Multi-Dimensional Cross-Reactive Array for Chemical Sensing

Abstract

The discrimination ability of a chemical sensing cross-reactive arrays is enhanced by constructing sensing elements in two dimensions, first in the x-y plane of the substrate, second in the z dimension so that the sensors are vertically stacked on top of one another. Stacking sensing elements on top of one another adds to the discrimination ability by enabling the characteristic measurement of how fast target chemicals are passing through the stack of sensors. The new invention also allows the ability to discriminate components in a sample mixture by separating them using their innate difference in diffusional rates. Multi-sensor response patterns at each z level of sensors and time delay information from the sample passing from one level to the next are used to generate the response vector. The response vector is used to identify individual component samples and components in a mixture sample.

Claims

1. A multi-dimensional cross-reactive array for chemical sensing, comprising: a sensor substrate having stacks of sensor elements, wherein the sensor elements of a given stack are sequentially stacked such that each stack of sensor elements rises in a z direction from a respective stack area as a unique sequence of sensor layers on an x-y surface of the sensor substrate; and an enclosure enclosing the sensor substrate such that a carrier medium carrying a chemical sample can flow across the sequentially laid out stack areas on an x-y surface of the sensor substrate from one open end to another open end of the enclosure.

2. The multi-dimensional cross-reactive array as recited in claim 1, wherein said sensor substrate is based either on quartz for optical based sensors or silicon for electrical based sensors.

3. The multi-dimensional cross-reactive array as recited in claim 1, wherein said carrier medium is either a gas or liquid sample carrier medium.

4. The multi-dimensional cross-reactive array as recited in claim 1, wherein said sensor elements are stacked in intimate contact one on top of another so that the only way for said sample chemical to interact with underlying sensor elements is to pass by diffusion through the sensor element on top of it, whereby the stacking of the sensor elements adds a time dependent response to the underlying sensor elements based upon diffusion of the sample through the upper sensor layers.

5. The multi-dimensional cross-reactive array as recited in claim 1, wherein a stack of sensor elements is based on its respective sequence of the following fluorescent polymers layers: Poly[2,5-bisoctyloxy)-1,4-phenylenevinylene] with a emission between 540-560 nm; Poly(9,9-dioctylfluorene-alt-benzothiadiazole) with emission between 515-535 nm; and Poly[(9,9-dihexylfluoren-2,7-diyl)-co-(anthracen-9,10-diyl)] with emission between 450-435 nm.

6. The multi-dimensional cross-reactive array as recited in claim 1, wherein a sensor element in a stack is based on a composite mix of fluorescent nanocrystals of a respective nanocrystal size and a non-fluorescent polymer chosen from Poly(vinyl stearate), Poly(benzyl methacrylate), Poly(methyl methacrylate) and Poly(ethylene-co-vinyl acetate).

7. The multi-dimensional cross-reactive array as recited in claim 1, wherein a stack of sensor elements is based on a set of CdSe nanocrystals of sizes 2.2, 2.5 3.3, 4.5 nm with emission maxima of 480, 520, 560, 600 nm, respectively; a sensor layer being associated with a unique nanocrystal size so that different sensor layers of the stack can be monitored independently.

8. The multi-dimensional cross-reactive array as recited in claim 1, wherein a stack of sensor elements is based on a stack of chemiresistors with an insulating buffer layer in between them, said chemiresistors being chosen from a group consisting of modified carbon nanotubes, carbon nanotube polymer composites, and polymer carbon black composites.

9. The multi-dimensional cross-reactive array as recited in claim 1, wherein a non-responsive permeable buffer layer is added in between the sensor layers to increase a migration time between sensors.

10. The multi-dimensional cross-reactive array as recited in claim 1, wherein the sensor elements are stacked sequentially in a row along the flow path.

11. The multi-dimensional cross-reactive array as recited in claim 1, wherein the sensor elements are z-stacked by stamping of the fluorescent polymer and/or polymer composite materials.

12. The multi-dimensional cross-reactive array as recited in claim 1, wherein the sensor elements are z-stacked by inkjet printing of sensor layers with a buffer layer between stacked sensors.

13. A chemical sensing device based on a multi-dimensional cross-reactive array, comprising: a multi-dimensional cross-reactive array disposed along a flow path based on a sensor substrate having a plurality of stacks of sensor elements, wherein the sensor elements of a stack are sequentially stacked such that a stack of sensor elements rises as a respective sequence of fluorescent layers; a light source focused onto the multi-dimensional cross-reactive array to cause each of the stacked sensor elements to emit a respective fluorescence; an optical system based on fiber optic cables for passing the respectively emitted light from each stack of sensors to a respective spectrometer elements to produce a respective spectrometer output; and a computing device connected to receive and process each spectrometer output for select wavelength bands to characterize each fluorescent layer in the sensor stack associated with the respective spectrometer output throughout the array.

14. The chemical sensing device based on a multi-dimensional cross-reactive array as recited in claim 13, wherein the light source is based on a 365 nm LED.

15. The chemical sensing device based on a multi-dimensional cross-reactive array as recited in claim 13, wherein each fluorescent layer in a sensor stack is an individually addressable polymer layer with its associated spectrometer, each fluorescent polymer in a sensor stack yielding a distinct spectral characteristic to provide a robust cross-reactive array response.

16. The chemical sensing device based on a multi-dimensional cross-reactive array as recited in claim 13, wherein a sensor element in a stack is based on its fluorescent nanocrystal/polymer composite, wherein fluorescent emission is determined by its nanocrystal size.

17. A method of chemical sensing based on a multi-dimensional cross-reactive array, the method comprising the steps of: directing a flow path of a carrier medium carrying an unknown sample; disposing along the directed flow path a multi-dimensional cross-reactive array based on a sensor substrate having a plurality of stacks of sensor elements, a sensor element in a stack being based on a respective fluorescent layer; a light source focused onto the multi-dimensional cross-reactive array to cause the stacked sensor elements to emit a respective fluorescence; passing via an optical system the respective emissions of a stack of sensors to a respective spectrometer element to produce a respective spectrometer output; and receiving the spectrometer outputs by a computing device to process select wavelength bands to characterize each fluorescent polymer emissions per sensor stack associated with the respective spectrometer output to identify individual component samples and components in a mixture sample.

18. The method of chemical sensing according to claim 17, wherein a fluorescent layer is based on any one of: Poly[2,5-bisoctyloxy)-1,4-phenylenevinylene] with a emission between 540-560 nm; Poly(9,9-dioctylfluorene-alt-benzothiadiazole) with emission between 515-535 nm; and Poly[(9,9-dihexylfluoren-2,7-diyl)-co-(anthracen-9,10-diyl)] with emission between 450-435 nm.

19. The method of chemical sensing according to claim 17, wherein the spectrometer outputs are processed and select wavelength bands are monitored to characterize each fluorescent emissions per sensor stack, thereby the respective polymers being individually addressable with a spectrometer associated with a stack for a robust detection of cross-reactive array response.

20. The method of chemical sensing according to claim 17, wherein the select wavelength bands are processed by: generating a response vector based on multi-sensor response patterns at each z level of sensors and time delay information from the sample passing from one level to the next; and using the response vector to identify individual component samples and components in a mixture sample.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] Additional advantages and features will become apparent as the subject invention becomes better understood by reference to the following detailed description when considered in conjunction with the accompanying drawings wherein:

[0013] FIG. 1 shows an exemplary 2-dimensional cross-reactive array having a sensor substrate in an enclosure.

[0014] FIG. 2 shows an exemplary z-dimensional stacking of sensor elements.

[0015] FIG. 3 shows a schematic of an exemplary three polymer system excitation using a light source such as a 365 nm LED.

[0016] FIG. 4 shows exemplary spectral bands of three fluorescent polymer system.

[0017] FIG. 5 shows exemplary z-stacked sensors in which a non-responsive permeable buffer layer is added in between sensor layers.

[0018] FIG. 6a shows exemplary stacked sensor layers spaced in the x and y direction by impermeable blocking layers.

[0019] FIG. 6b shows an alternate stacking sensor layering in which successive sensor layer each completely covers the sensor layer below.

DETAILED DESCRIPTION

[0020] Methods of making artificial olfactory systems (cross-reactive arrays) rely on non-specific sensors which respond in concert generating a pattern that can be identified as the odorant impinging upon the sensor. The response pattern is formed by using chemically different sensors who response to a single analyte is varied. The difference of the sensors on the molecular level generates the varying changes in the transduction and features such as total magnitude of response, percent change of response, fitting of polynomial lines, and amount of spectral change are used to make the descriptive response patterns.

[0021] This invention adds more descriptive information to the response pattern by arranging the elements of a cross-reactive array in a 2 dimensional manner, the first dimension is the direction of the sample flow in the sensor so that the sample interacts with each sensor in a sequential manner through the gas or liquid sample carrier medium. This is shown in FIG. 1 where 1 the sensor substrate which can be quartz for optical based sensors or silicon for electrical based sensors is in an enclosure 2. The areas where the stacks of sensor elements are laid out so that the flow interacts with them sequentially in the flow path are show as elements 3-8. The first dimension is in the x and y plane of the substrate that the device is constructed on. The stacking of the sensors happens in the z-dimension of the substrate shown in FIG. 2 where elements 9-14 are stacks of sensing elements. In this exemplary embodiment, the sensors are stacked in intimate contact one on top of another so that the only way for a sample to interact with underlying sensors is to pass through the sensor on top of it. The stacking of the sensors adds a time dependent response to the underlying sensors based upon diffusion of the sample through the upper sensor layers. The sensors in each z-stack have to be responsive to the same classes of chemicals so that the passage of a chemical from one layer to the next can be measured. Each sensor in the z-stacked also needs to be individually addressable so each one can be monitored for changes over time. A way to make a stack of individually addressable stacked sensors is to use fluorescent polymers whose emission intensity is dependent on their local environment. Each of the fluorescent polymers in the z-stack have to have emission spectrums that are spectrally separated enough to monitor each emission peak with a spectrometer. An example of this type of fluorescent polymer z-stack are these three polymers; Poly[2,5-bisoctyloxy)-1,4-phenylenevinylene] (P1) with a emission between 540-560 nm, Poly(9,9-dioctylfluorene-alt-benzothiadiazole) (P2) with emission between 515-535 nm and Poly[(9,9-dihexylfluoren-2,7-diyl)-co-(anthracen-9,10-diyl)] (P3) with emission between 450-435 nm. This three polymer system is also excitable with a common light source such as a 365 nm LED. A schematic of this device is in FIG. 3, where 15 is an excitation light source such as a 365 nm LED. The light source 15 is focused onto the polymers P1-P3 causing them to emit fluorescence which is collected by an optical system such as a fiber optic cable seen as elements 16-21 which passes the emitted light from each stack of sensors to a separate spectrometer elements 22-27. All of the spectrometers are connected to a computer element 28 which is used to select wavelength bands from each spectrometer output characteristic of each fluorescent polymer in the sensor stacks for each stack throughout the array. The spectrums measured by each spectrometer and the selected spectral bands of this three fluorescent polymer system are shown in FIG. 4. Where elements 29-31 are the fluorescence emission spectrums of P1-P3 respectively. The bands which are monitored to characterize the different fluorescent polymers are indicate in elements 32-34. In addition to these polymers being individually addressable with a spectrometer they are so structurally different enough to provide a robust cross-reactive array response.

[0022] A second method of making a z-stack of fluorescent sensors is to use a fluorescent nanocrystal/polymer composite. Fluorescence emission from nanocrystals is a size dependent property with narrow emission spectrums. The nanocrystals narrow emission spectrums allow more sensors to be stacked in the z-direction and still be able to be spectrally resolved using a spectrometer. A z-stack sensor array can be constructed using a set of CdSe nanocrystals of sizes 2.2, 2.5 3.3, 4.5 nm with emission maxima of 480, 520, 560, 600 nm respectively in the same manner as FIGS. 3 and 4. This set of nanocrystal can then be mixed with any non-fluorescent polymer to add chemical diversity such as this set, Poly(vinyl stearate), Poly(benzyl methacrylate), Poly(methyl methacrylate), Poly(ethylene-co-vinyl acetate). Each stack of sensors in must only contain one composite of each size nanocrystal so that different layers of the stack can be monitored independently.

[0023] A third way of making individually addressable sensor is to use a stack of chemiresistors with insulating buffer layer in between them. An example of chemiresistor chemical sensor suitable for z-stacking include modified carbon nanotubes, carbon nanotube polymer composites, and polymer carbon black composites.

[0024] In all iterations of z-stacked sensors a non-responsive permeable buffer layer can be added in between the sensor layer to increase the migration time between sensors as seen in FIG. 5. Where elements 35, 37, 39, 40, 42, and 44 are sensors and elements 36, 38, 41, and 43 are permeable buffer layers. The buffer layers increase the resolution of multi-analyte samples by increasing the time selective differential partitioning happens between sensors. Buffer layers can include neat forms of the polymers used in the sensing composites or other types of polymers such as siloxanes used in gas chromatography. The diffusion time of the samples through the sensor is based upon the thickness of the sensor layers, density of the sensor layer, chemical interactions that take place, and the time added for the sample to pass through the buffer layer.

[0025] There are several methods for constructing an array of z-stacked sensors including, stamping, thermal evaporation, and inkjet printing. Stamping of the fluorescent polymer and polymer composite materials is done with a polydimethlsiloxane made with Dow Corning Sylgard 184 with is cast onto a template of the desired sensor size and allowed to cure. The cured stamp then has the fluorescent polymer or polymer composite spun cast onto it from a solvent. The solvent is evaporated from the stamp leaving a layer of the sensing material. The inked stamp is then placed sensor side down on the sensor substrate and heated above the glass transition temperature of the polymer. The stamp is then removed from the substrate leaving behind the sensor layer. This stamping process is repeated with different sensing layers in the same location on the substrate to form the z-stacked sensor array. Stamping can also be used to create the buffer layers between the sensor layers. It is ideal to have the sample chemicals enter the z-stack from the top of the stack and not from the side walls of the stack. To prevent unwanted intrusion in the sensor stack two methods can be used with stamping. First, is to stamp sensor layers between an impermeable blocking layers that are defined by photolithograph which are impermeable to the chemicals that are being sensed. The second method is to construct the layers in a manner where the over coating layers are larger in size and fully cover the underlying layers eliminating any sidewalls. These two methods are seen in FIGS. 6a and 6b, where in FIG. 6a, 45 and 46 are stacked sensor layers and in intimate contact with them in the x and y direction are elements 42-44 which are impermeable blocking layers. In FIG. 6b the closest sensor layer to the substrate 47 is then completely covered by the next sensor layer 48 which is then completely covered the next sensor layer 49 until the desired number of sensor layer is achieved.

[0026] Thermal evaporation of sensing layer can be achieved by multiple depositions of the sensing material on top of one another. The positions of the sensing material is defined by shadow masking the sensor substrate.

[0027] Inkjet printing can also create stacked sensor layer structures by using an immiscible solvent system with a buffer layer between sensors. This process involves printing the first layer such as a fluorescent polymer in an organic solvent like Chloroform. The next layer deposited would then need to be in a solvent that will not perturb the underlying layer such as a water solution of poly(diallydimethylammonium chloride). This process of immiscible solvent layers is then repeated until the desired number of sensor layer is achieved.

[0028] This system operates with a flow path of gas or liquid above the array of stacked sensors. Into that flow path pulses of samples are introduced to interact with the sensor. The sensors at each z level are monitored in the same manner as traditional cross-reactive arrays where each sensor's response in the array is analyzed, selecting characteristic features from it. The features from each sensor are then aggregated to create a feature vector. The feature vector is then compared to known feature vectors to make sample identification. This invention by stacking sensor elements adds new information to the feature vector that was previously not measureable. The new information is difference in time from when vertically adjacent sensors start to respond. This time is characteristic of how long it took of the analyte to pass through the top sensor. The information added to the response pattern is the diffusion constants, and difference in time it takes for each sensor to respond. The diffusion constant and time delay are two characteristic features that can be added to the response pattern for discrimination. The addition of non-responsive buffer layer between the sensor layers allows for tuning the time differential for chemicals passing through the stack of sensors improving the array discriminating ability. Also increasing the resolving power for multicomponent samples.

[0029] It is obvious that many modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as described.