Patent Application
20210059017
Embodiments of the present disclosure generally relate to methods and apparatus for processing a substrate, and more particularly, to methods and apparatus for processing a substrate using a process chamber configured for bottom launch delivery of microwave energy.
In recent years new advanced packaging integration schemes for various types of substrates have been used. The substrates, for example, can be made from any suitable material and can sometimes be coated with one or more metal thin films (e.g., titanium (or other metal) coated glass substrates, titanium (or other metal) coated silicon substrates, epoxy substrates with embedded silicon dies, etc.). When packaging such substrates, microwave energy, which can be provided by one or more microwave energy sources through a sidewall (e.g., side launch) of the process chamber, is used to heat the substrates. Unfortunately, when processing substrates with such chambers, due to the behavior of the substrates (e.g., which can act as a conductor) in an E-field and B-field of the microwave energy, uniform heating of the substrates is sometimes hard to achieve. For example, the edges (e.g., peripheral edges) of the substrates tend to heat up quicker (and/or to higher temperatures) than the remaining area of the substrates, sometimes referred to as “edge hot” phenomenon. To overcome non-uniform heating of the substrates during operation, conventional process chambers can employ one or more various techniques. For example, some process chambers can be configured to rotate a hoop of the process chamber for rotating the substrate. Alternatively or additionally, some process chambers can include a microwave stirrer for agitating microwaves, e.g., to create additional microwave modes, and/or can be configured to sweep through different microwave frequencies. Such techniques, however, can be unpredictable and/or uncontrollable, and, typically, do not provide adequate uniform heating of the substrate.
Accordingly, the inventors have found that there is a need for methods and apparatus for processing a substrate using a process chamber configured for bottom launch delivery of microwave energy and including hardware configured to more evenly distribute microwave energy across the substrate.
Methods and apparatus for processing a substrate are provided herein. In some embodiments, for example, a process chamber for processing a substrate includes a microwave energy source configured to provide microwave energy from beneath a substrate support provided in an inner volume of the process chamber; a first microwave reflector positioned on the substrate support above a substrate supporting position of the substrate support; and a second microwave reflector positioned on the substrate support beneath the substrate supporting position, wherein the first microwave reflector and the second microwave reflector are positioned and configured such that microwave energy passes through the second microwave reflector and some of the microwave energy is reflected from a bottom surface of the first microwave reflector back to the substrate during operation.
In accordance with at least some embodiments, a process chamber for processing a substrate includes a substrate support provided in an inner volume of the process chamber; a first microwave reflector positioned on the substrate support above a substrate supporting position of the substrate support; a second microwave reflector positioned on the substrate support beneath the substrate supporting position; and a third microwave reflector positioned on the substrate support above the second microwave reflector and beneath the substrate supporting position, wherein the microwave energy passes through the second microwave reflector and some of the microwave energy passes through the third microwave reflector such that some of the microwave energy is reflected from a bottom surface of the first microwave reflector back to the substrate during operation.
In accordance with at least some embodiments, a method for processing a substrate using a process chamber can include positioning, on a substrate support disposed in an inner volume of a process chamber, a first microwave reflector above a substrate; positioning, on the substrate support, a second microwave reflector beneath the substrate; and transmitting, from beneath the substrate, microwave energy from a microwave energy source of the process chamber such that the microwave energy passes through the second microwave reflector and some of the microwave energy is reflected from a bottom surface of the first microwave reflector back to the substrate.
Other and further embodiments of the present disclosure are described below.
Embodiments of the present disclosure, briefly summarized above and discussed in greater detail below, can be understood by reference to the illustrative embodiments of the disclosure depicted in the appended drawings. However, the appended drawings illustrate only typical embodiments of the disclosure and are therefore not to be considered limiting of scope, for the disclosure may admit to other equally effective embodiments.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. The figures are not drawn to scale and may be simplified for clarity. Elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.
Embodiments of methods and apparatus for processing a substrate using a process chamber configured for bottom launch delivery of microwave energy and including hardware configured to evenly distribute microwave energy across the substrate are provided herein. The hardware can include, for example, two annular microwave reflectors and an optional additional microwave reflector. A substrate can be positioned between the two annular microwave reflectors to process the substrate and microwave energy can be directed from a bottom (e.g., from beneath the substrate) of the process chamber through a bottom one of the microwave reflectors to process the substrate. Some of the microwave energy is reflected from a bottom surface of a top one of the microwave reflectors and back towards the substrate to provide uniform heating of the substrate and reduce, if not eliminate, edge hot phenomenon typically associated with conventional process chambers.
In some embodiments, the process chamber 102 can be configured for packaging substrates. In such embodiments, the process chamber 102 can include one or more microwave energy sources 108 configured to provide microwave energy to the inner volume 106 via, for example, waveguide 110, for heating the substrate, e.g., from about 130° C. to about 150° C. The temperature that the substrate can be heated to can depend on, for example, thermal budget considerations, industry practices, etc. Accordingly, in some embodiments, the substrate can be heated to temperatures less than 130° C. and greater than 150° C. One or more temperature sensors (not shown), e.g., non-contact temperature sensors, such as infrared sensors, can be used to monitor a temperature of the substrate while the substrate is being processed, e.g., in-situ.
The waveguide 110 can be configured to provide the microwave energy through the bottom surface 107 (bottom launch) of the chamber body 104 (e.g., from beneath the substrate for centrosymmetric propagation of microwaves). More particularly, a waveguide opening 111 through which microwave energy is launched or output is provided at the bottom surface 107 of the chamber body 104. The waveguide opening 111 can be flush with the bottom surface 107 or can be slightly raised above the bottom surface 107, as illustrated in
A substrate 112 that is processed in the process chamber 102 can be any suitable substrate, e.g., silicon, germanium, glass, epoxy, etc. For example, in some embodiments, the substrate 112 can be made from glass having at least one metal (e.g., titanium, tungsten, etc.) deposited thereon, silicon having at least one metal (e.g., titanium, tungsten, etc.) deposited thereon, or an epoxy substrate (wafer) with one or more embedded silicon dies.
A controller 114 is provided and coupled to various components of the process chamber 102 to control the operation of the process chamber 102 for processing the substrate 112. The controller 114 includes a central processing unit (CPU) 116, support circuits 118 and a memory or non-transitory computer readable storage medium 120. The controller 114 is operably coupled to and controls the microwave energy source 108 directly, or via computers (or controllers) associated with a particular process chamber and/or support system components. Additionally, the controller 114 is configured to receive an input from, for example, the temperature sensor for controlling the microwave energy source 108 such that a temperature of the substrate 112 does not exceed a threshold while the substrate 112 is being processed.
The controller 114 may be any form of general-purpose computer processor that can be used in an industrial setting for controlling various chambers and sub-processors. The memory, or non-transitory computer readable storage medium, 120 of the controller 114 may be one or more of readily available memory such as random access memory (RAM), read only memory (ROM), floppy disk, hard disk, optical storage media (e.g., compact disc or digital video disc), flash drive, or any other form of digital storage, local or remote. The support circuits 118 are coupled to the CPU 116 for supporting the CPU 116 in a conventional manner. The support circuits 118 include cache, power supplies, clock circuits, input/output circuitry and subsystems, and the like. Inventive methods as described herein, such as the method for processing a substrate (e.g., substrate packaging), may be stored in the memory 120 as software routine 122 that may be executed or invoked to control the operation of the microwave energy source 108 in the manner described herein. The software routine may also be stored and/or executed by a second CPU (not shown) that is remotely located from the hardware being controlled by the CPU 116.
Continuing with reference to
In at least some embodiments, the substrate support 124 can include a lift assembly (not shown). The lift assembly may include one or more of a motor, an actuator, indexer, or the like, to control the vertical position of the peripheral members 130a-130c. The vertical position of the peripheral members 130a-130c is controlled for placing and removing the substrate 112 through an opening 132 (e.g., a slit valve opening) and onto or off one or more of the peripheral members 130a-130c. The opening 132 is formed through one of the sidewalls 105 at a height proximate the peripheral members 130a-130c to facilitate the ingress and egress of the substrate 112 into the inner volume 106. In some embodiments, the opening 132 may be retractably sealable, for example, to control the pressure and temperature conditions of the inner volume 106.
The vertical supports 126 can be supported by one or more components within the inner volume 106 of the process chamber 102. For example, in at least some embodiments, the vertical supports 126 may be supported by a hoop 128. The hoop 128 can be supported on the bottom surface 107 of the chamber body 104, for example via one more coupling elements such as fastening screws or the like, adjacent the waveguide opening 111 disposed through the waveguide 110. Alternatively or additionally, the hoop 128 can be supported on a bellows 130 that can be disposed on the bottom surface 107, as shown in
The reflector 200 also includes a second portion 208. The second portion 208 includes an OD2 thickness t2 of about 1.00 mm to about 5.00 mm, forming a step 208a from the outer edge 206 of the first portion 202 to an outer edge 210 of the second portion 208 (see
The reflector 200 is coupled to the peripheral member 130a (see
Additionally, unlike the reflector 200 which is coupled to the peripheral member 130a, the reflector 300 is coupled to the hoop 128 (see
In an assembled configuration, the substrate 112, the reflector 200, and the reflector 300 can be spaced-apart from each other and/or the waveguide opening 111 of the waveguide 110 at any suitable distance. For example, the inventors have found that to ensure even/uniform heating of the substrate 112 a distance d1 that a bottom surface of the reflector 200 can be from a top surface of the substrate 112 is at least three microwave wavelengths. Additionally, a distance d2 that a bottom surface of the substrate 112 can be from the waveguide opening 111 or the bottom surface 107 (e.g., depending if the waveguide opening 111 is flush with the bottom surface 107) is at least three microwave wavelengths. In at least some embodiments, for example, the distance d2 can be equal to about 160 mm. Moreover, a distance d3 that a bottom surface of the reflector 300 can be from the waveguide opening 111 or the bottom surface 107 (e.g., again depending if the waveguide opening 111 is flush with the bottom surface 107) is about 15 mm to about 80 mm.
The second portion 404 includes an outer edge 408 that defines an OD4 of the second portion 404 that can be about 1.00 mm to about 5.00 mm. The first portion 402 can have similar dimensions as the first portion 202 of the reflector 200. For example, in at least some embodiments, the first portion 402 can have an ID5 (e.g., measured from a center of the second portion 404 to an inner edge 410 of the first portion 402) of about 210 mm and an OD5 (e.g., measured from the center of the second portion 404 to an outer edge 412 of the first portion 402) of about 300 mm to 350 mm. A thickness of the first portion 402 and/or the second portion 404 can be equal to the thickness t1 or the thickness t2 of the first portion 202 or the second portion 208, respectively, e.g., a thickness of about 1.00 mm to 5.00 mm.
An opening 414 is formed between the outer edge 408 of the second portion 404 and the inner edge 410 of the first portion 402. The opening 414 is configured to allow microwave energy that is transmitted through the aperture 306 of the reflector 300 to pass therethrough for heating a bottom surface of the substrate 112.
The first portion 402, the second portion 404, and/or the metal connectors 406 of the reflector 400 can be made from any suitable metal including, but not limited to, copper, aluminum, stainless steel.
In the assembled configuration, similar to the reflector 200, the reflector 400 is coupled to one of the peripheral members, e.g., the peripheral member 130c (see
Next, at 502 a first microwave reflector (e.g., the reflector 200) can be provided and positioned above the substrate. For example, as noted above, the reflector 200 can be positioned on the peripheral member 130a. At 504, a second microwave reflector (e.g., the reflector 300) can be provided and positioned beneath the substrate. For example, the reflector 300 can be positioned on the hoop 128.
In some embodiments, the optional reflector 400 can be provided and positioned on the peripheral member 130c. The reflector 400 can be used to direct some of the microwave energy transmitted through the aperture 306 of the reflector 300.
Next, at 506, under the control of the controller 114, microwave energy is transmitted from the waveguide opening 111 (e.g., from beneath the substrate) and passes through the aperture 306 of the reflector 300. Additionally, some of the some of the microwave energy, e.g., the microwave energy that passes through the substrate, is reflected from a bottom surface, e.g., of the first portion 202 and the second portion 208, of the reflector 200 and back to the substrate during operation. The reflected microwave energy from the reflector 200 heats a top surface (e.g., areas of the substrate other than the edges) of the substrate and provides even/uniform heating of the substrate (e.g., reduce edge hot phenomenon). Additionally, the reflector 200 causes diffraction of some of the propagating microwave, which, in turn, provides a more predictive propagation pattern.
In at least some embodiments, such as when the optional reflector 400 is used, some of the microwave energy transmitted through the aperture 306 of the reflector 300 is also transmitted through the opening 414 between the first portion 402 and the second portion 404 of the reflector 400. Additionally, some of the microwave energy is reflected from bottom surfaces of the first portion 402 and the second portion 404 of the reflector 400 to the reflector 200. Some of the reflected microwave energy from the reflector 400 can then be redirected back from the reflector 300 and through the opening 414 between the first portion 402 and the second portion 404 of the reflector 400, thus providing additional uniform heating of the substrate. The reflector 400 also prevents direction microwave impingement, e.g., where the center of the substrate heats up too quickly.
While the foregoing is directed to embodiments of the present disclosure, other and further embodiments of the disclosure may be devised without departing from the basic scope thereof.
