CN208076394U - A kind of optical waveguide biosensor sensor of low testing cost and temperature-insensitive - Google Patents

Abstract

A kind of optical waveguide biosensor sensor of low testing cost and temperature-insensitive, wideband light source including particular range of wavelengths, sense micro-loop, sensitive zones, sense the straight-through output end of micro-loop, sense the download output end of micro-loop, Mach increases Dare interferometer MZI, first output end of MZI, second output end of MZI, the detector A being connected with first output end of the MZI and detector B being connected with second output end of MZI, the wideband light source of the particular range of wavelengths is composed of the wavelength filter of common wide light source and required wave-length coverage, the wideband light source of the particular range of wavelengths is connected with the input terminal of sensing micro-loop, the download output end of the sensing micro-loop is connected with the input terminal of MZI, two output ends of MZI are connected with detector A and detector B respectively.The utility model has the characteristics that temperature-insensitive and low testing cost.

Description

A kind of optical waveguide biosensor sensor of low testing cost and temperature-insensitive

Technical field

The utility model is related to optical waveguide biosensor sensing detection field, especially a kind of temperature-insensitive has low detection The optical waveguide biosensor sensor of cost.

Background technology

Based on the optical waveguide sensor of toroidal cavity resonator (ring resonator), since there is high sensitivity, exempt from label It detection, in real time monitoring, the advantages that sample consumption is low, not by electromagnetic interference, plays in chemistry and biological sample analysis Very important role.In particular with high index-contrast platform (for example, silicon-on-insulator (SOI) Platform, the silicon platform on insulator) the super-small micro-loop realized, since its technique and traditional cmos process are completely simultaneous Hold, and be expected to realize on the same chip with the hybrid integrated of the devices such as semiconductor light source, detector and microfluidic control unit, It is final to realize miniaturization, a portable multifunctional sensing detector.

However, since silicon materials have larger thermo-optical coeffecient (1.86 × 10^-4/ K) so that the sensing based on silicon materials is micro- Ring is very sensitive to the variation of environment temperature, and the drift of resonance wavelength can reach 50pm/ DEG C.So in sensing detection process In, if minor change occurs in environment temperature, this all can be to the essence of sensing micro-loop testing result (the resonance wavelength variable quantity of micro-loop) Exactness has an important influence on.In order to eliminate influence of the variation of ambient temperature to sensing micro-loop testing result, a kind of common method It is exactly to use temperature controller (N.A.Yebo, et an al, " On-chip arrayed waveguide grating interrogated silicon-on-insulator microring resonator-based gas sensor,”IEEE Photon.Technol.Lett., vol.23, no.20, pp.1505-1507,2011), it may ensure that environment temperature exists always One stationary temperature, but the method increase size, cost and the complexities etc. of sensing micro-loop detecting system, are unfavorable for big Scale on piece is integrated.Another method is by additional device (D.-X.Xu, et al, " Real-time cancellation of temperature induced resonance shifts in SOI wire waveguide ring resonator Label-free biosensor arrays, " Opt.Express, vol.18, no.22, pp.22867-22879,2010), than Such as variation of ambient temperature is monitored in real time using a reference rings, the result of reference rings is then utilized to believe from the detection of sensing micro-loop Temperature is eliminated in number to be influenced, and this method needs additional data processing.

In addition, the test to sensing micro-loop mainly calculates detectable substance in micro-loop by monitoring the variation of its resonance wavelength The case where.Since the resonance peak of micro-loop is more sharp, i.e. Q values are higher, this is allowed for peak wavelength position permanent normal need really The detection of micro-ring sensor is significantly increased by the high-precision tunable laser in periphery either high-precision spectrometer Cost is unfavorable for its application in portable sensor.In order to solve this problem, on piece spectrometer is used to monitoring micro-loop Wavelength change situation, such as J.Zou et al. (J.Zou, Z.Le, and J.-J.He, " Temeprature self- compensated optical waveguide biosensor based on cascade of ring resonator and arrayed waveguide grating spectrometer,”J.Lightwave Technol.,34(21), ) and N.A.Yebo et al. (N.A.Yebo, et al, " On-chip arrayed waveguide pp.4856-4863,2016 grating interrogated silicon-on-insulator microring resonator-based gas Sensor, " IEEE Photon.Technol.Lett., vol.23, no.20, pp.1505-1507,2011) propose utilize piece Cascade array waveguide grating spectrometer is gone up to realize the measurement to sensing micro-ring resonant wavelength change.In this scenario due to needing High-resolution array waveguide grating is wanted, causes such array waveguide grating size larger, it is also incomplete in technique at this stage The device performance is less ideal in the case of maturation, also can accordingly decline to being accurate to for micro-ring resonant wavelength measurement.

Invention content

In order to solve the problems, such as that tradition senses the temperature sensitivity that micro-loop encounters in the detection and high expensive testing cost, to meet Its demand in the sensing detection application of portable low cost, the utility model provides a kind of based on sensing micro-loop and Mach Increase the cascade optical waveguide sensor of Dare interferometer, it has the characteristics that temperature-insensitive and low testing cost.

The purpose of this utility model is achieved by the following technical solution：

A kind of optical waveguide biosensor sensor of low testing cost and temperature-insensitive, includes the broadband light of particular range of wavelengths Source, sensing micro-loop, sensitive zones, the straight-through output end for sensing micro-loop, the download output end for sensing micro-loop, Mach increase Dare interference First output end of instrument MZI, MZI, second output end of MZI, the detector A being connected with first output end of MZI and The detector B being connected with second output end of MZI, the wideband light source of the particular range of wavelengths is by common wide light source and institute The wavelength filter of wave-length coverage is needed to be composed, the input terminal of the wideband light source and sensing micro-loop of the particular range of wavelengths Be connected, the download output end of the sensing micro-loop is connected with the input terminal of MZI, two output ends of MZI respectively with spy Device A is surveyed with detector B to be connected.

Further, the upper arm waveguide of the MZI is by two kinds of width w₀And w₁Composition, w₀And w₁Between pass through lossless taper Waveguide connects；The underarm waveguide of MZI is by two kinds of width w₀And w₂Composition, w₀And w₂Between pass through lossless tapered transmission line and connect； The upper underarm width of MZI is w₀Waveguide between length difference be Δ L, width is w in upper underarm₁And w₂Waveguide length be L_a, and L_a Meet relational expression L with Δ L_a=x × Δ L, wherein x are temperature dependency regulatory factor；Duct width w₀、w₁And w₂And x is really Surely to meet MZI with variation of ambient temperature wavelength shift and sensing micro-loop resonance wavelength in detectable substance with environment temperature The wavelength shift of variation is identical, i.e. the two temperature dependency having the same.

Further, the waveguiding structure of the sensing micro-loop and MZI are bar shaped or ridge, and sense the sensing unit of micro-loop Domain and with protection top covering MZI be in identical detection sample, i.e., detection sample cover sensitive zones and MZI, when When sensing micro-loop and MZI temperature dependencies having the same, the duct width w of micro-loop is sensed_sWith the duct width parameter w of MZI₀、 w₁And w₂And meet following relational expression between x

Wherein λ₀Initial resonant wavelength for the sensing micro-loop selected in design,WithIt is wide respectively Degree is w_sWhen sense micro-loop waveguide effective refractive index and group index,WithIt is respectively Waveguide in MZI is w in width_iWhen corresponding effective refractive index and group index.

Further, the sensing micro-ring resonant wavelength is λ_s, the performance number I that obtains in detector A_A(λ_s) and detection The performance number I obtained in device B_B(λ_s), define detection functionWork as λ_sTo include λ₀MZI's inside In the wave-length coverage of half of Free Spectral Range when variation, the cross-coupling coefficient k of the outbound course coupler of MZI_mSelection Satisfaction makes R (λ_s) in the wave-length coverage and λ_sBetween have maximum linear relationship range.

The utility model is when carrying out the analysis of sensing detection object, it is assumed that the resonance of inductive sensing micro-loop when initial time t=0 Wavelength is λ₀, detection function value is R (λ₀), it is λ to the resonance wavelength of inductive sensing micro-loop in moment t_t, detection function value is R (λ_t), R (λ₀) and R (λ_t) all it is always positioned at R (λ_s) linear relationship within the scope of.Simultaneously in determining cross-coupling coefficient k_mUnder, R (λ_s) linear relationship range size can change by adjusting the Free Spectral Range size of MZI.

When carrying out the analysis of sensing detection object, R (λ are utilized_s) and λ_sBetween linear relationship slope value, pass through t moment and t The detection function value changes delta R (Δ R=R (λ at=0 moment_t)-R(λ₀)) resonance wave long value changes delta λ in sensing micro-loop is extrapolated, Actually detected object is extrapolated further according to the relationship between the concentration variation and sensing micro-ring resonant wavelength change Δ λ of detection and analysis object Situation of change.

The beneficial effects of the utility model are mainly manifested in：1, the testing cost to sensing micro-loop is reduced；2, sensing is solved The temperature tender subject encountered in micro-loop detection；3, application of the micro-loop in miniaturization, portable sensing detection is realized；4, it It can be realized in different material platforms, such as silicon nitride (Si₃N₄) and the platforms such as silicon (Si).

Description of the drawings

Fig. 1 be the utility model proposes a kind of low testing cost and temperature-insensitive optical waveguide biosensor sensor tool Body embodiment structure schematic diagram；

Fig. 2 be the utility model proposes optical waveguide biosensor sensor structure in the regions MZI enlarged diagram；

Fig. 3 is the enlarged drawing of temperature dependency adjustment region in MZI；

Fig. 4 is the sectional view at AA ' in Fig. 1, i.e., the cross-sectional view of micro-loop waveguide is sensed in sensitive zones；

Fig. 5 is the sectional view at BB ' in Fig. 1, i.e. waveguide cross-section schematic diagram in MZI；

Fig. 6 be the utility model proposes optical waveguide sensor realize temperature-insensitive detection schematic diagram；

Fig. 7 is that the waveguide of sensing micro-loop corresponds to different waveguide width when highly for 250nm and aqueous solution as top covering Under, the ability of TE basic modes and TM basic modes perception solution variations in refractive index in waveguide；

Fig. 8 be duct height be 250nm when sensing micro-loop resonance wavelength and MZI spectrum under different waveguide width The duct width w selected in temperature dependency and below design_s、w₀、w₁And w₂；

Fig. 9 is the temperature dependency of MZI at 1550nm with the variation relation of x.

Figure 10 is the relationship for sensing the related correlation of the temperature of both the MZI of micro-loop to x=3.5 when with wavelength change Figure；

Figure 11 is that the light intensity of two output port in the wave-length coverage of a Free Spectral Range of MZI becomes with wavelength The schematic diagram of change；

Figure 12 (a) is the power ratio between two output port in the wave-length coverage of a Free Spectral Range of MZI Natural logrithm value ρ with the schematic diagram of wavelength change, be (b) near the intermediate wavelength of (a) in a Free Spectral Range Enlarged drawing；

Figure 13 is the outbound course coupler cross-coupling coefficient k in MZI_mIt takesWhen, sense the one way of micro-loop waveguide Transmission loss a corresponding detection function R (λ when taking different value_s) with the resonance wavelength of sensing micro-loop_sThe relational graph of variation；

Figure 14 is the one way Transmission loss a=0.98 for sensing micro-loop waveguide, directional coupler from coefficient of coup r₁ =r₂=0.99, work as λ_sTo include λ₀Corresponding R when variation in the wave-length coverage of half of Free Spectral Range of MZI inside (λ_s) situation of change, that is, sense micro-loop detection before calibration curve；

Figure 15 be the utility model proposes optical waveguide sensor respectively under three environment temperatures, when the temperature phase of MZI When closing property is equal to temperature dependency of the sensing micro-loop in solution to be detected, detection function R is reflected with sensitive zones detection solution The relational graph of rate variation；

Figure 16 be the utility model proposes optical waveguide sensor respectively under three environment temperatures, when not having in MZI When temperature dependency adjustment region, i.e. MZI temperature dependencies are not equal to the temperature dependency for sensing micro-loop, detection function R is with biography Feel the relational graph of region detection solution variations in refractive index.

In figure：1, the wideband light source of particular range of wavelengths, 2, sense micro-loop input terminal, 3, sensing micro-loop, 4, sensing it is micro- The duct width w of ring_s, 5, sensitive zones, 6, sense the straight-through output end of micro-loop, 7, sense the download output end of micro-loop, 8, MZI, 9, first output end of MZI, 10, second output end of MZI, 11, the detection being connected with first output end of MZI Device A, 12, the detector B being connected with second output end of MZI, 13, the upper arm waveguide of MZI, 14, width w₀Waveguide, 15, the underarm waveguide of MZI, 16, the temperature dependency adjustment region in MZI, 17, the outbound course coupler of MZI, 18, waveguide Width is from w₀Change to w₁Noenergy lose spot-size converter, 19, width w₁Waveguide, 20, width w₁Waveguide length Degree is L_a, 21, duct width is from w₀Change to w₂Noenergy lose spot-size converter, 22, width w₂Waveguide, 23, width For w₂Waveguide length be L_a, the docking of 24, two spot-size converters 21, the docking of 25, two spot-size converters 18.

Specific implementation mode

The utility model is further described below in conjunction with the accompanying drawings.

Referring to Fig.1~Figure 16, a kind of optical waveguide biosensor sensor of low testing cost and temperature-insensitive, including certain wave The wideband light source 1 of long range, sensing micro-loop 3, sensitive zones 5, the straight-through output end 6 for sensing micro-loop, the download of sensing micro-loop are defeated Outlet 7, Mach increase first output end 9 of Dare interferometer MZI8, MZI, second output end 10 of MZI, first with MZI The detector B12 a output end connected detector A11 and be connected with second output end of MZI, the particular range of wavelengths Wideband light source 1 be composed of the wavelength filter of common wide light source and required wave-length coverage, the specific wavelength model The wideband light source 1 enclosed is connected with the input terminal 2 of sensing micro-loop, the input of the download output end 7 and MZI of the sensing micro-loop End is connected, and two output ends 9,10 of MZI are connected with detector A11 and detector B12 respectively.

The upper arm waveguide 13 of MZI is by two kinds of width w₀14 and w₁19 compositions, w₀14 and w₁Pass through lossless cone between 19 Shape waveguide 18 connects；The underarm waveguide 15 of MZI is by two kinds of width w₀14 and w₂22 compositions, w₀14 and w₂Pass through nothing between 22 The tapered transmission line 21 of damage connects；The upper underarm width of MZI is w₀Waveguide between length difference be Δ L, width is w in upper underarm₁And w₂ Waveguide length be L_a, and L_aMeet relational expression L with Δ L_a=x × Δ L, wherein x are temperature dependency regulatory factor；Waveguide is wide Spend w₀、w₁And w₂And the determination of x will meet resonance wavelengths of the MZI with the wavelength shift of variation of ambient temperature and sensing micro-loop It is identical with the wavelength shift of variation of ambient temperature in detectable substance, i.e., temperature dependency both having the same.

The waveguiding structure for sensing micro-loop 3 and MZI 8 is ridge or bar shaped, and senses the sensitive zones 5 of micro-loop 3 and have The MZI 8 of protection top covering is in identical detection sample, that is, is detected sample and covered sensitive zones 5 and MZI 8, such as Fig. 4 Shown in sensing micro-loop 3 waveguide cross-section schematic diagram and MZI shown in fig. 58 waveguide cross-section schematic diagram, work as sensing When 8 temperature dependency having the same of micro-loop 3 and MZI, the duct width w of micro-loop 3 is sensed_sThe duct width of 4 and MZI 8 is joined Number w₀ 14、w₁19 and w₂Meet following relational expression between 22 and x

Wherein λ₀Initial resonant wavelength for the sensing micro-loop selected in design,WithIt is wide respectively Degree is w_sThe effective refractive index and group index of micro-loop waveguide are sensed when 4,WithIt is respectively Waveguide in MZI 8 is w in width_iWhen corresponding effective refractive index and group index.

Sensing micro-ring resonant wavelength is λ_s, the performance number I that obtains in detector A 11_A(λ_s) and detector B 12 in obtain Performance number I_B(λ_s), define detection functionWork as λ_sTo include λ₀Half of MZI 8 inside is freely In the wave-length coverage of spectral region when variation, the cross-coupling coefficient k of the outbound course coupler 17 of MZI_mSelection satisfaction make R (λ_s) in the wave-length coverage and λ_sBetween have maximum linear relationship range.

When carrying out the analysis of sensing detection object, it is assumed that be λ to the resonance wavelength of inductive sensing micro-loop 3 when initial time t=0₀, Detection function value is R (λ₀), it is λ to the resonance wavelength of inductive sensing micro-loop 3 in moment t_t, detection function value is R (λ_t), R (λ₀) With R (λ_t) all it is always positioned at R (λ_s) linear relationship within the scope of.Simultaneously in determining cross-coupling coefficient k_mUnder, R (λ_s) line Sexual intercourse range size can change by adjusting the Free Spectral Range size of MZI 8.

When carrying out the analysis of sensing detection object, R (λ are utilized_s) and λ_sBetween linear relationship slope value, pass through t moment and t The detection function value changes delta R (Δ R=R (λ at=0 moment_t)-R(λ₀)) extrapolate resonance wave long value changes delta in sensing micro-loop 3 λ is extrapolated actually detected further according to the relationship that the concentration of detection and analysis object changes between sensing micro-ring resonant wavelength change Δ λ The situation of change of object.We will be further elaborated the utility model with actual example below：

Using the utility model proposes sensor structure as shown in Figure 1, realize on the SOI platforms to sensing micro-loop On piece low cost and temperature-insensitive detection.First, we carry out a theory to the operation principle of device architecture shown in FIG. 1 It introduces.

Assuming that the directional coupler being connected between the input terminal 2 and sensing micro-loop 3 of sensing micro-loop from the coefficient of coup and Cross-coupling coefficient is (r₁,k₁), and they meet relational expression r₁ ²+k₁ ²=1, while sensing the download output end 7 of micro-loop and passing The directional coupler being connected between sense micro-loop 3 from the coefficient of coup and cross-coupling coefficient be (r₂,k₂), and meet relational expression r₂ ²+k₂ ²=1, then sense the transmission spectrum T of micro-loop 3_d(λ) can be expressed as

Wherein, a is the one way amplitude transmission factor for sensing micro-loop, it includes the transmission loss and two when ring transmits one week The loss introduced in directional coupler；L_rIt is the ring perimeter for sensing micro-loop 3, n_eff(w_s) it is the effective refraction for sensing micro-loop waveguide Rate.

Similarly, two output ends 9 of MZI 8 shown in Fig. 1 and 10 transmission spectral function T_M1(λ) and T_M2(λ) can be with It is expressed as

Wherein k_mIt is the cross-coupling coefficient of the outbound course coupler 17 of MZI, Δ L is the upper arm waveguide 13 of MZI under Width is w between arm waveguide 15₀Waveguide 14 length difference, x is that width is w in 13 and 15₁And w₂Waveguide length L_aWith Δ L Between ratio, i.e. x=L_a/ΔL；n_eff(w₀)、n_eff(w₁) and n_eff(w₂) be respectively width be w₀、w₁And w₂Waveguide correspond to Effective refractive index.

Assuming that the resonance wavelength of sensing micro-loop is λ_s, i.e., corresponding wavelength at Energy maximum value in formula (1), then institute in Fig. 1 The performance number obtained in the detector A 11 and detector B 12 that show can be expressed as

Wherein S (λ) is particular range of wavelengths (i.e. λ_-To λ₊) wideband light source 1 output spectrum, it is to be noted here that In light source light spectrum range lambda_-To λ₊It is interior, sense micro-loop download output end 7 frequency spectrum in only there are one resonance peak occur.Utilize formula (5) and the ratio of the result of (6) takes logarithm that can define a sensing micro-ring resonant wavelength X_sDetection function R (λ_s), it can be with It is expressed as

Since light source light spectrum S (λ) is already contained in formula (5) and (6), therefore the R (λ in (7)_s) value and light source light spectrum tremble It is dynamic unrelated.Meanwhile the result of formula (7) is by the cross-coupling coefficient k of MZI outbound courses coupler 17_mInfluence, later we It can be seen that the suitable k of selection_mIt can make R (λ_s) and λ_sBetween have larger linear relationship range, be conducive to large range of Sensing detection.

For sensing micro-loop, resonance wave strong point λ_sResonance Equation can be expressed as

n_eff(w_s)·L_r=m_rλ_s (8)

Wherein m_rIt is diffraction time.λ can be obtained using formula (8)_sWith the relationship of variation of ambient temperature, i.e. temperature dependency, It can be expressed as

Wherein n_g(w_s) it is to sense micro-loop duct width as w_sWhen in λ_sThe group index at place.

Similarly, for the MZI 8 in Fig. 1, transmission spectrum can be expressed as

n_eff(w₀)·ΔL+(n_eff(w₁)-n_eff(w₂)) x Δs L=m_m·λ_m (10)

Wherein m_mIt is diffraction time.λ in MZI spectrum_mIt is with the correlation of variation of ambient temperature

N in formula_g(w₀)、n_g(w₁) and n_g(w₂) it is that duct width takes w in MZI respectively₀、w₁And w₂When corresponding group index. It can be seen that effective folding of basic mode in the temperature dependency for sensing the humorous spectrum of micro-loop and MZI spectrum and waveguide from formula (9) and (11) The temperature dependency for penetrating rate is related, i.e.,Simultaneously in formula (11), the temperature dependency of MZI spectrum is also w with width₁ And w₂Temperature dependency difference the being temperature dependent property regulatory factor x of waveguide is related.

Fig. 6 give this civilization proposition to sense micro-ring resonant wavelength X_sRealize the principle signal of temperature-insensitive detection Figure.Assuming that environment temperature, there are one minor change Δ T, corresponding sensing micro-ring resonant wavelength shift is Δ λ_Ts, the spectrum of MZI Drift value is Δ λ_Tm.As can be seen from Figure 6 as Δ λ_Tm>Δλ_Ts, probe function value is from R₀Become R₂；As Δ λ_Tm<Δλ_Ts, detection Functional value is from R₀Become R₁；However work as Δ λ_Tm=Δ λ_Ts, probe function value remains unchanged.So being wanted in structure proposed in this paper Sensing micro-loop and MZI temperature dependencies having the same are asked, i.e. formula (9) and (11) is for same wavelength value having the same. Assuming that λ₀Initial resonant wavelength for the sensing micro-loop selected in design, the temperature-insensitive to meet the wavelength detect, then formula (9) and after (11) simultaneous meet following relationship

WhereinWithBe respectively width be w_sSensing micro-loop waveguide in λ₀The effective refractive index at place and Group index,WithBe waveguide in MZI respectively in width it is w_iWhen correspond to λ₀Place has Imitate refractive index and group index.

Then we design example the realization of the utility model is expanded on further with one.

Use material：Commercial SOI wafer, top layer silicon thickness are 250nm, and insulation buried oxide layer is 3 μm.In addition to sensing Outside the sensitive zones of micro-loop, the top covering of entire chip is silicon dioxide layer of protection, in order to ensure sensing micro-loop 3 and MZI 8 have There are identical environment temperature contact conditions, the two is placed in together in the microchannel that stream has detection solution, Fig. 4 and Fig. 5 are provided The waveguide cross-section schematic diagram of the two can be ridge (a) or bar shaped (b) etc., and also stream has detection molten to the top covering of MZI 8 Liquid.Herein, it will be assumed that the detection solution that sensitive zones flow through is pure water, and waveguide cross-section is bar shaped, that is, Fig. 4 b and 5b.Fig. 7 The silicon that thickness is 250nm is given, top covering is aqueous solution, under different waveguide width, TE basic modes and TM basic modes in waveguide Effective refractive index with aqueous solution variations in refractive index relational graph.From this figure, it can be seen that TM basic modes perception aqueous solution refractive index becomes The ability of change is better than TE basic modes, therefore we select work polarization state of the TM basic modes as waveguide in the design below.

Fig. 8 gives when silicon duct thickness is 250nm, and top covering is respectively SiO₂When with pure water, corresponding MZI and biography The schematic diagram that the temperature dependency of sense micro-loop changes with duct width.From this figure, it can be seen that the temperature phase of MZI and sensing micro-loop Closing property increases with the increase of duct width, simultaneously for identical width, temperature of the temperature dependency than sensing micro-loop of MZI Greatly at least 10pm/ DEG C of correlation.In view of requiring and sensing the single mode operation requirement of micro-loop waveguide in actual process, we select Sense the width w of micro-loop waveguide_s, conventional waveguide width w in MZI₀With narrow duct width w₁It is 450nm, while wide wave in MZI Lead width w₂For 800nm.Fig. 9 provides the variation relation for giving the temperature dependency of MZI with temperature dependency regulatory factor x, It can be seen that under specific duct width, by changing x, the temperature dependency of MZI can be arbitrary value.It is new according to this practicality To realize temperature-insensitive detection described in type, the temperature phase of MZI should be equal to by sensing temperature dependency of the micro-loop in detecting solution Guan Xing, as can be seen from Figure 9 in λ both as x=3.5₀There is equal temperature dependency at=1550nm wavelength.Figure 10 gives Go out the temperature dependency of the MZI and both sensing micro-loops in x=3.5 with the schematic diagram of wavelength change, it can be seen that With wavelength departure initial designs wavelength X₀When, the temperature dependency difference of the two gradually increases, but relatively small at one In wave-length coverage, such as in the wave-length coverage of 1540~1555nm, the temperature dependency difference of the two is less than 0.5pm/ DEG C.Due to In actual detection, sense the wave length shift of micro-loop generally in the wave-length coverage of very little, such as in 5nm, still can be with One small range of selection simultaneously allows sensing micro-loop to be operated in the wave-length coverage, we can be approximately considered the two in the range in this way Interior temperature dependency having the same.

After determining the temperature dependency regulatory factor x in MZI, it would be desirable to obtain such a detection relationship be exactly In required detection range, make as far as possible detection function value R and sense micro-loop resonance wavelength between there are larger linear passes It is that there are larger linear relationship ranges between range namely R and object concentration to be detected variation.It is defeated that Figure 11 gives MZI two Transmission spectral function in the wave-length coverage of a Free Spectral Range of exit port centered on by 1550nm wavelength, therefrom can be with Find out the cross-coupling coefficient k in the outbound course coupler of MZI_mWhen taking different value, the corresponding performance number of two output ports Difference, in order to further analyze the two performance numbers and k_mBetween relationship, we with reference to formula (7), definition WhereinWithIt is provided by formula (2) and (3).Figure 12 gives free light centered on by 1550nm wavelength For ρ with the schematic diagram of wavelength change, Figure 12 b give the amplification in the centre wavelength region of the Free Spectral Range in spectral limit Figure, there it can be seen that with k_mIncrease, the linear relationship range that ρ changes with λ first becomes larger to be reduced afterwards, while the linear model The slope for enclosing region increases always.So to k_mSelection when, between linear relationship range and slope value there are one compromise. Herein, we choose larger linear relationship range, obtain and work as from Figure 12 bWhen, in a freedom between ρ and λ There is maximum linear relationship range in the wavelength region of spectral region.However in actual application, due to the suction of aqueous solution It receives, there is light a degree of energy loss, the energy loss to pass through amplitude transmission factor a when being propagated in sensing micro-loop<1 It embodies, senses the width at the transmission peak maximum of micro-loop downloading end and usually indicated with half maximum value overall with, i.e.,

It can be seen that for wirelessly close to 1 r₁And r₂And the ring of energy loss, i.e. a=1, FWHM do not become wirelessly Be bordering on 0, the peak value sharpness of the corresponding ring is higher, which can also be indicated with the Q values of ring, i.e., resonance wavelength and The ratio of FWHM, Q=λ_s/FWHM.In addition, it can be seen that for the sensing micro-loop with energy loss, in a<When 1, FWHM is total It is greater than 0, i.e., always there is certain width at actual sensing micro-ring resonant peak.Figure 13 gives half of free spectrum in MZI In the wave-length coverage of range, different amplitude transmission factor a, i.e., different resonance peak spectrum widths is to detection function R (λ_s) influence, ρ (λ) in figure corresponds to ideally, i.e. the case where when FWHM=0, is derived from Figure 12Situation.It can see Go out, when a changes are small, i.e., corresponding ring loss becomes larger, detection function value R (λ_s) it is gradually deviated from ρ values ideally, and phase The range of linearity region answered also reduces.So when actually detected, due to the unknown of amplitude transmission factor a, needing when detecting The corresponding R values of sensing micro-loop are calibrated first.

Herein our theoretical validations once the utility model proposes sensor structure sensing capability.Assuming that sensing is micro- Ring has following parameter：r₁=r₂=0.99, a=0.98, L_r=50 μm, w_s=450nm, n_g(w_s)=4.522, m_r=64, just Beginning resonance wavelength is λ₀=1550nm；MZI has following design parameter：w₀=w₁=450nm, w₂=800, x=3.5,FSR_m=8nm, λ_m=1550nm, m_m=58.125, L=72.63 μm of Δ.For ease of comparing, we also design one A region for not having temperature dependency to adjust in MZI, i.e. x=0, major parameter are as follows：λ_m=1550nm, m_m=85.125, L=67.77 μm of Δ, FSR_m=8nm.According to the parameter of sensing micro-loop, it is about 1.1 × 10 that we, which can calculate its Q value,⁴, the Q Value can be obtained easily very much using CMOS technology ripe at present.Figure 14 gives bent to sensing the calibration of micro-loop before detection Line senses the resonance wavelength of micro-loop_sIn the wave-length coverage of half of Free Spectral Range centered on MZI is by 1551nm wavelength Variation.R (λ are can be seen that from the curve_s) all meet linear relationship, and Linear Quasi in the very wide range of the wave-length coverage The degree of correlation of conjunction is equal to 1.

Assuming that using the NaCl solution (various concentration corresponds to different refractivity) of various concentration as sensing analysis object, simultaneously Sensing micro-loop is in three different environment temperatures, i.e., detection knot when room temperature, room temperature change 10 degree, room temperature changes 20 degree Fruit.Figure 15 gives the detected value R that sensor structure used by the utility model the obtains relationships changed with detection liquid concentration Figure, it can be seen that linear characteristic is presented with the variation of detection liquid concentration in R, and in same detection liquid, the value of R Do not change with the variation of environment temperature, i.e., to the utility model proposes sensor, to sense micro-loop testing result only with The variation for detecting liquid concentration is related.Figure 16 gives the testing result that temperature dependency regulatory factor is not introduced into MZI, therefrom It can be seen that detected value R is related with the variation of detection liquid concentration and variation of ambient temperature, this will cause our actually detected results Prodigious error.It can be seen that the utility model proposes sensor structure can solve the temperature that encounters in sensing micro-loop detection Sensitive question is spent, simultaneously because introducing cascade MZI carries out the testing cost that power detection greatly reduces sensing micro-loop.

Claims (4)

1. the optical waveguide biosensor sensor of a kind of low testing cost and temperature-insensitive, which is characterized in that the optical waveguide biosensor Sensor includes the wideband light source of particular range of wavelengths, sensing micro-loop, sensitive zones, the straight-through output end for sensing micro-loop, sensing Micro-loop download output end, Mach increases first output end of Dare interferometer MZI, MZI, second output end of MZI, with The detector B first output end of MZI connected detector A and be connected with second output end of MZI, the specific wavelength The wideband light source of range is composed of the wavelength filter of common wide light source and required wave-length coverage, the specific wavelength The wideband light source of range is connected with the input terminal of sensing micro-loop, the input of the download output end and MZI of the sensing micro-loop End is connected, and two output ends of MZI are connected with detector A and detector B respectively.

2. the optical waveguide biosensor sensor of low testing cost and temperature-insensitive as described in claim 1, which is characterized in that institute The upper arm waveguide of MZI is stated by two kinds of width w₀And w₁Composition, w₀And w₁Between pass through lossless tapered transmission line and connect；The underarm of MZI Waveguide is by two kinds of width w₀And w₂Composition, w₀And w₂Between pass through lossless tapered transmission line and connect；The upper underarm width of MZI is w₀Wave Length difference is Δ L between leading, and width is w in upper underarm₁And w₂Waveguide length be L_a, and L_aMeet relational expression L with Δ L_a=x × Δ L, wherein x are temperature dependency regulatory factor；Duct width w₀、w₁And w₂And the determination of x will meet MZI with environment temperature The wavelength shift of variation and the resonance wavelength of sensing micro-loop are identical with the wavelength shift of variation of ambient temperature in detectable substance, That is the two temperature dependency having the same.

3. the optical waveguide biosensor sensor of low testing cost and temperature-insensitive as claimed in claim 1 or 2, feature exist In the waveguiding structure of the sensing micro-loop and MZI are bar shaped or ridge, and sense the sensitive zones of micro-loop and have in protection The MZI of covering is in identical detection sample, that is, is detected sample and covered sensitive zones and MZI, when sensing micro-loop and MZI tools When having identical temperature dependency, the duct width w of micro-loop is sensed_sWith the duct width parameter w of MZI₀、w₁And w₂And between x Meet following relational expression

Wherein λ₀Initial resonant wavelength for the sensing micro-loop selected in design,WithBe respectively width be w_s When sense micro-loop waveguide effective refractive index and group index,WithIt is in MZI respectively Waveguide is w in width_iWhen corresponding effective refractive index and group index.

4. the optical waveguide biosensor sensor of low testing cost and temperature-insensitive as claimed in claim 1 or 2, feature exist In the sensing micro-ring resonant wavelength is λ_s, the performance number I that obtains in detector A_A(λ_s) and detector B in the power that obtains Value I_B(λ_s), define detection functionWork as λ_sTo include λ₀Half of Free Spectral Range of MZI inside Wave-length coverage in variation when, the cross-coupling coefficient k of the outbound course coupler of MZI_mSelection satisfaction make R (λ_s) in the wave In long range and λ_sBetween have maximum linear relationship range.