Methods of forming micromechanical resonators having high density trench arrays therein that provide passive temperature compensation
First Claim
1. A method of forming a micromechanical resonator operable in a bulk acoustic mode, comprising:
- forming a resonator body anchored to a substrate by at least a first anchor, said resonator body comprising a first material having a negative temperature coefficient of elasticity (TCE) and an array of spaced-apart trenches filled with a second material having a positive TCE, said array of spaced-apart trenches having a sufficient density in the resonator body to meet the following relationship;
1≦
−
RV(TCEI/TCES)[(EI/ES)+(ρ
I/ρ
S)1/2(EI/ES)−
1/2]≦
3,where RV=(VI/VS);
TCES, ES, ρ
S and VS represent the temperature coefficient of elasticity, Young'"'"'s modulus, density and volume of the first material in the resonator body, respectively; and
TCEI, EI, ρ
I and VI represent the temperature coefficient of elasticity, Young'"'"'s modulus, density and total volume of the second material in the array of spaced-apart trenches, respectively.
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Abstract
A method of forming a micromechanical resonator includes forming a resonator body anchored to a substrate by at least a first anchor. This resonator body may include a semiconductor or other first material having a negative temperature coefficient of elasticity (TCE). A two-dimensional array of spaced-apart trenches are provided in the resonator body. These trenches may be filled with an electrically insulating or other second material having a positive TCE. The array of trenches may extend uniformly across the resonator body, including regions in the body that have relatively high and low mechanical stress during resonance. This two-dimensional array (or network) of trenches can be modeled as a network of mass-spring systems with springs in parallel and/or in series with respect to a direction of a traveling acoustic wave within the resonator body during resonance.
33 Citations
12 Claims
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1. A method of forming a micromechanical resonator operable in a bulk acoustic mode, comprising:
-
forming a resonator body anchored to a substrate by at least a first anchor, said resonator body comprising a first material having a negative temperature coefficient of elasticity (TCE) and an array of spaced-apart trenches filled with a second material having a positive TCE, said array of spaced-apart trenches having a sufficient density in the resonator body to meet the following relationship;
1≦
−
RV(TCEI/TCES)[(EI/ES)+(ρ
I/ρ
S)1/2(EI/ES)−
1/2]≦
3,where RV=(VI/VS);
TCES, ES, ρ
S and VS represent the temperature coefficient of elasticity, Young'"'"'s modulus, density and volume of the first material in the resonator body, respectively; and
TCEI, EI, ρ
I and VI represent the temperature coefficient of elasticity, Young'"'"'s modulus, density and total volume of the second material in the array of spaced-apart trenches, respectively.- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12)
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Specification
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- Resources
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Current AssigneeGeorgia Tech Research Corporation (University System of Georgia)
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Original AssigneeGeorgia Tech Research Corporation (University System of Georgia)
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InventorsAyazi, Farrokh, Tabrizian, Roozbeh, Casinovi, Giorgio
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Primary Examiner(s)Tugbang, A. Dexter
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Assistant Examiner(s)Carley, Jeffrey T
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Application NumberUS12/794,361Publication NumberTime in Patent Office998 DaysField of Search29/253.5, 295/921, 295/94, 295/95, 298/32, 298/46, 331/68, 331/154, 331/155, 333/187, 333/193US Class Current29/25.35CPC Class CodesH03H 2009/2442 Square resonatorsH03H 3/0076 for obtaining desired frequ...H03H 9/02448 of temperature influenceY10T 29/42 Piezoelectric device makingY10T 29/49005 Acoustic transducerY10T 29/49155 Manufacturing circuit on or...
