The present disclosure relates generally to spatial atomic layer deposition and, more specifically, to monitoring and, if necessary, adjusting the relative positioning of the depositor head and the opposed substrate plate during operation of the spatial atomic layer deposition apparatus.
Atomic layer deposition (ALD) is a thin-film deposition technique that is capable of conformally coating a substrate—typically an ultra-high-aspect ratio substrate—with an angstrom-scale film of an ALD material one atomic layer at a time. ALD involves sequentially exposing a designated portion of a build substrate to first and second ALD precursor gases. Each of the ALD precursor gases includes reactive ligands that participate in a self-limiting surface reaction to chemically deposit an atomic monolayer of the reacted precursor gases. The two atomic monolayers that are derived alternately from the ALD precursor gases together produce a single atomic layer of the ALD material film upon completion of their reaction. As such, the thickness of the ALD material film can be controlled by varying the number of ALD cycles performed and, thus, the number of atomic layers of the ALD material that are chemically-deposited in a layer-by-layer fashion. Indeed, the ALD material film exhibits a linear growth rate; that is, the thickness of the film is proportional to the number of ALD cycles performed. The material that can be deposited by ALD can range from oxides to nitrides, sulfides, carbides, and/or metals by exploiting the self-limiting binary chemical reactions of ALD.
Spatial atomic layer deposition (SALD) is a specific version of ALD where the ALD cycles are spatially controlled by exposing the build substrate to different precursor gas zones rather than a conventional temporally controlled ALD process where long purging of the precursor gases in a static chamber is required. In SALD, the time-consuming purge step of conventional ALD is not practiced, which expediates the process by about three orders of magnitude, without sacrificing the self-limiting, conformal growth of the ALD material film. As a result, the net deposition rate of SALD is much greater compared to conventional ALD, which enables higher throughput in a shorter amount of time. SALD deposition processes may be performed in conjunction with the prior patterning of inhibition materials by printing, stamping, lithography, or other patterning methods, in a process known as area-selective atomic layer deposition (AS-ALD). AS-ALD can be used to fabricate 3-D devices in a bottom-up manner without the need for lithography and top-down etching processes. The thin-film 3-D devices may even include multiple films of dissimilar materials to stack thin film layers for device fabrication.
An SALD apparatus that performs the SALD process includes a depositor head that discharges at least one flow of each of the ALD precursor gases. The flows of the ALD precursor gases are separated by a flow of an inert gas. The gas flows discharged from the depositor head may extend linearly and parallel to one another to establish an elongated zone of each of the ALD precursor gases and an elongated inert gas curtain that isolates the ALD precursor gas zones for at least a certain distance away from the depositor head. In addition to the depositor head, the SALD apparatus also includes a substrate plate that opposes the depositor head and retains the build substrate onto which the ALD material film is grown. SALD can be performed at atmospheric pressure since the reactive ALD precursor gases are confined spatially by the inert gas zones.
The substrate plate is oriented spatially with respect to the depositor head to facilitate the SALD process. In particular, the substrate plate and the depositor head are spaced apart by a gap, which is preferably maintained as uniform as possible in an effort to achieve parallelism between the depositor head and the substrate plate. The gap is typically relatively small—on the order of several tens to several hundreds of microns—to ensure isolation of the precursor gas zones. If the gap is or becomes too large, the inert gas curtain(s) will begin to dissipate prior to reaching the build substrate that is held on the substrate plate, which may allow the ALD precursor gases to diffuse through the inert gas curtains and mix together. Such unintended mixing of the ALD precursor gases is detrimental to the SALD process since it results in chemical vapor deposition (CVD) growth instead of the controlled layer-by-layer growth of the ALD film material. Furthermore, the ALD precursor gases may escape to the surrounding environment and may even react with air if the gap between the depositor head and the substrate plate becomes too large.
The depositor head and the substrate plate have conventionally been positioned relative to one another using manual adjustment techniques. The two components are set at the desired spacing as close-to-parallel as feasible, and the SALD apparatus is operated with the expectation that the depositor head and the substrate plate will not stray from their original set positions. The positional relationship between the depositor head and the substrate plate, including, most notably, the size and uniformity of the gap between the opposed surfaces of those two components, is generally not monitored with instrumentation installed on the SALD apparatus. In the present application, an approach for monitoring the spatial orientation of the depositor head and the substrate plate in real-time during operation of the SALD apparatus is disclosed. The disclosed approach permits the size of the gap between the depositor head and the substrate plate and/or the parallelism of the two components to be monitored over time and, if necessary, adjusted to correct for any deviation in the relative positioning of the two components that may have occurred.
According to one aspect of the disclosure, there is provided a spatial atomic layer deposition apparatus that includes:
a depositor head having an active surface configured to discharge a flow of a first precursor gas, a flow of a second precursor gas, and a flow of an inert gas that separates the flow of the first precursor gas and the flow of the second precursor gas;
a substrate plate that opposes the depositor head, the substrate plate having a support surface that retains a build substrate, the support surface of the substrate plate being spaced apart from the active surface of the depositor head by a gap;
a plurality of gap detection sensors supported on either the depositor head or the substrate plate, each of the gap detection sensors producing an output signal indicative of a distance between the active surface of the depositor head and the support surface of the substrate plate; and
a controller that communicates with the plurality of gap detection sensors and receives the output signal from each of the plurality of gap detection sensors, the controller, based on the output signals received from the gap detection sensors, being configured to determine a spatial orientation of the active surface of the depositor head and the support surface of the substrate plate.
According to various embodiments, the spatial atomic layer deposition apparatus may further include any one of the following features or any technically-feasible combination of some or all of these features:
According to another aspect of the disclosure, there is provided a spatial atomic layer deposition apparatus that includes:
a bridge supported in an elevated position and having an elongated body that is tiltable about both a longitudinal axis and a lateral axis of the body;
an ALD precursor gas distributor carried by the elongated body, the ALD precursor gas distributor comprising a depositor head having an active surface configured to discharge a flow of a first precursor gas, a flow of a second precursor gas, and a flow of an inert gas that separates the flow of the first precursor gas and the flow of the second precursor gas;
a substrate plate that opposes the depositor head, the substrate plate having a support surface that retains a build substrate and a back surface opposite the support surface, the support surface of the substrate plate being spaced apart from the active surface of the depositor head by a gap;
a plurality of linear actuators that engage the back surface of the substrate plate;
a plurality of gap detection sensors supported on either the depositor head or the substrate plate, each of the gap detection sensors producing an output signal indicative of a distance between the active surface of the depositor head and the support surface of the substrate plate at a location of the sensor; and
a controller that receives the output signal from each of the plurality of gap detection sensors and sends a positioning signal to each of the plurality of linear actuators, the controller being configured to determine a spatial orientation of the active surface of the depositor head and the support surface of the substrate plate based on the output signals received from the gap detection sensors and to adjust the size or the uniformity of the gap between the support surface of the substrate plate and the active surface of the depositor head by actuating, via the positioning signals, one or more of the plurality of linear actuators.
According to various embodiments, the spatial atomic layer deposition apparatus may further include any one of the following features or any technically-feasible combination of some or all of these features:
According to another aspect of the disclosure, there is provided method of operating a spatial atomic layer deposition apparatus that includes the steps of:
supplying a first ALD precursor gas, a second ALD precursor gas, and an inert gas to a depositor head of a spatial atomic layer deposition apparatus;
discharging at least one linear flow of the first ALD precursor gas, at least one linear flow of the second ALD precursor gas, and at least one linear flow of the inert gas from an active surface of the depositor head, the at least one linear flow of the inert gas separating the at least one linear flow of the first ALD precursor gas and the at least one linear flow of the second ALD precursor gas;
moving a substrate plate that retains a build substrate on a support surface relative to the depositor head to deposit one or more atomic layers of an ALD material film, each atomic layer of the ALD material film being deposited by sequentially exposing the build substrate to the linear flow of the first ALD precursor gas and the linear flow of the second ALD precursor gas as a result of relative movement between the substrate plate and the depositor head, wherein the first and the second ALD precursor gases react to form the atomic layers of the ALD material film; and
measuring a spatial orientation of the active surface of the depositor head and the support surface of the substrate plate using a plurality of gap detection sensors mounted to either the depositor head or the substrate plate, each of the plurality of gap detection sensors producing an output signal indicative of a distance it measures between the active surface of the depositor head and the support surface of the substrate plate.
According to various embodiments, the method of operating a spatial atomic layer deposition apparatus may further include any one of the following features or steps or any technically-feasible combination of some or all of these features/steps:
Example embodiments will hereinafter be described in conjunction with the appended drawings, wherein like designations denote like elements, and wherein:
The present disclosure describes an SALD apparatus that includes a depositor head that discharges linear zone-separated first and second ALD precursor gases towards an opposed substrate plate that retains a build substrate where SALD growth is directed. An active surface of the depositor head through which the first and second ALD precursor gases are discharged and a confronting support surface of the substrate plate are separated by a gap. The size of the gap is maintained at a target value, typically in the range of 50 μm to 1000 μm, with a spatial tolerance of no more than 10 μm, to ensure that adjacent ALD precursor gas zones remain separated by an intervening inert gas curtain. Any deviation in the size and/or the uniformity of the gap that may occur through unwanted variations in the relative spatial orientation of the depositor head and the substrate plate can heighten the possibility that the inert gas curtain(s) will be unable to fully isolate the ALD precursor gas zones. If the ALD precursor gas zones lose their fluid autonomy and begin to intermix, the layer-by-layer growth mechanism of SALD will wane and give way to CVD deposition instead. Furthermore, this may result in the leakage of ALD precursor gases to the atmosphere. To that end, the disclosed SALD apparatus and, in particular, one of the depositor head or the substrate plate, is outfitted with gap detection sensors. These gap detection sensors communicate with a controller and render the SALD apparatus capable of real-time adjustment of the gap between the active and support surfaces of the depositor head and the substrate plate, respectively, as well as dynamic gap alignment control.
The first and second ALD precursor gases used during SALD processing may vary depending on the composition of the ALD material film being deposited. The first ALD precursor gas may, for example, be an organometallic gas, and the second ALD precursor gas may be an oxidant gas. In one implementation of SALD, the ALD material film grown on the build substrate may be a metal oxide such as zinc oxide (ZnO), tin oxide (SnO2), or aluminum oxide (Al2O3). To deposit ZnO, SnO2, or Al2O3 by SALD, the first ALD precursor gas (an organometallic gas) may be diethylzinc (DEZ) for ZnO, tetrakis(dimethylamido)tin (TDMASn) for SnO2, and dimethylaluminum isopropoxide (DMAI) or trimethyl aluminum (TMA) for Al2O3, and the second ALD precursor gas (an oxidant gas) in each instance may be distilled water. The inert gas used to separate and isolate the first and second ALD precursor gases may be nitrogen (N2). Of course, other ALD precursor gases and inert gases may be employed to form any of the aforementioned metal oxide films as well as other compositions of the ALD material. The SALD apparatus described herein and the ways in which the SALD apparatus is used are not limited to any particular ALD precursor gases, inert gases, or compositions of the deposited ALD material film.
Referring now to
The frame 12 includes first and second upstanding support legs 32a, 32b that are spaced apart from one another above a stand surface. The first and second upstanding support legs 32a, 32b support the bridge 14 horizontally in an elevated position. The bridge 14 comprises an elongated body 34 having opposed first and second ends 36a, 36b. A longitudinal axis A of the elongated body 34 runs centrally through the body 34 between the opposed first and second ends 36a, 36b of the body 34 while a lateral axis B runs centrally through the elongated body 34 perpendicular to the longitudinal axis A and half way between the opposed first and second ends 36a, 36b (
The elongated body 34 carries the zoned ALD precursor gas distributor 16 and is supported in its elevated position on the upstanding support legs 32a, 32b. The elongated body 34 is tiltable and, as such, has the potential to control the tilt of the gas distributor 16. The elongated body 34 is tiltable in that the plane of the body 34 established by the longitudinal and lateral axes A, B can be tilted about both axes A, B. For example, in the embodiment shown here, the elongated body 34 is an elongated plate 38 that defines a central opening 40. An underside 42 of the plate 38 is supported inboard of the first end 36a by first and second linear actuators 44a, 44b and is also supported inboard of the second end 36b by a ball mount 46. The first and second linear actuators 44a, 44b are secured to an elevated platform 48 of the first upstanding support leg 32a, which extends inwardly towards the second upstanding support leg 32b. The ball mount 46 that supports the underside 42 of the elongated plate 38 is similarly secured on an elevated platform 50 of the second upstanding support leg 32b, which extends inwardly towards the first upstanding support leg 32a.
The first and second linear actuators 44a, 44b preferably include first and second motors 52a, 52b and first and second actuation rods 54a, 54b that are connected to and driven by their respective motors 52a, 52b. The actuation rods 54a, 54b are linearly displaceable in both a positive (forward or extending) and negative (rearward or retracting) direction. The actuation rod 54a, 54b of each linear actuator 44a, 44b is linearly displaceable by a rotatable leadscrew driven by its respective motor 52a, 52b, which, for example, is preferably a stepper motor. Each of the motors 52a, 52b used to drive linear displacement of its respective actuation rod 54a, 54b preferably has a step size or resolution of 1.5 μm or higher to enable precision guided linear displacement of the actuation rods 54a, 54b. Commercially available actuator assemblies that include a motor and an actuation rod may be employed to support the elongated body 34. For example, one such suitable assembly that may be used here is a linear motion stepper motor assembly from Haydon Kerk Pittman. While stepper motors and actuation rods are described here as being preferred implementations, it will be appreciated that other types of linear actuators and driving mechanisms may of course be employed to achieve the same functionality.
The first and second linear actuators 44a, 44b support the elongated plate 38 closer to the first end 36a than the lateral axis B of the plate 38 and, likewise, the ball mount 46 supports the plate 38 closer to the second end 36b than the lateral axis B of the plate 38. The linear actuators 44a, 44b are spaced apart along the width of the elongated plate 38 with the first actuator 44a engaging the underside 42 of the plate 38 on one side of the longitudinal axis A and the second actuator 44b engaging the underside 42 of the elongated plate 38 on the other side of the longitudinal axis B. The ball mount 46 engages the underside 42 of the elongated plate 38 on the longitudinal axis A of the plate 38 and, thus, the points of engagement between the underside 42 of the elongated plate 38 and the linear actuators 44a, 44b and the ball mount 46 form an acute triangle. To that end, the controlled linear displacement of the actuation rods 54a, 54b of the first and second linear actuators 44a, 44b—individually and in coordination with each other—plus the articulating movement permitted by the ball mount 46 allows the elongated body 36, which, here is the elongated plate 38, to be tilted about each of its axes A, B to achieve precision movement in three-dimensions.
The zoned ALD precursor gas distributor 16 includes a gas manifold 56 and a depositor head 58 (
The depositor head 58 has an active surface 62 configured to discharge at least one linear flow of the first ALD precursor gas 64, at least one linear flow of the second ALD precursor gas 66, and at least one linear flow of the inert gas 68 that separates the linear flow of the first ALD precursor gas 64 and the linear flow of the second ALD precursor gas 66, as shown in
In one specific embodiment, as shown in
The active surface 62 of the depositor head 58 also defines a continuous peripheral border channel 82 that surrounds and encloses all of the other channels 70, 72, 74, 76, 78. The peripheral border channel 82 includes first and second elongated side channel portions 82a, 82b that run parallel to the other elongated channels 70, 72, 74, 76, 78 and, thus, extend in the first direction DF. Additionally, the peripheral border channel 82 includes first and second elongated bridge channel portions 82c, 82d that run perpendicular to the elongated channels 70, 72, 74, 76, 78 and connect with the elongated side channel portions 82a, 82b to complete the continuous track of the peripheral border channel 82. The peripheral border channel 82 discharges a flow of the inert gas and, more specifically, the four channel portions 82a, 82b, 82c, 82d of the peripheral border channel 82 discharge corresponding linear flows of the inert gas. In that regard, a linear flow of the inert gas is located on each side of the second and third elongated channels 72, 74 opposite the fourth and fifth elongated channels 76, 78, respectively, such that an inert gas curtain is present on each side of the second ALD precursor gas zones established by the linear flows of the second ALD precursor gas discharged from the second and third elongated channels 72, 74.
The substrate plate 18 has a first axis C and a second axis D (
The base plate 20 is positioned below the substrate plate 18 and is disposed on a central block 92 that is either integral with the base plate 20 or otherwise secured to the base plate 20 by, for example, one or more fasteners (
Each of the third, fourth, and fifth actuation rods 104a, 104b, 104c of the third, fourth, and fifth linear actuators 100a, 100b, 100c extends through its respective aligned opening 94a, 94b, 94c in the base plate 20 and engages the back surface 90 of the substrate plate 18. The third, fourth, and fifth linear actuators 100a, 100b, 100c support the substrate plate 18 above the base plate 20 yet below the depositor head 58 such that a gap G exists between the active surface 62 of the depositor head 58 and the support surface 84 of the substrate plate 18. In the embodiment shown, the third actuation rod 104a engages the back surface 90 of the substrate plate 18 on the first axis C while the fourth and fifth actuation rods 104b, 104c are spaced apart along a direction parallel to the second axis D such that the fourth actuation rod 104b engages the back surface 90 of the substrate plate 18 on one side of the first axis C and the fifth actuation rod 104c engages the back surface 90 on the other side of the first axis C. The third linear actuator 100a may be positioned proximate the first and second linear actuators 44a, 44b that support the first end 36a of the elongated body 34 while the fourth and fifth linear actuators 100b, 100c may be positioned proximate the ball mount 46 that supports the second end 36b of the elongated body 34. As such, the points of engagement between the back surface 90 of the substrate plate 18 and the third, fourth, and fifth linear actuators 100a, 100b, 100c form an acute triangle that is oppositely oriented from the acute triangle formed by the engagement points of first and second linear actuators 44a, 44b and the ball mount 46 with the underside 42 of the elongated plate 38. The controlled linear displacement of the third, fourth, and fifth actuation rods 104a, 104b, 104c of the third, fourth, and fifth linear actuators 100a, 100b, 100c—individually and in coordination with each other—allows the substrate plate 18 to be tilted about each of its axes C, D to achieve precision movement in three-dimensions.
The linear motion stage 22 moves the substrate plate 18 relative to the depositor head 58 to facilitate the SALD process. The linear motion stage 22 includes a travel stand 108 and a mobile table 110 that is slidable fore and aft along the travel stand 108 in a machine dimension. The sliding movement of the mobile table 110 is effectuated by a linear drive motor housed within the travel stand 108. As part of the SALD apparatus 10, the central block 92 upon which the base plate 20 is disposed is mounted to the mobile table 110 by mechanical fasteners. Sliding linear movement of the mobile table 110 thus simultaneously moves the substrate plate 18 in the same direction since the substrate plate 18 is supported by the third, fourth, and fifth linear actuators 100a, 100b, 100c and carried by the base plate 20, as described above. A number of constructions of the linear motion stage 22 are permitted and would work within the construct of the SALD apparatus 10. In general, the linear motion stage 22 preferably has sub-micron resolution, or minimum incremental movement, typically on the order of 5 nm to 10 nm, and a maximum travel speed of 2 meters per second, along with sub-micron repeatability and sub-10-micron horizontal and vertical straightness. One specific and commercially available linear motion stage that satisfies these performance characteristics is an Aerotech Pro 165 LM mechanical bearing linear motor stage.
The gap detection sensors 24 number at least three and are attached to either the depositor head 58 or the substrate plate 18 and are configured to measure the size of the gap G—i.e., the distance between the active surface 62 of the depositor head 58 and the support surface 84 of the substrate plate 18—at each sensor location (
Capacitive sensors measure the capacitance between two electrically conductive surfaces that are close to each other. Here, one of the depositor head 58 or the substrate plate 18 is connected to a high-impedance amplifier, and the other of the depositor head 58 or the substrate plate 18 is connected to ground. The amplifier, which can supply an amplified voltage of up to 2 kV, is activated to excite the depositor head 58 or the substrate plate 18, whichever component it is connected to, thus creating a capacitance between the sensor and the opposed active or support surface 62, 84. This capacitance is sensitive to the distance between the sensor and the opposed surface and is measured by the capacitive sensor. The capacitive sensor outputs an output signal, typically an output voltage, that is scaled to represent the size of the gap G at that particular sensor location. The output signal from each of the capacitive sensors is delivered to a data acquisition device that collects and amplifies the output signals for subsequent data processing. Any of a wide variety of capacitive sensors may be used for this application including, in particular, Capacitec HPB-75 capacitive button probes and conjunction with a high-impedance 200-series modular amplifier.
The controller 26 is connected to and interfaces with the gap detection sensors 24, through the data acquisition device, as well the amplifier and the first through fifth motors 52a, 52b, 102a, 102b, 102c that drive the first through fifth actuation rods 54a, 54b, 104a, 104b, 104c. The linear motion stage 22 and the mass flow controllers MF1, MF2, MFP that control gas flow through the zoned ALD precursor gas distributor 16 may also be connected to and interface with the controller 26. The controller 26 may be a computer terminal that is dedicated to operating the SALD apparatus 10 or some other programmable device that can receive input data, execute programmed instructions, and export output data. A programming language, such as Python, may be used to establish an integrated application program interface through which all of the components connected to the controller 26 can be communicated with and controlled through appropriate communication protocols. The Python programming language is a good candidate because it allows for a user interface, parallel processing with multi-threading, and can communicate with all of the applicable hardware devices in the SALD apparatus 10. A diagrammatic depiction of how the various components of the SALD apparatus 10 may connect with the controller 26 is shown in
The SALD apparatus 10 can be operated to grow a precision film of the ALD material layer-by-layer onto the growth portion 28 of the build substrate 30 while monitoring and, if necessary, adjusting a spatial orientation of the depositor head 58 and the substrate plate 18 in real-time. The spatial orientation of the depositor head 58 and the substrate plate 18 that is monitored and possibly adjusted may be the size of the gap G between the active surface 62 of the depositor head 58 and the support surface 84 of the substrate plate 18 and/or the parallelism of those two surfaces 62, 84. For example, when conducting SALD, it may be desired to maintain the gap G between the active and support surfaces 62, 84 of the depositor head 58 and the substrate plate 18, respectively, at a target value ranging anywhere from 50 μm to 1000 μm, or more narrowly from 50 μm to 500 μm, while maintaining parallelism between the active and support surfaces 62, 84. The term “parallelism” refers to a parallel orientation between the active and support surfaces 62, 84 of the depositor head 58 and the substrate plate 18, respectively, or, in other words, a constant distance between the two surfaces 62, 84 across the entire gap G, within a tolerance of ±10 μm.
To operate the SALD apparatus, the linear flow(s) of the first ALD precursor gas 64, the linear flow(s) of the second precursor ALD gas 66, and the linear flow(s) of the inert gas 68 are discharged from the active surface 62 of the depositor head 58 to establish the precursor ALD gas zone(s) and the inert gas curtain(s). The discharge of these linear gas flows is controlled by the controller 26 through the mass flow controllers MF1, MF2, MFP. All of the first ALD precursor gas zone(s), the second ALD precursor gas zone(s), and the inert gas curtain(s) that separate and isolate the first and second ALD precursor gas zones extend along the first direction DF as described above. At the same time, the linear motion stage 22 causes the substrate plate 18 to move back-and-forth relative to the depositor head 58 in a second direction DS (
The relative linear movement between the substrate plate 18 and the depositor head 58 alternately exposes the growth portion 28 of the build substrate 30 to the first and second ALD precursor gases to deposit the ALD material film one atomic monolayer at a time. The constant relative movement between the substrate plate 18 and the depositor head 58 when conducting SALD on one build substrate 30 or a number of different build substrates 30 may, at some point, result in a spatial deviation or misalignment between the two components 18, 58, which can render the gap G between the opposed active and support surfaces 62, 84 too large and/or too non-uniform to support the first and second ALD precursor gas zones. To that end, the gap detection sensors 24 allow the size and parallelism of the gap G to be monitored over time. Each gap detection sensor 24 detects the size of the gap G—that is, the distance between the active surface 62 of the depositor head 58 and the support surface 84 of the substrate plate 18 at its particular sensor location—and reports that distance to the controller 26 in real-time through the generated output signal it delivers to the controller 26. The controller 26 uses the reported distance data embedded in the output signals received from the gap detection sensors 24 to determine whether parallelism exists between the active and support surfaces 62, 84.
Based on that data received from the gap detection sensors 24, the controller 26 can adjust the size and/or uniformity of the gap G by commanding one or more of the first through fifth motors 52a, 52b, 102a, 102b, 102c to linearly displace, either positively or negatively, one or more of their respective actuation rods 54a, 54b, 104a, 104b, 104c. The controller 26 can command the motors 52a, 52b, 102a, 102b, 102c to linearly actuate their respective actuation rods 54a, 54b, 104a, 104b, 104c by a certain calculated distance through a positioning signal that is sent from the controller 26 to each of the motors 52a, 52b, 102a, 102b, 102c. In that regard, the controller 26 can (1) actuate the first and/or second actuation rods 54a, 54b to tilt the elongated body 34 about either or both of its axes A, B, which in turn causes the depositor head 58 to tilt in a corresponding fashion, can (2) actuate the third, fourth, and/or fifth actuation rods 104a, 104b, 104c to tilt the substrate plate 18 about either or both of its axes C, D, or (3) can cause both forms of tilting at the same time to correct the size and/or uniformity of the gap G. For example, upon receiving the output signals from the gap detection sensors 24 and determining that an adjustment in the gap G between the active surface 62 of the depositor head 58 and the support surface 84 of the substrate plate 18 is needed, the controller 26 can execute a parallel plane alignment algorithm to determine how much linear actuation is needed from each of the first through fifth actuation rods 54a, 54b, 104a, 104b, 104c to bring the size and/or uniformity of the gap G back into conformity, and can command the appropriate linear movement of the actuation rods 54a, 54b, 104a, 104b, 104c through actuator-specific positioning signals.
In one type of parallel plane alignment algorithm that focuses on actuating the third, fourth, and fifth actuation rods 104a, 104b, 104c to bring about parallelism between the active and support surfaces 62, 84, parallel plane geometry may be used to solve for a distance Δz that each of the actuation rods 104a, 104b, 104c must be moved to achieve parallelism. Given the three data sets contained in the output signals produced by the three gap detection sensors 24, a plane equation that represents a parallel state between the active surface 62 and the support surface 84 can be obtained by solving the following system of equations, in which x1, x2, x3, y1, y2, y3, z1, z2, z3 are points for the sensors 24 in an x-y-z coordinate system established for the calculation, and d is the target distance between the active and support surfaces 62, 84 at each sensor location:
Sensor 1: ax1+by1+cz1+d=0
Sensor 2: ax2+by2+cz2+d=0
Sensor 3: ax3+by3+cz3+d=0
The Sensor 1, Sensor 2, and Sensor 3 equations above essentially dictate that the gap distance “d” measured by each of the gap detection sensors 24 is the same. The Sensor equations can be solved using basic matrix manipulations and Cramer's rule, in which D is a non-zero for planes not through the origin, such that a, b, and c can be calculated as follows:
Once a, b, and c are calculated, the plane equation is set, and the Δz distance that each actuation rod 104a, 104b, 104c must be moved to equalize the measured gap distance reported by each sensor and to therefore achieve parallelism between the active and support surfaces 62, 84 can be calculated as follows:
Once the Δz distances are determined for each of the actuation rods 104a, 104b, 104c, the controller 26 can command each of the third through fifth motors 102a, 102b, 102c to move their respective actuation rods 104a, 104b, 104c the calculated distance Δz through positioning signals. The process can be repeated multiple times, if necessary, to iteratively improve the accuracy of the calculations and to ultimately achieve the desired gap size and uniformity characteristics. Of course, the controller 26 and gap detection sensors 24 are continually monitoring the gap G between the active and support surfaces 62, 84 and reporting data to the controller 26, which, in turn, can execute the parallel plane alignment algorithm and continuously instruct movement of any or all of the actuation rods 54a, 54b, 104a, 104b, 104c of the linear actuators 44a, 44b, 100a, 100b, 100c at any time. Furthermore, a Python-based user interface (UI) can record and display live data for the size and uniformity of the gap G. Accordingly, the size of the gap G and the uniformity of the gap G can be confidently preserved over time to ensure the SALD process is not disrupted on account of suboptimal spacing between the depositor head 58 and the substrate plate 18.
It is to be understood that the foregoing description is of one or more preferred example embodiments of the invention. The invention is not limited to the particular embodiment(s) disclosed herein, but rather is defined solely by the claims below. Furthermore, the statements contained in the foregoing description relate to particular embodiments and are not to be construed as limitations on the scope of the invention or on the definition of terms used in the claims, except where a term or phrase is expressly defined above. Various other embodiments and various changes and modifications to the disclosed embodiment(s) will become apparent to those skilled in the art. All such other embodiments, changes, and modifications are intended to come within the scope of the appended claims.
As used in this specification and claims, the terms “for example,” “e.g.,” “for instance,” and “such as,” and the verbs “comprising,” “having,” “including,” and their other verb forms, when used in conjunction with a listing of one or more components or other items, are each to be construed as open-ended, meaning that the listing is not to be considered as excluding other, additional components or items. Other terms are to be construed using their broadest reasonable meaning unless they are used in a context that requires a different interpretation.
This invention was made with government support under CMMI1727918 awarded by the National Science Foundation. The government has certain rights in the invention.
Filing Document | Filing Date | Country | Kind |
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PCT/US21/14824 | 1/23/2021 | WO |
Number | Date | Country | |
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62981231 | Feb 2020 | US |