CN100570755C - A kind of micro-cantilever resonator of low temperature cross sensitivity - Google Patents
A kind of micro-cantilever resonator of low temperature cross sensitivity Download PDFInfo
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- CN100570755C CN100570755C CNB2006100505143A CN200610050514A CN100570755C CN 100570755 C CN100570755 C CN 100570755C CN B2006100505143 A CNB2006100505143 A CN B2006100505143A CN 200610050514 A CN200610050514 A CN 200610050514A CN 100570755 C CN100570755 C CN 100570755C
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Abstract
The invention discloses a kind of micro-cantilever resonator that has than the low resonant frequency temperature coefficient.This resonator adopts silica/silicon or silicon dioxide/silicon nitride double-decker to realize the temperature self-compensation of semi-girder resonance frequency.Show that by Theoretical Calculation and experimental verification the silicon of the double-deck semi-girder resonator of silicon/silicon dioxide and the ratio of silica membrane optimal thickness are 1.1~1.7, the ratio of the silica membrane of the double-deck semi-girder resonator of silicon dioxide/silicon nitride and the optimal thickness of silicon nitride film is 0.9~1.2, silicon dioxide is wherein grown by thermal oxidation method, and silicon nitride is made by low-pressure vapor phase sedimentation (LPCVD).The micro-cantilever resonator of low temperature cross sensitivity disclosed in this invention have temperature compensation simple and easy to do, simple in structure, with low cost, do not need to introduce advantages such as extra temperature sensor, reference semi-girder and compensating circuit.
Description
Technical field
The present invention relates to a kind of micro-cantilever resonator of low temperature cross sensitivity, particularly a kind of difference of utilizing the temperature coefficient of different semiconductor material Young moduluss and density realizes the semi-girder resonator of the temperature self-compensation of resonance frequency, belongs to the microelectromechanical systems field.
Background technology
Sensor is the basis of test instrumentation and detection system, and traditional sensor comes non electrical quantities such as gaging pressure, temperature, displacement by changing electrical quantities such as resistance, electric capacity or inductance, and exports with the voltage and current signal.Need to increase A/D converter between sensor and control circuit, this has not only reduced reliability, response speed and the measuring accuracy of system, and has increased cost.The output quantity of resonant transducer is a frequency signal, precision and resolution height, and long-time stability are good, can realize interface with computing machine by simple digital circuit, thereby save complex structure, expensive A/D conversion equipment.Development resonant transducer, adaptation are that the digital control system at center is one of important directions of sensor development with the microprocessor.But now practical resonant transducer (as humorous vibration cylinder, resonance beam, responant diaphragm, resonance bend pipe) physical dimension is bigger, and complex structure costs an arm and a leg, and resonance frequency and sensitivity are low.Along with the development of microelectric technique and micromachining technology and the application in sensor,, caused people's special interest with the silicon micromachine resonant sensor that micromachining technology produces.The sensitive element of micromachine resonant sensor is micro-cantilever, microbridge (two-end fixed beam), the square film harmonic oscillators such as (or diaphragms) of making of microelectronics and micromechanical process, utilize its resonance frequency, amplitude or phase place etc. as responsive measured parameter, can be used to physical quantitys such as gaging pressure, vacuum tightness, angular velocity, acceleration, flow, temperature, humidity and gas componant.The energisation mode of resonator has electric magnetization, static excitation, contrary piezoelectric excitation, electric heating excitation, photothermal excitation etc., and its detection mode (being the pick-up mode) has piezoelectricity pick-up, voltage dependent resistor (VDR) pick-up, electromagnetism pick-up, capacitor vibration pick-up, optics pick-up etc.
Semi-girder resonator one end is fixed, other end freedom, and the unrelieved stress that free end forms in beam in the time of can discharging element manufacturing, resonance frequency are not subjected to the influence of encapsulation stress.The shape of semi-girder resonator has vertical bar shaped, variable cross section vertical bar shaped, U-shaped beam, three cantilevered corner beams, tuning fork beam etc., is used widely on devices such as atomic force microscope (AFM) probe (rapping pattern and noncontact mode), micromechanics electronic filter, oscillator, biochemical sensor.
Resonant transducer based on micro-cantilever is a research focus in moment sensor field, is with a wide range of applications.But variation of ambient temperature is bigger to the cross sensitivity of resonance frequency, has hindered the micro-cantilever resonant transducer to industrialized development.For example, the temperature coefficient of the resonance frequency of single-crystal silicon cantilever beam is-21ppm/ ℃~-45ppm/ ℃, the temperature coefficient of the resonance frequency of polysilicon semi-girder is-36ppm/ ℃.So big temperature coefficient its lower sensitivity relatively obviously is too big.The sensitivity that for example utilizes the MFI molecular sieve to detect fluorine Lyons gas is-0.0024%/ppm, as the temperature coefficient of the resonance frequency of this resonator at-21ppm/K, then environment temperature raise 10 ℃ cause resonance frequency be changed to-0.021% relatively, be equivalent to the change of resonance frequency that 8.75ppm fluorine Lyons gas causes, well beyond receptible limiting error.
In order to reduce the error that temperature is brought the micro-cantilever resonance frequency, can adopt the reference semi-girder to suppress undesired signal.But the introducing of reference semi-girder need be set up independently closed loop for it, has also increased the complicacy and the cost of chip structure, encapsulation and detection system greatly.In addition, only depend on the reference beam and suppress the requirement that ambient temperature effect can not satisfy high-acruracy survey fully.Therefore, be necessary to take appropriate measures and reduce the temperature coefficient of resonance frequency.
Summary of the invention
Purpose of the present invention is made a kind of micro-cantilever resonator of low temperature cross sensitivity.
For achieving the above object, the technical solution adopted in the present invention is: resonator adopts silica/silicon or silicon dioxide/silicon nitride double-decker.Since the Young modulus of silicon dioxide be on the occasion of, the temperature coefficient of the Young modulus of silicon and silicon nitride is a negative value, thereby the thickness of multilayer material of forming beam by choose reasonable is than the temperature coefficient realization self compensation of the resonance frequency that can make semi-girder, thereby is reduced to lower level.
Semi-girder resonator involved in the present invention can be realized the principle of resonance frequency temperature self-compensation: the resonance frequency of semi-girder and the length of beam and to form Young modulus, density and the thickness of multilayer material of beam relevant, thereby the temperature coefficient of thickness, thermal expansivity and the Young modulus of the temperature coefficient of semi-girder resonance frequency and the multilayer material of composition beam and density is relevant.Temperature coefficient by Theoretical Calculation semi-girder resonance frequency and to make it be zero can obtain forming the optimal thickness ratio of the multilayer material of semi-girder.The semi-girder that multilayer material is formed in this ratio should have lower temperature coefficient of resonance frequency.
According to above compensation principle, material commonly used in the semiconductor technology is carried out preferably, adopt silica/silicon or silicon dioxide/silicon nitride double-decker to realize the temperature self-compensation of semi-girder resonance frequency.In order to realize concrete excitation or detection means, excitation/detecting element can be made, on beam as reflector layer, metal connecting line, electrode, resistance etc.But if these width and beam width as the auxiliary layer material of excitation/detecting element can be compared (as reflector layer), then its thickness should be much smaller than the gross thickness of beam; If auxiliary layer thickness bigger (as metal connecting line), then its width should be much smaller than the width of beam.
As calculated and experimental results show that: (1) temperature coefficient of resonance frequency can be reduced to the silicon layer of the double-deck semi-girder of silicon/silicon dioxide of lower level and the optimal thickness ratio of silica membrane is 1.1~1.7.(2) temperature coefficient of resonance frequency can be reduced to the silica membrane of the double-deck semi-girder of silicon dioxide/silicon nitride of lower level and the optimal thickness ratio of silicon nitride film is 0.9~1.2, silicon dioxide is wherein grown by thermal oxidation method, and silicon nitride is made by low-pressure chemical vapor phase deposition method (LPCVD).
The micro-cantilever resonator of low temperature cross sensitivity involved in the present invention has following advantage: temperature compensation is simple and easy to do, and is simple in structure, with low cost, do not need to introduce extra temperature sensor, reference semi-girder and compensating circuit.
Description of drawings
Accompanying drawing 2 is the manufacture craft flow processs as the silicon/silicon dioxide semi-girder resonator of the photothermal excitation/optical signal detecting of one embodiment of the present of invention.
Accompanying drawing 3 is the manufacture craft flow processs as the silicon dioxide/silicon nitride semi-girder resonator of the photothermal excitation/optical signal detecting of one embodiment of the present of invention.
In the accompanying drawing:
1-backing material 2-silicon dioxide buried regions 3-forms the silicon dioxide layer of beam
4-silicon layer 5-silicon nitride layer 6-encourages resistance
7-pick-up resistance 8-forming tank 9-back side window
The 10-reflector layer
Embodiment
The present invention will be further described below in conjunction with drawings and Examples, but be not limited to this embodiment.
Present embodiment is a silicon/silicon dioxide semi-girder resonator of making a kind of photothermal excitation/optical signal detecting.Wherein, silicon layer [4] thickness is 1.3 microns, 1 micron of silicon dioxide layer [3] thickness, and its structure is shown in accompanying drawing 1 (a).Its manufacture craft flow process following (seeing accompanying drawing 2):
(1) original silicon chip is 400 micron thickness { 100} face twin polishing soi wafers.If its silicon dioxide buried regions [2] thickness is the t micron, then silicon layer [4] thickness should be (1.8+0.45t) micron.(see Fig. 2 .[1])
(2) thermal oxide, oxide layer [3] thickness are (1+t) micron.(see Fig. 2 .[2])
(3) positive photoetching semi-girder figure, the earth silicon mask in the forming tank [8] around slowly-releasing hydrofluorite (BOE) the corrosion beam.(see Fig. 2 .[3])
(4) silicon in the forming tank [8] around the anisotropic etchant corrosion beam is till exposing silicon dioxide buried regions [2].(see Fig. 2 .[4])
(5) back side photoetching forms back of the body corrosion window [9].(see Fig. 2 .[5])
(6) silicon of tetramethyl oxyammonia (TMAH) corrosive liquid of employing 25% corrosion back side window [9] is till exposing silicon dioxide buried regions [2].(see Fig. 2 .[6])
(7) the silicon dioxide buried regions [2] of slowly-releasing hydrofluorite (BOE) corrosion soi wafer, silicon dioxide layer [3] thickness in semi-girder front also can reduce simultaneously.The control etching time stops corrosion after silicon dioxide buried regions [2] is just removed fully, at this moment the silicon dioxide layer in beam front [3] thickness just is 1 micron.(see Fig. 2 .[7])
(8) the deposit gold film is as reflector layer [10], thickness 30 nanometers.(see Fig. 2 .[8])
Present embodiment is a kind of silicon dioxide/silicon nitride semi-girder resonator of photothermal excitation/optical signal detecting.Its structure is shown in accompanying drawing 1 (b).Its manufacture craft flow process following (seeing accompanying drawing 3):
(1) original silicon chip is { the common silicon chip of 100} face [1].(see Fig. 3 .[1])
(2) thermal oxide.(see Fig. 3 .[2])
(3) back side photoresist protection, positive photoetching semi-girder figure, the silicon dioxide in the forming tank [8] around slowly-releasing hydrofluorite (BOE) the corrosion beam.(see Fig. 3 .[3])
(4) LPCVD method deposition silicon nitride film [5], thickness are 0.9~1.2 times of silicon dioxide layer [3] thickness.The positive photoetching semi-girder of same mask figure is adopted in back side photoresist protection, and the silicon nitride film [5] in the beam forming tank [8] is on every side removed in corrosion.(see Fig. 3 .[4])
(5) back side photoetching, the silicon dioxide of slowly-releasing hydrofluorite (BOE) corrosion window [9].(see Fig. 3 .[5])
(6) adopt the silicon of 25% tetramethyl oxyammonia (TMAH) corrosive liquid corrosion back side window [9], till corrosion is worn the back rest and obtained discharging.(see Fig. 3 .[6])
(7) the deposit gold film is as reflector layer [10], thickness 30 nanometers.(see Fig. 3 .[7])
Claims (3)
1. the micro-cantilever resonator of a low temperature cross sensitivity, adopt silica/silicon or silicon dioxide/silicon nitride double-decker, it is characterized in that: the silicon layer of silica/silicon double-decker micro-cantilever resonator and the ratio of silicon dioxide layer thickness are 1.1~1.7, and the silicon dioxide layer of silicon dioxide/silicon nitride double-decker micro-cantilever resonator and the ratio of silicon nitride layer thickness are 0.9~1.2.
2. according to the micro-cantilever resonator of the described low temperature cross sensitivity of claim 1, it is characterized in that: silicon dioxide is wherein grown by thermal oxidation method, and silicon nitride is made by low-pressure chemical vapor phase deposition method (LPCVD).
3. the energisation mode according to the micro-cantilever resonator of described silica/silicon of claim 1 or the double-deck low temperature cross sensitivity of silicon dioxide/silicon nitride can be one of electric magnetization, static excitation, contrary piezoelectric excitation, electric heating excitation and photothermal excitation; Its detection mode can be one of piezoelectricity pick-up, capacitor vibration pick-up, electromagnetism pick-up, light signal pick-up and voltage dependent resistor (VDR) pick-up.
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KR20110049748A (en) | 2008-05-16 | 2011-05-12 | 드렉셀유니버시티 | System and method for evaluating tissue |
CN101451946B (en) * | 2008-12-26 | 2010-12-22 | 中国科学院上海微系统与信息技术研究所 | Method for implementing multi-substance detection by utilizing simple micromechanical cantilever beam |
EP2284629A1 (en) * | 2009-08-13 | 2011-02-16 | ETA SA Manufacture Horlogère Suisse | Thermocompensated mechanical resonator |
CN102706924B (en) * | 2012-06-21 | 2014-06-18 | 山东大学 | Device for realizing second-order resonant excitation of micro-cantilever probe |
CN103234648B (en) * | 2013-03-29 | 2015-09-23 | 清华大学 | A kind of polymkeric substance double-material micro beam and temperature sensitive structure |
CN103234669B (en) * | 2013-03-29 | 2015-04-01 | 厦门大学 | Pressure sensor utilizing electrostatic negative stiffness and production method of pressure sensor |
WO2014185280A1 (en) * | 2013-05-13 | 2014-11-20 | 株式会社村田製作所 | Vibrating device |
JP6482169B2 (en) * | 2013-07-19 | 2019-03-13 | セイコーエプソン株式会社 | Vibrating piece, vibrator, oscillator, electronic device and moving object |
CN108680246B (en) * | 2018-05-14 | 2020-11-06 | 中国科学院上海微系统与信息技术研究所 | Vibration mode recognition device and method based on threshold driving energy collector |
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CN1374249A (en) * | 2002-04-19 | 2002-10-16 | 清华大学 | Bending cantilever beam executor and its making process |
CN1381710A (en) * | 2002-06-07 | 2002-11-27 | 西安交通大学 | Frequency output type micromechanical dual-beam resonator with autoamtic temp compensation |
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CN1374249A (en) * | 2002-04-19 | 2002-10-16 | 清华大学 | Bending cantilever beam executor and its making process |
CN1381710A (en) * | 2002-06-07 | 2002-11-27 | 西安交通大学 | Frequency output type micromechanical dual-beam resonator with autoamtic temp compensation |
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