrate as claimed in claim 20, said first and second plurality of cavities being coated with a metal acetate layer, said metal acetate layer being deposited by bathing the substrate in a solution containing metal acetate and thermally reacting the metal acetate solution to form the metal seed layer.
38. A process as claimed in claim 6, wherein said deposition by atomic layer deposition comprises deposition of inorganic oxides, said inorganic oxides being capable of providing electrical insulation and conformal surface coatings.
39. A process as claimed in claim 2, wherein the isolation material is prepared by activating it with a seed layer that reacts with the conductive material, said seed layer being deposited at low temperatures by atomic layer deposition or chemical vapor deposition.
40. A process as claimed in claim 8, wherein the seed layer is applied by: bathing the substrate in a solution containing a metal acetate such that the vias are coated with the metal acetate; heating the solution such that the metal acetate solution forms a thin metal layer on the interior surfaces of the vias.
41. A process for plating a surface, comprising: depositing a first material onto the surface; preparing the first material for receiving a second material, the second material being electrically conductive, such that the second material reacts with the first material to plate the surface; and depositing the second material onto the surface by means of a solution plating technique.
42. A process for plating a surface as claimed in claim 41 , wherein the first material material is a polymer.
43. A process for plating a surface as claimed in claim 42, wherein the polymer is among the various types of parylene.
44. A process for plating a surface as claimed in claim 41, wherein preparing the first material comprises: exposing the first material to a plasma to cause the surface to become hydrophilic.
45. A process for plating a surface as claimed in claim 41, wherein preparing the first material comprises: applying a seed layer to the first material.
46. A process for plating a surface as claimed in claim 41 , wherein the seed layer is applied by activation by metal precursor solutions, vapor deposited metal, or metal acetate decomposition.
47. A plated substrate having a surface, comprising: a first layer of parylene deposited onto the surface of the substrate; wherein the parylene surface is treated by exposing said parylene surface to a plasma; a seed layer deposited onto the parylene layer, the seed layer deposited by bathing the substrate in a first solution containing first metal ions, the first solution releasing the first metal ions of the solution onto the parylene layer, and bathing the substrate in a second solution containing second metal ions, the second solution releasing the second metal ions onto the first metal ions in a monolayer; and an electrodeposited conductive layer, wherein the conductive layer reacts with the thin layer of the second metal ion on the first metal ion to plate the substrate.
PCT/US2006/004176 2005-02-09 2006-02-07 A low temperature method for fabricating high-aspect ratio vias and devices fabricated by said method WO2006086337A1 (en)

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