The present disclosure relates to a piezoelectric MEMS (MicroElectroMechanical System) device with a suspended membrane having high mechanical shock resistance and to the manufacturing process thereof.
As known, actuators are devices that convert a physical quantity of one type into another physical quantity of a different type; in particular, the quantity deriving from the conversion usually involves some form of movement or mechanical action.
Recently, actuators of micrometric and nanometric dimensions have been proposed, also referred to as micro-actuators or nano-actuators, which can be manufactured using the semiconductor technology (the so-called MEMS technology) and thus at very contained costs. Such micro-actuators and nano-actuators can be used in a wide range of devices, in particular in mobile and portable devices.
Examples of micro-actuators are valves, switches, pumps, linear and rotary micromotors, linear-positioning devices, speakers, optical devices, and piezoelectric micro-machined ultrasonic transducers (PMUTs).
Micro-actuators of a known type may operate according to four physical principles:
Each technology presents advantages and limits as regards power consumption, rapidity of movement, exerted force, movement amplitude, movement profile, simplicity of manufacture, amplitude of the applied electrical signals, strength, and sensitivity, which render advantageous use thereof in certain applications, but not in others and thus determine the sector of use.
Hereinafter, reference is made to a MEMS actuator device that operates according to a piezoelectric principle and in particular is able to exploit the TFP (Thin-Film Piezo) MEMS technology.
TFP MEMS technology currently uses a unimorphic actuation mode, in which a structure (for example, a membrane, a beam, or a cantilever), generally formed by at least two layers arranged on top of one another, undergoes bending as a result of variations in the applied load. In this case, there is a controlled alteration of the strain in one of the layers, referred to as “active” layer, which causes an induced strain in the other layer or layers, also referred to as “inactive” or “passive” layer or layers, with consequent flexure of the structure.
This technique is advantageously used for bending the membrane, beam, or cantilever in applications where a vertical movement, i.e., a movement in the direction perpendicular to the lying plane of the structure is desired, such as in liquid ink-jet printing heads, autofocus systems, micropumps, microswitches, speakers, and PMUTs.
For instance,
In the presence of a reverse bias, as illustrated in
An embodiment of a MEMS piezoelectric actuator applied to a generic optical device is illustrated in
In the absence of bias,
The piezoelectric actuators illustrated in
Another embodiment of a piezoelectric-actuation MEMS device is illustrated in
The MEMS device 30 comprises a body 31, extending in thickness along the axis Z and having a first and a second surface 31A, 31B. In particular, the body 31 comprises a substrate 32, of semiconductor material (e.g., silicon), delimited at the top by a third surface 32A and at the bottom by the second surface 31B. The substrate 32 accommodates a cavity 34, extending from the second surface 31B throughout the entire thickness (along the axis Z) of the substrate 32.
In detail, the cavity 34 is delimited at the side by a wall 34A and at the top by a bottom surface 34B; moreover, the cavity 34 has, in top plan view, for example a circular shape with center O.
The body 31 further comprises an insulating layer 39, for example, of silicon oxide (SiO2), extending over the third surface 32A of the substrate 32; and a structural layer 41, for example, of glass, such as BPSG, extending over the insulating layer 39. The insulating layer 39 and the structural layer 41 form a membrane 37, fixed to the substrate 32 at a peripheral portion 45 of the body 31.
A piezoelectric actuator 50, having, for example, an annular shape with center O in top plan view, extends on the first surface 31A of the body 31 along the entire periphery of the MEMS device 30. The internal circumference of the piezoelectric actuator 50 defines a central portion 43 of the body 31, where the structural layer 41 is at least partly exposed.
In particular, the piezoelectric actuator 50 is formed by a stack of layers, comprising a first electrode 60; a piezoelectric material layer 61, for example PZT (Pb, Zr, TiO2) or aluminum nitride (AlN), extending on the first electrode 60; and a second electrode 62, extending on the piezoelectric material layer 61. In particular, the first and the second electrodes 60, 62 are electrically coupled to respective voltage generators (not illustrated) by respective conductive paths (not illustrated).
In use, a difference of potential is applied between the first and the second electrodes 60, 62 of the piezoelectric actuator 50 so as to generate a deflection of the membrane 37 in the upward direction (i.e., along the axis Z, towards the outside of the cavity 34) in a unidirectional way; in particular, the deflection of the membrane 37 generates a spherical curvature at the central portion 43 of the body 31.
The MEMS device 30 of
In detail,
In particular, the MEMS device 730 has an opening 772, extending through the structural layer 741 and the insulating layer 739 (and, thus, the membrane 737) at the central portion 743 of the body 731. In detail, the opening 772 has, in top plan view, for example a circular shape with center O. The structural layer 741 of the MEMS device 730 may, for example, be of polysilicon or oxide (e.g., silicon oxide).
The MEMS device 730 further comprises a first electrical contact 774, which has, for example, an annular shape, in top plan view, with center O and surrounds the opening 772. The first electrical contact 770 is electrically coupled to a first terminal 776 by first electrical lines 775 (schematically illustrated in
The switch 770 further comprises a contact element 777, facing the MEMS device 730. In particular, the contact element 777 comprises a contact substrate 780, having a contact surface 780A facing the MEMS device 730 and extending in a plane parallel to a plane XY of a Cartesian reference system XYZ; and a second electrical contact 785, arranged on the surface 780A. In detail, the second electrical contact 785 extends along an axis X of the Cartesian reference system XYZ so as to face and be aligned to the first electrical contact 774. The second electrical contact 785 is further electrically coupled by second electrical lines 786 (schematically illustrated in
In a rest condition, i.e., when the difference of potential between the first and the second electrodes 760, 762 of the piezoelectric actuator 750 is zero, the membrane 737 extends parallel to the plane XY and to the contact element 777 (i.e., it is not deflected); consequently, the terminals 776 and 790 are electrically separated and the switch 770 is open.
When a difference of potential of appropriate value is applied between the first and the second electrodes 760, 762, it causes deflection of the membrane 737 upwards and brings the first electrical contact 774 against the second electrical contact 785, electrically coupling the first and the second terminals 776, 790 together and closing the switch 770.
In an operating condition, the piezoelectrically actuated devices illustrated in
In this case, a mechanical shock generates a force of a high value on the membrane 37, 737 of the MEMS device 30, 730, generating a sharp deflection of the membrane 37, 737 itself. Application of a force of high value in a sudden way involves a sudden stress on the structure, in particular at the membrane 37, 737 where it is fixed to the peripheral portion 45, 745 of the MEMS device 30, 730. This stress, over time, may generate one or more fractures in the stressed region of the membrane 37, 737, thus jeopardizing correct operation of the MEMS device 30, 730.
To solve this problem, it is therefore desirable to increase the resistance to mechanical shock of the MEMS device 30, 730. For instance, it is possible to increase the thickness of the membrane 37, 737. However, an increase in the thickness of the membrane 37, 737 determines a corresponding degradation of the optical aperture of the MEMS device 30 of
The aim of the present disclosure is to provide a piezoelectric MEMS device and a manufacturing process thereof that overcome the drawbacks of the prior art.
According to the present disclosure, a MEMS device and a manufacturing process thereof are provided, as defined in the attached claims.
For a better understanding of the present disclosure, preferred embodiments thereof are now described, purely by way of non-limiting example, with reference to the attached drawings, wherein:
With reference to
The body 131 further comprises a stiffening element 170 extending on the third surface 132A. In particular, the stiffening element 170 comprises a stiffening layer 171 of semiconductor (e.g., polysilicon), and a coating layer 172, of insulating material (e.g., silicon oxide).
The stiffening element 170 has at the center an opening 170A, which is concentric with respect to the cavity 134 and has a diameter D2, smaller than the diameter D1 of the cavity 134. Consequently (
The coating layer 172 coats the stiffening layer 171 on the side facing the substrate 170 and fixes the stiffening element 170 to the substrate 132. Moreover, the coating layer 172 coats the inner wall of the opening 170A.
The stiffening element 170 has a thickness (stiffening thickness T1), for example between 1 μm and 20 μm.
The body 131 further comprises an insulating layer 139, for example of silicon oxide, extending on the third surface 132A; and a structural layer 141, for example of BPSG, extending on the insulating layer 139. In particular, the structural layer 141 is delimited at the top by the first surface 131A of the body 131, and the ensemble formed by the insulating layer 139 and the structural layer 141 has a structural thickness T2, for example comprised between 5 μm and 50 μm. Moreover, the portion of insulating layer 139 exposed by the opening 170A delimits the cavity 134 at the top, to form a second part of end surface 134A of the cavity 134.
The coating layer 172, the stiffening layer 171, the insulating layer 139 and the structural layer 141 form a membrane 137 of variable thickness, suspended over the cavity 134. In particular, the membrane 137 has a first and a second portion 180, 181. The first portion 180 is formed only by the insulating layer 139 and by the structural layer 141, is surrounded by the second portion 181 of the membrane 137, and has a thickness equal to the structural thickness T2. The second portion 181 is formed by the insulating layer 139, the structural layer 141, the stiffening layer 171 and the coating layer 172, is arranged adjacent to a peripheral portion 145 of the body 131, and has a thickness T3 equal to the sum of the stiffening thickness T1 and the structural thickness T2.
Moreover, as may be noted from the top plan view of
A piezoelectric actuator 150 having, in top plan view (
In particular, the piezoelectric actuator 150 is formed by a stack of layers, comprising a first electrode 160, of conductive material; a piezoelectric material layer 161, for example PZT (Pb, Zr, TiO2), aluminum nitride (AlN), potassium-sodium niobate (KNN) or barium titanate (BaTiO3), extending on the first electrode 160; and a second electrode 162, of conductive material, extending on the piezoelectric material layer 161. In particular, the first and the second electrodes 160, 162 are electrically coupled to respective voltage sources (not illustrated) by conductive paths (not illustrated).
Moreover, a dielectric layer (not illustrated) extends between the structural layer 141 and the first electrode 161 so as to physically and electrically isolate them from one another.
In use, the MEMS device 130 operates according to the modalities described with reference to the MEMS device 30 of
The stiffening element 170 allows an increase in the resistance to mechanical shock of the membrane 137 of the MEMS device 130 in its peripheral portion (first portion 180) without increasing the thickness in the operative central region (second portion 181) of the membrane 137, and thus without reducing the performance of the MEMS device 130. In fact, the stiffening element 170 is of a material (here, polysilicon) capable of withstanding a high tensile stress (e.g., ranging between 1 GPa and 2 GPa). In this way, when a high force due to a mechanical shock (e.g., when the device is dropped) acts on the MEMS device 130, causing a high stress in the second portion 181 of the membrane 137, the stiffening element 170 is capable of absorbing said force (and, thus, the stress localized in the second portion 181) at least in part. In this way, it is possible to limit sharp deflection of the membrane 137 and prevent possible failures. In other words, the stiffening element 170 locally thickens the membrane 137 in the points of greater concentration of the mechanical stress.
The manufacturing steps of the MEMS device 130 are illustrated schematically in
Initially (
With reference to
With reference to
Next,
In
With reference to
Next,
Next,
Next, a mask layer (not illustrated) is deposited and patterned on the second surface 132B of the substrate 132, which is etched from the back using known photolithographic and etching techniques (e.g., through anisotropic etching, such as DRIE—Deep Reactive Ion Etching) so as to form the cavity 134 and the opening 170A, thus releasing the membrane 137.
At the end of the process, the mask layer is removed, and the wafer 200 is diced so as to obtain the MEMS device 130 of
In a variant of the manufacturing process of the stiffening element 170 illustrated in
With reference to
Next,
Next, the further epitaxial layer 1250 is planarized and polished according to known techniques, in a way similar to what described with reference to
The further manufacturing steps are similar to the ones described in
In particular, the MEMS device 330 has a through hole 385, extending through the structural layer 341 and the insulating layer 339 at the first portion 380 of the membrane 337. In particular, the through hole 385 has, in top plan view (
Moreover, in the present embodiment, the structural layer 341 may, for example, be of polysilicon, silicon, BPSG or metal (such as copper, Cu, aluminum, Al, platinum, Pt, gold, Au).
An electrical contact (not illustrated) similar to the electrical contact 774 of
The MEMS device 330 may advantageously be used, for example, for acoustic applications (e.g., such as microphone), as a valve, or as an RF switch in a way similar to what discussed for the switch 770 of
The MEMS device 330 of
In particular, the membrane 1337 forms a cantilever, suspended over the cavity 1334. Moreover, in the present embodiment, the membrane 1337 has, for example, a quadrangular (e.g., rectangular) shape in top plan view (not illustrated); in addition, the piezoelectric actuator 1350 has, for example, a quadrangular (e.g., rectangular) shape in top plan view (not illustrated).
In use, the MEMS device 1330 operates according to the operating modalities described with reference to the MEMS devices 130, 330 of
Moreover, the MEMS device 1330 is obtained in a way similar to what described with reference to the manufacturing steps illustrated in
The electronic device 500 comprises, in addition to the MEMS device 530, a microprocessor (CPU) 501, a memory block 502, connected to the microprocessor 501, and an input/output interface 503, for example a keyboard and/or a display, also connected to the microprocessor 501. An application-specific integrated circuit (ASIC) 504 may be integrated in the MEMS device 530 or, as illustrated in
The MEMS device 530 communicates with the microprocessor 701 via the ASIC 504.
The electronic device 500 is, for example, a mobile communication device, such as a mobile phone or smartphone, a PDA, or a computer, but may also be a voice recorder, a player of audio files with voice-recording capacity, a console for video games, and the like.
The present MEMS device and the manufacturing process thereof have various advantages.
In particular, the presence of the stiffening element 170, 370 allows to reduce the impact of mechanical shock, for instance when the MEMS device 30, 330 is dropped. In particular, the stiffening element 170, 370 is arranged in the second portion 181, 381 of the membrane 137, 337, where there is a high stress in the case of a high force. In addition, the stiffening element 170, 370 is of a material capable of withstanding high tensile stresses (e.g., polysilicon). In this way, in the presence of mechanical shocks, the deflection of the membrane 137, 337 of the MEMS device 30, 330 is limited in so far as the stiffening element 170, 370 (and thus the second portion 181, 381 of the membrane 137, 337) is able to absorb at least in part the force (and, thus, the stress) and consequently reduce the risk of failure or weakening of the membrane due to mechanical shock.
Moreover, the present MEMS device 130, 330 is manufactured according to a simple and far from costly manufacturing process.
Finally, it is clear that modifications and variations may be made to the MEMS device and to the manufacturing process described and illustrated herein, without thereby departing from the scope of the present disclosure, as defined in the attached claims.
For instance, the stiffening element 170, 370, 1370 may be provided in MEMS devices of the type described in U.S. Patent Publication No. 2018/0190895, which describes a piezoelectric micro-actuator formed by a beam element of semiconductor material and by a piezoelectric region, extending over the beam. In particular, one end of the beam element is fixed and may be provided with the stiffening element 180, 380, 1380; the other end is connected to a hinge element of a constraint structure that is not deformable in the thickness direction of the beam.
Moreover, the present stiffening element 170, 370, 1370 may be provided in MEMS devices of the type described in U.S. Patent Publication No. US2019/0240844, which describes a MEMS device of a piezoelectric type having a first and a second manipulation arm formed by a control arm and an articulated arm. The control arm of both of the manipulation arms may be provided with the stiffening element described herein.
The various embodiments described above can be combined to provide further embodiments. These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.
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