Method and system for automated on-chip material and structural certification of MEMS devices
First Claim
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1. A method for quality control of MEMS fabrication processes, comprising the steps of:
- a) fabricating MEMS structures on a substrate;
b) co-fabricating at least one IMaP test structure on said substrate, said at least one IMaP test structure comprising at least one anchor to said substrate, at least one compliant member functionally attached to said anchor, at least one electrostatic actuator so configured as to apply mechanical stress to said at least one compliant member, at least one diagnostic surface whose shape is determined by the response of said at least one compliant member to said mechanical stress, and contact sites whereby each such electrostatic actuator can be actuated by a voltage applied to said contact sites;
c) releasing the at least one IMaP test structure from the substrate;
d) evaluating the substrate by automated process steps comprising;
α
) making effective electrical contact between an external voltage source and said contact sites;
β
) actuating at least one of the at least one IMaP test structures by applying prescribed test voltages to said electrostatic actuators via said contact sites;
γ
) measuring the displacement of the diagnostic surfaces of the actuated IMaP test structures;
δ
) comparing said displacement with corresponding standards for a high-quality fabrication process; and
, ε
) rejecting said substrate if said comparison reveals process flaws outside of pre-established tolerances.
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Abstract
A new approach toward MEMS quality control and materials characterization is provided by a combined test structure measurement and mechanical response modeling approach. Simple test structures are cofabricated with the MEMS devices being produced. These test structures are designed to isolate certain types of physical response, so that measurement of their behavior under applied stress can be easily interpreted as quality control and material properties information.
103 Citations
36 Claims
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1. A method for quality control of MEMS fabrication processes, comprising the steps of:
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a) fabricating MEMS structures on a substrate;
b) co-fabricating at least one IMaP test structure on said substrate, said at least one IMaP test structure comprising at least one anchor to said substrate, at least one compliant member functionally attached to said anchor, at least one electrostatic actuator so configured as to apply mechanical stress to said at least one compliant member, at least one diagnostic surface whose shape is determined by the response of said at least one compliant member to said mechanical stress, and contact sites whereby each such electrostatic actuator can be actuated by a voltage applied to said contact sites;
c) releasing the at least one IMaP test structure from the substrate;
d) evaluating the substrate by automated process steps comprising;
α
) making effective electrical contact between an external voltage source and said contact sites;
β
) actuating at least one of the at least one IMaP test structures by applying prescribed test voltages to said electrostatic actuators via said contact sites;
γ
) measuring the displacement of the diagnostic surfaces of the actuated IMaP test structures;
δ
) comparing said displacement with corresponding standards for a high-quality fabrication process; and
,ε
) rejecting said substrate if said comparison reveals process flaws outside of pre-established tolerances.- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26)
e) co-fabricating at least one passive IMaP test structure on said substrate, said at least one passive IMaP test structure comprising at least one brace affixed to said substrate, at least one compliant element functionally attached to said brace, and at least one diagnostic surface whose shape is determined by residual stress acting on said compliant element;
f) releasing the at least one passive IMaP test structure from the substrate;
g) further evaluating the substrate by automated process steps comprising;
i) measuring the profile of the diagnostic surfaces of the released passive IMaP test structures; and
,ii) refusing certification of the processed substrate if the measured profiles vary from ideal values by more than pre-established tolerances.
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17. The method of claim 16, wherein some of said at least one compliant element are chosen from the group consisting of cantilever beams, multiply-anchored suspended beams, fixed-fixed beams, multiply-anchored plates, multiply-anchored multiply-connected plates, and edge-supported diaphragms.
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18. The method of claim 16, wherein the step of measuring the profile of the diagnostic surface of the released passive IMaP test structures is carried out by steps comprising taking optical interferometric measurements of said diagnostic surfaces.
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19. The method of claim 18, wherein the profiles corresponding to said optical interferometric measurements are determined by automated computer analysis of said optical interferometric measurements.
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20. The method of claim 1, further comprising the steps of:
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e) further co-fabricating IMaP metrology standards on said substrate;
f) further evaluating the substrate by automated process steps comprising;
i) measuring the dimensions of the IMaP metrology standards; and
,ii) rejecting said substrate if said dimensions fall outside the design values by more than pre-established tolerances.
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21. The method of claim 20, wherein said IMaP metrology standards comprise at least one pit etched from the surface down to a depth characteristic of a buried structural interface.
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22. The method of claim 20, wherein said IMaP metrology standards comprise at least one lateral dimensional standard.
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23. The method of claim 20, wherein measuring the dimensions of the IMaP metrology standards is carried out using a profilometer.
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24. The method of claim 21, wherein measuring said depth comprises use of a capacitive probe.
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25. The method of claim 22, wherein measuring the dimensions of said lateral dimensional standard is carried out through microscopic image analysis.
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26. The method of claim 1, further comprising determining mechanical properties of the material making up the IMaP test structures through analysis of the displacement of the diagnostic surfaces and detailed modeling of the IMaP test structure geometries.
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27. A MEMS fabrication quality control apparatus, comprising:
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a) a mount capable of holding at least one process wafer without inducing unacceptably large values of mounting stress in the at least one process wafer, all of said at least one process wafer having at least one IMaP test structure fabricated thereon, said at least one IMaP test structure comprising at least one anchor to said process wafer, at least one compliant member functionally attached to said anchor, at least one electrostatic actuator so configured as to apply mechanical stress to said at least one compliant member, at least one diagnostic surface whose shape is determined by the response of said at least one compliant member to said mechanical stress, and contact sites whereby each such electrostatic actuator can be actuated by a voltage applied to said contact sites;
b) voltage probes capable of making electrical contact to said contact sites;
c) a voltage source functionally connected to said voltage probes, and which applies voltages as controlled by voltage control data;
d) an imaging optical interferometer comprising a camera which captures an optical interferometric image, converts said image into image data suitable for automated computer analysis, and transmits said image data to an apparatus controller;
e) a positioner which adjusts the relative position and orientation of the voltage probes, the imaging optical interferometer, and the mount in response to position control data;
f) said apparatus controller, comprising;
1) a control computer comprising a central processing unit, a voltage control data source, a position control data source, an image data input receptor, and reporting means to report the results of the quality control analysis;
2) control software which directs the MEMS fabrication quality control apparatus to carry out steps including;
a) positioning the voltage probes, the imaging optical interferometer, and the mount so that the optical interferometric image provided by the imaging optical interferometer includes the image of an IMaP test structure, including its diagnostic surfaces, and also so that the voltage probes make electrical contact with the contact sites connected to said imaged IMaP test structure;
b) generating voltage control data so that voltages programmed to activate the imaged IMaP test structure are applied to the voltage probes;
c) commanding the control computer to accept image data from said camera;
d) analyzing said image data to determine the shape of the diagnostic surfaces of the imaged IMaP test structure; and
,e) evaluating the level of process quality by analyzing the diagnostic surface shapes for the imaged IMaP test structure. - View Dependent Claims (28, 29, 30, 31, 32, 33, 34, 35, 36)
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Specification