CN113533454B - Three-dimensional nanotube-based gas sensor, manufacturing method and application thereof - Google Patents
Three-dimensional nanotube-based gas sensor, manufacturing method and application thereof Download PDFInfo
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/02—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance
- G01N27/04—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance by investigating resistance
- G01N27/12—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating impedance by investigating resistance of a solid body in dependence upon absorption of a fluid; of a solid body in dependence upon reaction with a fluid, for detecting components in the fluid
- G01N27/125—Composition of the body, e.g. the composition of its sensitive layer
- G01N27/127—Composition of the body, e.g. the composition of its sensitive layer comprising nanoparticles
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y15/00—Nanotechnology for interacting, sensing or actuating, e.g. quantum dots as markers in protein assays or molecular motors
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y30/00—Nanotechnology for materials or surface science, e.g. nanocomposites
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y40/00—Manufacture or treatment of nanostructures
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A50/00—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE in human health protection, e.g. against extreme weather
- Y02A50/20—Air quality improvement or preservation, e.g. vehicle emission control or emission reduction by using catalytic converters
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Abstract
The invention relates to a three-dimensional nanotube-based gas sensor, a manufacturing method and application thereof, wherein the method comprises the following steps: the three-dimensional nano tube array penetrates through the anodic aluminum oxide film and allows gas to circulate from two ends of the three-dimensional nano tube, a sensing area which takes the three-dimensional nano tube as a substrate and is deposited with a gas sensitive material is arranged between a first electrode on the first surface of the anodic aluminum oxide film and a second electrode on the second surface of the anodic aluminum oxide film, at least one first electrode and at least one second electrode form an electrode pair which is arranged at two ends of the sensing area, wherein the surfaces of the gas sensitive materials of different sensing areas in the three-dimensional nano tube sensor array are provided with different metal nano particle modifications, and therefore one sensing area has at least two gas sensitivities. The invention integrates a three-dimensional nanotube array by combining a wire bonding technology and an upper and lower crossing electrode technology, finishes the extraction of upper and lower electrodes, and realizes a three-dimensional nanotube sensor array capable of detecting various gases simultaneously.
Description
The invention discloses a three-dimensional nanotube gas sensor array and a packaging method thereof, wherein the application date is 2020, 7, 21, the application number is 202010709099.8, and the application type is the divisional application of an invention patent.
Technical Field
The invention relates to the technical field of intelligent sensing, in particular to a three-dimensional nanotube-based gas sensor, a manufacturing method and application thereof.
Background
The three-dimensional double-pass nanotube substrate, represented by a double-pass anodic aluminum oxide (Free-standing Anodized Aluminum Oxide) film, has wide application prospects in the fields of gas sensors, photoelectric sensors, light-emitting diodes, solar cells, variable resistance memories and the like. Particularly in the field of gas sensors, the nano-sized gas-sensitive material film is deposited on the tube wall, so that the extremely high specific surface area can be achieved, the high-sensitivity rapid detection at room temperature can be realized, and a higher working temperature is not required to be kept all the time. In particular, by selecting different gas sensitive material electrodes, the integration of a plurality of sensors can be realized on a single three-dimensional nanotube substrate, and the three-dimensional nanotube gas sensor array is subjected to chip integration, so that the data reading of the sensor array with high density can be realized.
The existing gas sensor arrays are mostly planar structures, and signals of the sensor arrays can be led out to a chip carrier by integrating a plurality of interdigital electrodes (Finger electrodes) or a plurality of Source-drain Electrode pairs (Source-Drain Electrode Pair) on a monolithic substrate and depositing different gas sensor materials and matching with wire bonding. For example, the solutions disclosed in documents Solid-state electronics, vol.51, no.1, p.69-76 (2007) and Sensors and Actuators B, vol.247, 903-915 (2017).
The existing gas sensor array packaging technology is only aimed at a planar gas-sensitive material film, and is not compatible with a three-dimensional nanotube structure. The electrodes of the film gas-sensitive material are coplanar electrodes, and the electrodes of the three-dimensional nanotube sensor are upper and lower electrodes and are not coplanar, so that the current packaging technology cannot be applied to the packaging of the three-dimensional nanotube sensor.
For example, chinese patent CN108614009a discloses a method for manufacturing a tubular spoke-type nanotube array carrier gas sensor, a sensor and applications thereof. The sensor manufacturing method comprises the following main process steps: winding a platinum wire, acid-base surface treatment, shape shaping, lead cutting, tubular die design, die processing, die surface spraying, die heating, molten metal aluminum, injection into a die, vacuum pumping, demolding and drilling, electrochemical in-situ growth, high-temperature heat treatment, aluminum nitrate solution soaking, platinum palladium modification, lead nitrate solution soaking, high-temperature pyrolysis, lead welding and packaging, and a gas sensor. The tubular spoke-type nanotube array is encapsulated in an isolated open-pore tube shell to form a tubular spoke-type nanotube array carrier gas sensor that does not directly encapsulate three-dimensional nanotube material.
Chinese patent CN109781686a discloses a nano sensor array for detecting human respiratory gas, the nano sensor array comprises a plurality of nano gas sensors made of composite films of different nano materials, and the nano sensor array is characterized in that: the nano gas sensors are distributed in an array, and the plurality of nano gas sensors are respectively provided with a TGS822 sensor, a TGS825 sensor, a TGS826 sensor and a TGS2602 sensor. The nano sensor array for detecting the human respiratory gas is characterized in that quantum fluorescent dots are used as optical indicators for optical sensing application, namely chemical vapor phase detection, classification and identification, a unique combined response is established for each target gas, and the gas can be detected, and qualitative and quantitative analysis and judgment can be carried out on the gas by using the unique combined response array sensor. Although this patent uses quantum fluorescent dots to improve the sensitivity of the component to be lifted and to quantitatively detect the component, the package structure is not improved. That is, the packaging structure of the current nanosensor array is still not improved.
Furthermore, there are differences in one aspect due to understanding to those skilled in the art; on the other hand, as the inventors studied numerous documents and patents while the present invention was made, the text is not limited to details and contents of all that are listed, but it is by no means the present invention does not have these prior art features, the present invention has all the prior art features, and the applicant remains in the background art to which the rights of the related prior art are added.
Disclosure of Invention
The structure of the sensor array in the prior art is arranged, so that the sensor array needs to be provided with more electrodes, and the third electrodes lack fixing devices, so that the structure of the third electrodes is unstable, and the transmission of data signals is greatly affected.
In order to overcome the defects in the prior art, the invention provides a packaging method of a three-dimensional nanotube gas sensor array, which is characterized by comprising the following steps: a three-dimensional nanotube gas sensor array is established that includes several sensing regions of differing gas sensitivity. The three-dimensional nano sensor array can simultaneously respond to various gases by establishing the sensing areas with differentiated gas sensitivity, and can detect more gas types.
Shorting a plurality of first electrodes which are arranged along a first direction on the first surface of the anodic aluminum oxide film and correspond to the sensing area in a wire bonding mode; and connecting a common second electrode which is arranged along a second direction on the second surface of the anodic aluminum oxide film and corresponds to the sensing area with a third electrode on the first surface of the ceramic layer. The arrangement mode of the electrodes is beneficial to reducing the number of the third electrodes and is also beneficial to the brief arrangement of the circuit.
Preferably, the first electrodes arranged along the first direction and arranged at the start end or the end are connected with at least one third electrode in an idle state on the first surface of the ceramic layer, and the third electrode in the idle state is in the same column/row in the first direction as the third electrode connected with the common second electrode. The invention connects all signals to the bottom bonding pad, which is beneficial to the quick connection with the PCB of the application end by reflow soldering and other modes.
Preferably, a sensing area which takes the three-dimensional nano tube as a substrate and is deposited with a gas-sensitive material is arranged between a first electrode on the first surface of the anodic aluminum oxide film and a second electrode on the second surface of the anodic aluminum oxide film, and at least one first electrode and at least one second electrode form an electrode pair arranged at two ends of the sensing area. The arrangement of the electrode pairs shortens the current flow path and can accelerate the response speed of the gas-sensitive material to gas detection.
Preferably, a plurality of third electrodes on the first surface of the ceramic layer form bonding pads capable of being welded with the chip on the second surface of the bottom of the ceramic layer in a via hole mode, and the plurality of third electrodes form a third electrode array, so that electric signals or data transmitted by the third electrodes are rapidly transmitted to the chip for data extraction.
Preferably, under the condition that the first direction and the second direction are mutually perpendicular, a plurality of sensing areas taking the three-dimensional nano tube as a substrate are arranged in a matrix array mode to form a three-dimensional nano sensor array. The arrangement of the invention is advantageous in that an independent gas sensor is formed between the electrode pairs. The sensor array detects several gases simultaneously.
Preferably, the surfaces of the gas sensitive materials of different sensing areas in the three-dimensional nanotube sensor array are provided with different metal nano particle modifications, so that one sensing area has at least two gas sensitivities, and the three-dimensional nanotube sensor array forms a detection platform capable of simultaneously detecting multiple gases. According to the invention, different metal nanoparticle modifications are arranged in one sensing area, so that at least two gases can be detected in one sensing area. The three-dimensional nano sensor array can detect the gas types which are increased according to the multiple levels, so that the gas detection capability of the sensor array is further expanded.
Preferably, the packaging method further comprises: and depositing a gas-sensitive sensing material with a certain thickness into the pipe wall of the three-dimensional nano-pipe based on an atomic layer deposition method or an ultrasonic spray pyrolysis method, wherein the gas-sensitive sensing material comprises a metal oxide semiconductor material, and two ends of the three-dimensional nano-pipe are in a through state after the deposition of the gas-sensitive material is completed. More sensitive gas sensitivity is advantageously created by metal oxide semiconductor gas sensitive material deposition.
Preferably, the packaging method further comprises: different metal nanoparticle solutions are deposited on different areas of the three-dimensional nanotube wall so that the three-dimensional nanosensor array forms a differential response to different gases. So arranged, a sensing region between one electrode pair is formed with the capability of detecting at least two gases.
Preferably, the non-sensing area, the routing area and the exposed part of the first surface of the ceramic layer, which are not covered by the electrode, in the first surface of the anodic aluminum oxide film are integrally covered by an epoxy resin layer. Preferably, ultraviolet rays are used for curing the epoxy resin layer, so that protection of the metal connecting wires and further fixation of the three-dimensional nanotube substrate are realized.
The three-dimensional nanotube gas sensor array is characterized by comprising a plurality of sensing areas with differentiated gas sensitivity, wherein a plurality of first electrodes which are arranged along a first direction and correspond to the sensing areas on the first surface of an anodic aluminum oxide film are in short connection in a wire bonding mode; the common second electrode arranged along the second direction on the second surface of the anodic aluminum oxide film and corresponding to the sensing area is connected with the third electrode on the first surface of the ceramic layer.
The three-dimensional nanotube gas sensor array is characterized in that a first electrode which is arranged along a first direction and is arranged at the initial end or the tail end is connected with at least one third electrode in an idle state on the first surface of the ceramic layer, and the third electrode in the idle state is in the same column/row in the first direction with the third electrode connected with a shared second electrode.
The three-dimensional nanotube gas sensor array is characterized in that a sensing area which takes a three-dimensional nanotube as a substrate and is deposited with a gas-sensitive material is arranged between a first electrode on the first surface of an anodic aluminum oxide film and a second electrode on the second surface of the anodic aluminum oxide film, and at least one first electrode and at least one second electrode form an electrode pair arranged at two ends of the sensing area.
According to the three-dimensional nanotube gas sensor array, a plurality of third electrodes on the first surface of the ceramic layer form bonding pads capable of being welded with chips on the second surface of the bottom of the ceramic layer in a through hole mode, and the third electrodes form a third electrode array.
According to the three-dimensional nanotube gas sensor array, under the condition that the first direction and the second direction are perpendicular to each other, a plurality of sensing areas taking three-dimensional nanotubes as substrates are arranged in a matrix array mode to form the three-dimensional nanotube gas sensor array.
According to the three-dimensional nanotube gas sensor array, different metal nano particle modifications are arranged on the surfaces of gas sensitive materials of different sensing areas in the three-dimensional nanotube gas sensor array, so that one sensing area has at least two gas sensitivities, and the three-dimensional nanotube gas sensor array forms a detection platform capable of simultaneously detecting multiple gases.
According to the three-dimensional nanotube gas sensor array, a gas-sensitive sensing material with a certain thickness is deposited in the wall of the three-dimensional nanotube, the gas-sensitive sensing material comprises a metal oxide semiconductor material, and after the deposition of the gas-sensitive material is completed, two ends of the three-dimensional nanotube are in a through state.
According to the three-dimensional nanotube gas sensor array, different metal nanoparticle solutions are deposited in different areas of the wall of the three-dimensional nanotube, so that the three-dimensional nanotube gas sensor array forms differential response to different gases.
The invention also provides a manufacturing method of the three-dimensional nanotube-based gas sensor, which comprises the following steps: the three-dimensional nano tube array penetrates through the anodic aluminum oxide film and allows gas to circulate from two ends of the three-dimensional nano tube, a sensing area which takes the three-dimensional nano tube as a substrate and is deposited with a gas sensitive material is arranged between a first electrode on the first surface of the anodic aluminum oxide film and a second electrode on the second surface of the anodic aluminum oxide film, at least one first electrode and at least one second electrode form an electrode pair which is arranged at two ends of the sensing area, wherein the surfaces of the gas sensitive materials of different sensing areas in the three-dimensional nano tube sensor array are provided with different metal nano particle modifications, and therefore one sensing area has at least two gas sensitivities.
Preferably, the method further comprises: different metal nanoparticle solutions are deposited on different areas of the three-dimensional nanotube wall so that the three-dimensional nanosensor array forms a differential response to different gases.
Preferably, the method further comprises: and depositing a gas-sensitive sensing material with a certain thickness into the pipe wall of the three-dimensional nano-pipe based on an atomic layer deposition method or an ultrasonic spray pyrolysis method, wherein the gas-sensitive sensing material comprises a metal oxide semiconductor material, and two ends of the three-dimensional nano-pipe are in a through state after the deposition of the gas-sensitive material is completed.
Preferably, the method further comprises: shorting a plurality of first electrodes which are arranged along a first direction on the first surface of the anodic aluminum oxide film and correspond to the sensing area in a wire bonding mode; and connecting a common second electrode which is arranged along a second direction on the second surface of the anodic aluminum oxide film and corresponds to the sensing area with a third electrode on the first surface of the ceramic layer.
Preferably, the method further comprises: and a plurality of third electrodes on the first surface of the ceramic layer form a bonding pad which can be welded with a chip on the second surface of the bottom of the ceramic layer in a via hole mode, and the third electrodes form a third electrode array.
Preferably, the method further comprises: in case the first direction and the second direction are perpendicular to each other,
the sensing areas taking the three-dimensional nanotubes as the substrate are arranged in a matrix array mode to form a three-dimensional nano sensor array.
Preferably, the first electrodes arranged along the first direction and arranged at the start end or the end are connected with at least one third electrode in an idle state on the first surface of the ceramic layer, and the third electrode in the idle state is in the same column/row in the first direction as the third electrode connected with the common second electrode.
The invention also provides a three-dimensional nanotube-based gas sensor, which at least comprises a three-dimensional nanotube array, an anodic aluminum oxide film and electrodes, wherein the three-dimensional nanotube array penetrates through the anodic aluminum oxide film and allows gas to circulate from two ends of the three-dimensional nanotube, a sensing area taking the three-dimensional nanotube as a substrate and deposited with a gas sensitive material is arranged between a first electrode on the first surface of the anodic aluminum oxide film and a second electrode on the second surface of the anodic aluminum oxide film, at least one first electrode and at least one second electrode form an electrode pair arranged at two ends of the sensing area, and different metal nanoparticle modifications are arranged on the surfaces of the gas sensitive materials of different sensing areas in the three-dimensional nanotube sensor array, so that one sensing area has at least two gas sensitivities.
Preferably, the three-dimensional nanotube gas sensor array includes several sensing regions of differential gas sensitivity, wherein different metal nanoparticle solutions are deposited on different regions of the three-dimensional nanotube tube wall, such that the three-dimensional nanotube gas sensor array forms a differential response to different gases.
The invention also provides application of the three-dimensional nanotube-based gas sensor, and the three-dimensional nanotube-based gas sensor is used for detecting at least two gases simultaneously.
Drawings
FIG. 1 is a schematic structural view of a three-dimensional nanotube structure of the present invention;
FIG. 2 is a schematic structural view of a sensor array of the three-dimensional nanotube structure of the present invention;
fig. 3 is another structural schematic diagram of a sensor array of the three-dimensional nanotube structure of the present invention.
List of reference numerals
51O: a first electrode; 520: a second electrode; 530 a third electrode; s1: a sensing region; AAO: anodic aluminum oxide film; epoxy: an epoxy resin; BB: a ceramic layer; a: a first direction; b: a second direction.
Detailed Description
The following detailed description refers to the accompanying drawings.
As shown in fig. 1, the present invention provides a method for packaging a three-dimensional nanotube gas sensor array, which includes: and shorting a plurality of first electrodes 51O arranged along the first direction and corresponding to the sensing region S1 on the first surface of the anodic aluminum oxide film AAO in a wire bonding manner. The common second electrode 520 arranged in the second direction on the second surface of the anodic aluminum oxide film AAO and corresponding to the sensing region S1 is connected to the third electrode 530 on the first surface of the ceramic layer. The invention integrates three-dimensional nanotube structure by combining wire bonding technology and upper and lower crossing electrode technology, and finishes the extraction of upper and lower electrodes. The first direction of the present invention refers to the arrangement direction in which the first electrodes 510 are shorted in columns. The second direction of the present invention is perpendicular to the first direction. The present invention includes several sensing regions, and the sensing region S1 in fig. 1 is only an example. Preferably, the sensing region is a surface region of a three-dimensional nanotube wall based on a three-dimensional nanotube. The three-dimensional nanotubes penetrate the anodized aluminum film AAO and allow gas to flow through from both ends.
In the present invention, the gas sensitive material covered on the wall of the nano three-dimensional nanotube between each pair of upper and lower opposing first and second electrodes forms a sensing region. That is, the area between each pair of the first and second electrodes opposing each other up and down is a sensing area. The current flows from the upper electrode to the lower electrode along the gas sensitive material on the nanotube wall or the current flows from the lower electrode to the upper electrode along the gas sensitive material on the nanotube wall. When the gas sensor is contacted with the gas, the gas diffuses into the through holes from the upper surface and reacts with the gas sensitive material on the pipe wall, so that the resistance between the upper electrode and the lower electrode is changed, and the gas sensing is realized.
Preferably, the first electrodes 510 arranged in the first direction and corresponding to the sensing regions and arranged at the start or end of the sensing region are connected to at least one third electrode 530 in an idle state on the first surface of the ceramic layer, as shown in fig. 1. The third electrode 530 in the idle state is in the same column/row in the first direction as the third electrode to which the common second electrode is connected. The advantage of this arrangement is that: the first electrode and the third electrode form a complete electric loop, sensing data acquired by the sensing area S1 can be effectively transmitted to the chip through the third electrode in the ceramic layer, and the circuit is neat and not easy to be confused. Furthermore, each sensing area is an independent sensor. Shorting the first electrodes of the n sensors and connecting to the third electrode that is idle, the total number of third electrodes is equal to the number of sensors plus one, i.e., n+1. According to the invention, n+n electrodes are not required to be arranged, and signals of all n sensors can be read only by arranging n+1 electrodes. The invention can also effectively reduce the manufacturing procedure and the manufacturing cost by reducing the number of the point sets.
Preferably, a plurality of third electrodes forming a third electrode array on the first surface of the ceramic layer form bonding pads capable of being welded with the chip on the second surface of the bottom of the ceramic layer in a via mode. Forming the third electrode as a pad in the manner of a via hole has an advantage in that each of the electrical signals or data transmitted through the third electrode can be rapidly transmitted to the chip for data extraction. Through the packaging mode, all signals are connected to the bonding pads at the bottom, and the signals can be quickly connected with the PCB at the application end through reflow soldering and the like.
Preferably, the non-sensing area of the first surface of the anodized aluminum film, which is not covered by the electrode, the wire bonding portion, and the exposed portion of the first surface of the ceramic layer are integrally covered with an epoxy resin layer. The advantage of such a cover package is that: on one hand, the epoxy resin isolates the metal connecting wire from air, so that the influence of oxygen and humidity in the air on the conductivity of the metal wire is eliminated; on the other hand, the epoxy resin can enhance the adhesiveness between the three-dimensional nanotube substrate and the ceramic substrate after being cured, and enhance the mechanical stability of the whole device.
Preferably, as shown in fig. 2, a sensing region for collecting gas components is formed in the anodized aluminum film by electrically connecting the first electrode and the second electrode. Thus, in case the first direction and the second direction are perpendicular to each other, the several sensing areas form a sensing array based on the arrangement of the first electrode and the second electrode. The advantage of forming a matrix sensor array is that it facilitates a uniform distribution of the acquisition area to obtain more gas data analysis. The sensor array can uniformly acquire the data of the volatile organic compounds in the gas through the uniform distribution of the sensing areas, so that the probability of missing the data of the gas components is reduced, the monitoring of the gas components is more accurate, and the sensitivity is higher. In another aspect, the present invention also enables the selection of different metal nanoparticle modifications to be performed on the surface representations of the gas sensitive material in different sensing regions, such that each sensing region is a unique gas sensor. The sensitivity of the sensing area to different gases is different, so that a sensor array is integrated on a single chip, and a platform for multi-gas detection is built. Furthermore, the three-dimensional nanosensor array can be arranged in a matrix array, but also in other arrays, such as a staggered array. The three-dimensional nano sensor matrix array has the advantage that after one sensing area fails, the other sensing areas can still work independently, and the whole gas detection effect is not affected.
Preferably, as shown in fig. 3, in the case where the second direction is tangential perpendicular to the first direction, the sensing region forms a sensing array in the form of a circular array based on the arrangement of the first electrode and the second electrode.
The packaging method of the three-dimensional nanotube gas sensor array further comprises the following steps:
s1: and depositing metal oxide semiconductor gas-sensitive sensing materials with the thickness of a plurality of nanometers in the pipe wall of the three-dimensional nanotube substrate of the upper through hole and the lower through hole. After the deposition of the gas sensitive material is finished, the three-dimensional nanotube substrate still maintains the state of the upper through hole and the lower through hole.
Specifically, a metal oxide semiconductor gas-sensitive sensing material is deposited in the pipe wall of the three-dimensional nano-pipe substrate by utilizing an atomic layer deposition (Atomic Layer Deposition) or ultrasonic spray pyrolysis (Ultrasonic Spray Pyrolysis) method to form a sensing area. The thickness of the three-dimensional nanotube substrate ranges from 10 to 50um, and the pore diameter ranges from 100 to 500nm. The three-dimensional nanotube substrate is represented by an anodic aluminum oxide film AAO, and can be other films, such as an anodic titanium oxide film ATO.
S2: and depositing different metal nanoparticle solutions in different sensing areas of the three-dimensional nanotube substrate to form the three-dimensional nanotube substrate with differential sensing. After the deposited three-dimensional nanotube substrate is calcined in 200-DEG inert gas, different metal particle modifications exist on the surfaces of gas-sensitive materials in different areas, so that differential response to different gases is realized. The metal nanoparticle solution comprises gold, platinum, silver and other particle solutions.
For example, if one sensing region is provided with a different metal particle modification, each sensing region can have a differential response of the individual gases. For a sensor array with m sensing areas, at most m gases can be detected and differentially responded.
For example, one sensing region can have a differential response of two gases by providing two different metal particle modifications. Then a maximum of 2m gases can be detected and responded to for a sensor array with m sensing areas.
Preferably, at least two metal particle modification areas in the sensing area of the three-dimensional nano sensor can be longitudinally divided according to the axial direction of the pipe wall to form a longitudinal sensing area. Preferably, the two metal particle modification regions are respectively provided with a plurality of longitudinal strip-shaped regions, for example, which can be staggered. The advantage of this arrangement is that the gas can be detected and responded correspondingly in the path through which the gas passes, and in particular the corresponding gas can be detected at the port where the gas enters the three-dimensional nanosensor array, thereby reducing the dead zone of detection. Preferably, the sensing region is not limited to the arrangement of two kinds of metal particle modification regions, but may divide a larger variety of metal particle modification regions in the longitudinal direction. Several methods for forming the modification of metal particles in longitudinal sub-regions are available, and with the development of technology, more and more technological means are available. For example, a three-dimensional nanotube substrate having three-dimensional nanotube portions divided in the longitudinal direction, respectively, may be used to splice into a complete three-dimensional nanotube, which is then packaged. Or, shielding is carried out step by step in the deposition process by adopting a nano-scale shielding object, so that longitudinal zonal deposition is realized.
Preferably, at least two metal particle modification regions in the sensing region of the three-dimensional nanosensor may be divided according to the circumference of the pipe wall, thereby forming an annular detection region. Preferably, the detection areas are arranged according to the half-circumferential area, and the two metal particle modification areas are arranged in the same radial direction and in a staggered manner, so that the detection areas of two gases exist at the port of the three-dimensional nano sensor at the same time, and the sensitivity of the three-dimensional nano gas sensor array is improved. Preferably, the sensing region is not limited to the arrangement of two kinds of metal particle modification regions, but a larger variety of metal particle modification regions may be divided in the circumferential direction. For example, a plurality of thin three-dimensional nanotube substrates respectively provided with different metal particle modifications are spliced up and down, so that the three-dimensional nanotubes of the two substrates are coaxially arranged with the same radius in the longitudinal direction, and the two three-dimensional nanotubes are communicated in the longitudinal direction, thereby realizing different distribution of the metal particle modifications in the circumferential direction.
Preferably, at least two metal particle modified regions in the sensing region of the three-dimensional nanosensor may be adjacently disposed in a spiral curve-shaped region in the tube wall. Compared with longitudinal division and circumferential division, the staggered arrangement of the spiral curve-shaped areas is more beneficial to the sensitivity response of different metal particle modification on the gas-sensitive material. As long as the gas passes through the three-dimensional nano tube, the metal particle modification on the gas-sensitive material can detect the corresponding gas at any position on the two ends and the tube wall and respond, and the method is not limited by the limitation of dividing dead zones in the longitudinal direction and the circumferential direction. Therefore, the three-dimensional nano sensor array arranged in this way has higher detection sensitivity and higher response speed to gas. For example, in the simplest form, the surface on which the gas sensitive material is deposited is provided with a spiral nanoscale shielding wire, sheet or other shielding member to achieve a spiral-shaped metal particle-modifying region. The technical means for achieving the same technical effect of the present invention is not limited thereto, and may be other technical means having the same technical effect.
Preferably, at least two kinds of metal particles are mixed and arranged on a sensing area of the three-dimensional nano sensor in a point mode, so that a dead zone for detecting certain gases does not exist in the sensing area, and the detection of various gases is facilitated. The mixing arrangement includes uniform mixing as well as non-uniform mixing.
Preferably, a plurality of metal particles are deposited on the gas-sensitive material in an unordered way according to the modification mode of particle aggregation, which is more beneficial to improving the detection sensitivity of the sensing area to various gases. Particle agglomeration refers to the agglomeration of metal particles into clusters of particles by a polymer that does not affect detection and then deposition onto a gas sensitive material. By the arrangement, the defect that tiny components of detected gas are ignored due to the dispersion of metal particles can be avoided, and the detection blind area of a sensing area in the three-dimensional nanotube is avoided.
S3: dividing the upper and lower surfaces of a differentially sensed three-dimensional nanotube substrateOther kinds of thingsAt least one pair of electrodes aligned one above the other is deposited. The deposition method includes a thermal evaporation method or an electron beam evaporation method. Preferably, the invention is used for differentiation transmissionAnd respectively depositing at least one gold electrode with the diameter of 1OOnm aligned up and down on the upper surface and the lower surface of the sensitive three-dimensional nanotube substrate. The conductivity of the gold electrode is more favorable for the circulation of current and the transmission of sensing data.
S4: and the lower surface electrode of the three-dimensional nanotube substrate is arranged on the upper surface of the ceramic substrate by adopting a film-rewinding packaging method. Preferably, after the electrode pair deposition is completed, the lower surface electrode of the obtained three-dimensional nanotube substrate is connected with the upper surface electrode of the ceramic substrate with the via hole.
Specifically, the method for rewinding packaging comprises the following steps: and (3) coating solder paste on the electrode on the upper surface of the ceramic substrate by using a mask, aligning the three-dimensional nanotube substrate on the ceramic substrate, heating to 180-220 ℃ for reflow soldering, and forming stable electric connection between the lower electrode of the three-dimensional nanotube substrate and the upper electrode of the ceramic substrate.
S5: the upper surface electrodes of the three-dimensional nanotube substrate on the ceramic substrate in the same direction are connected using wire bonding and finally connected to some free electrode on the ceramic substrate.
S6: and (3) smearing epoxy resin on a non-sensing area and a wire bonding part of the three-dimensional nanotube substrate by using a mask, and curing by using ultraviolet rays to realize the protection of the metal connecting wire and the further fixation of the three-dimensional nanotube substrate.
According to the packaging method of the three-dimensional nanotube gas sensor array, the sensor array can form differentiated sensing areas, and the sensitivity of the sensor array to different gases is different, so that the sensor array is integrated on a single chip, and a platform for detecting multiple gases is built. The three-dimensional nanotube gas sensor array can monitor various gases simultaneously, and has lower manufacturing cost.
It should be noted that the above-described embodiments are exemplary, and that a person skilled in the art, in light of the present disclosure, may devise various solutions that fall within the scope of the present disclosure and fall within the scope of the present disclosure. It should be understood by those skilled in the art that the present description and drawings are illustrative and not limiting to the claims. The scope of the invention is defined by the claims and their equivalents.
Claims (10)
1. A method of manufacturing a three-dimensional nanotube-based gas sensor, the method comprising:
the three-dimensional nanotube array is penetrated through the anodized aluminum film and gas is allowed to flow through both ends of the three-dimensional nanotubes,
a sensing area which takes the three-dimensional nano tube as a substrate and is deposited with a gas-sensitive material is arranged between a first electrode on the first surface of the anodic aluminum oxide film and a second electrode on the second surface of the anodic aluminum oxide film,
at least one first electrode and at least one second electrode form electrode pairs arranged at both ends of the sensing region, the first electrodes arranged along a first direction and arranged at a start end or an end are connected with at least one third electrode in an idle state on a first surface of the ceramic layer, wherein,
different metal nano particle modification areas are arranged on the surfaces of gas-sensitive materials of different sensing areas in the three-dimensional nano tube sensor array, and at least two metal particle modification areas in the sensing areas of the three-dimensional nano tube sensor are divided longitudinally and circumferentially and/or spirally according to the axial direction of the tube wall, so that one sensing area has at least two gas sensitivities.
2. The method of manufacturing a three-dimensional nanotube based gas sensor of claim 1, further comprising:
different metal nanoparticle solutions are deposited on different areas of the three-dimensional nanotube wall so that the three-dimensional nanosensor array forms a differential response to different gases.
3. The method of manufacturing a three-dimensional nanotube based gas sensor of claim 1, further comprising:
depositing a gas-sensitive sensing material with a certain thickness into the pipe wall of the three-dimensional nano-pipe based on an atomic layer deposition method or an ultrasonic spray pyrolysis method,
the gas sensing material comprises a metal oxide semiconductor material, wherein,
after the deposition of the gas sensitive material is completed, two ends of the three-dimensional nanotube are in a through state.
4. The method of manufacturing a three-dimensional nanotube based gas sensor of claim 1, further comprising:
shorting a plurality of first electrodes which are arranged along a first direction on the first surface of the anodic aluminum oxide film and correspond to the sensing area in a wire bonding mode;
and connecting a common second electrode which is arranged along a second direction on the second surface of the anodic aluminum oxide film and corresponds to the sensing area with a third electrode on the first surface of the ceramic layer.
5. The method of manufacturing a three-dimensional nanotube based gas sensor of claim 4, further comprising:
a plurality of third electrodes on the first surface of the ceramic layer form bonding pads capable of being welded with chips on the second surface of the bottom of the ceramic layer in a via way,
and a plurality of third electrodes form a third electrode array.
6. The method of manufacturing a three-dimensional nanotube based gas sensor of claim 5, further comprising:
in case the first direction and the second direction are perpendicular to each other,
the sensing areas taking the three-dimensional nanotubes as the substrate are arranged in a matrix array mode to form a three-dimensional nano sensor array.
7. The method of manufacturing a three-dimensional nanotube based gas sensor of claim 1,
the third electrode in the idle state is in the same column/row in the first direction as the third electrode to which the common second electrode is connected.
8. A three-dimensional nanotube-based gas sensor is characterized by at least comprising a three-dimensional nanotube array, an anodic aluminum oxide film and an electrode,
the three-dimensional nanotube array penetrates the anodized aluminum film and allows gas to flow through from both ends of the three-dimensional nanotubes,
a sensing area which takes the three-dimensional nano tube as a substrate and is deposited with a gas-sensitive material is arranged between a first electrode on the first surface of the anodic aluminum oxide film and a second electrode on the second surface of the anodic aluminum oxide film,
at least one first electrode and at least one second electrode form electrode pairs arranged at both ends of the sensing region, the first electrodes arranged along a first direction and arranged at a start end or an end are connected with at least one third electrode in an idle state on a first surface of the ceramic layer, wherein,
different metal nano particle modification areas are arranged on the surfaces of gas-sensitive materials of different sensing areas in the three-dimensional nano tube sensor array, and at least two metal particle modification areas in the sensing areas of the three-dimensional nano tube sensor are divided longitudinally and circumferentially and/or spirally according to the axial direction of the tube wall, so that one sensing area has at least two gas sensitivities.
9. The three-dimensional nanotube based gas sensor of claim 8,
the three-dimensional nanotube gas sensor array includes a plurality of sensing regions of differing gas sensitivity, wherein,
different metal nanoparticle solutions are deposited in different areas of the three-dimensional nanotube wall, so that the three-dimensional nanosensor array forms a differential response to different gases.
10. Use of a three-dimensional nanotube based gas sensor according to claim 8 or 9 for simultaneous detection of at least two gases.
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