Patent Description:
Patent Literature <NUM> discloses a chemical sensor device which is used for identifying a substance on the basis of variations in the resonance frequencies of vibrators, occurring when the substance is adsorbed or desorbed. The chemical sensor device includes the vibrators exhibiting the different properties of the desorption and adsorption of the substance, wherein each of the vibrators includes a piezoelectric substrate. Application of an alternating voltage allows such piezoelectric substrates to be deformed, thereby vibrating the vibrators. The substance can be identified by specifying a vibrator with a varying resonance frequency.

In the chemical sensor device disclosed in the above Patent Literature <NUM>, the vibrators are merely two-dimensionally arrayed on a flat plate but are not efficiently arranged to help each vibrator to adsorb a substance included in air. In such a configuration, the flat plate in itself may block airflow, thereby deteriorating the efficiency of adsorption of a substance, of each vibrator.

The present disclosure was made under such actual circumstances with an objective to provide a substance detecting element that is capable of more efficiently detecting a substance.

In order to achieve the aforementioned objective, there is provided a substance detecting element according to claim <NUM>.

According to the present disclosure, a through-hole through which gas including a substance passes is provided with a substance adsorption film, such a configuration is made that gas including a substance to be detected is helped to pass through the periphery of the substance adsorption film, and therefore, the substance can be more efficiently detected.

An embodiment of the present disclosure will be described in detail below. A substance detecting element according to the present embodiment is produced using micro electro mechanical systems (MEMS) which are semiconductor production technology that realizes micro processing.

As illustrated in <FIG>, a substance detecting element <NUM> according to the present embodiment includes a supporting substrate <NUM> having a generally rectangular flat-plate shape. The supporting substrate <NUM> is produced from, for example, a silicon-on-insulator (SOI) substrate. The SOI substrate, which is a semiconductor substrate with a layered structure, including a BOX layer which is a buried oxide layer and a silicon (SOI) layer which is a semiconductor layer on the BOX layer, is a wafer containing an oxide film.

The supporting substrate <NUM> is configured by layering a Si supporting layer <NUM> including a BOX layer formed of a substrate wafer and a buried oxide layer on a base <NUM> including a resin, as illustrated in <FIG>. A Si active layer <NUM> (see <FIG>) which is an element wafer active layer is layered on the Si supporting layer <NUM>.

An opening <NUM> having a circular shape is disposed in a part of the base <NUM> of the supporting substrate <NUM>, and the Si supporting layer <NUM> is exposed in a portion corresponding to the opening <NUM>. Seven through-holes <NUM> are disposed in the Si supporting layer <NUM> and the Si active layer <NUM> in the portion corresponding to the opening <NUM>. The through-holes <NUM> have a circular shape and each have the same diameter.

As illustrated in <FIG>, each of the through-holes <NUM> is provided with a pair of plate-shaped beams <NUM>. The pair of beams <NUM> includes a drive beam (first beam) 4A having a linear plate shape and a detection beam (second beam) 4B having a linear plate shape. Each of the beams <NUM> (the drive beam 4A and the detection beam 4B) includes a portion that is formed of the Si active layer <NUM> and extends from an edge toward an opposite edge.

The drive beam 4A and the detection beam 4B are orthogonal to each other and are coupled to each other at the middles of the drive beam 4A and the detection beam 4B. In an illustrative embodiment, the width of the drive beam 4A and the width of the detection beam 4B may be equal to each other, which is not according to the invention. The widths indicate the length of the drive beam 4A in a lateral direction and the length of the detection beam 4B in a lateral direction. The pair of beams <NUM> does not close the whole of each through-hole <NUM> but closes a part of each through-hole <NUM>. Thus, the beams <NUM> prevent gas from remaining in each through-hole <NUM> to help the gas to pass through each through-hole <NUM>.

As illustrated in <FIG>, the beams <NUM> support a substance adsorption film <NUM> that adsorbs a substance to be detected. The substance adsorption film <NUM> is located at the middles of the beams <NUM>, that is, the center in each through-hole <NUM>, and is disposed on the coupling portion of the drive beam 4A and the detection beam 4B. The width of one beam <NUM> in the lateral direction and the width of the other beam <NUM> in the lateral direction, at the middles of the beams <NUM>, that is, the portion at which the beams <NUM> in the pair are coupled to each other and on which the substance adsorption film <NUM> is formed, are set to be wider than those of the portions of the beams <NUM> other than the coupled portion. In addition, the substance adsorption film <NUM> has a dome shape (hemispheric shape). Therefore, the substance adsorption film <NUM> can have an increased surface area exposed to gas and therefore, more easily adsorb the substance to be detected, included in gas (for example, in air).

The substance to be detected is a gaseous substance (hereinafter referred to as "constitutive substance") constituting, for example, a chemical substance to be detected, included in air, in, for example, a chemical substance group (odor factor) constituting an odor. Examples of the chemical substance to be detected include an odor causative substance having a specific odor, such as ammonia, mercaptan, aldehyde, hydrogen sulfide, or amine. After a lapse of a certain period of time following the adsorption of a constitutive substance constituting an odor causative substance, the adsorbed constitutive substance is separated, and therefore, the substance adsorption film <NUM> can be reused.

The beams <NUM> are configured so that a vibration frequency (for example, a resonance frequency) is varied when the substance adsorption film <NUM> adsorbs the constitutive substance. Since the substance adsorption film <NUM> is arranged in each through-hole <NUM> which is an opening through which gas including the constitutive substance passes, the substance adsorption film <NUM> is helped to adsorb the constitutive substance included in the gas. In order to prevent the vibrations of the beams <NUM> from being affected by the vibration of an apparatus (for example, an electronic instrument <NUM> described below) into which the substance detecting element <NUM> is incorporated, the vibration frequencies of the beams <NUM> are desirably set to be different from and to be higher than the vibration frequency of the apparatus.

As illustrated in <FIG>, drive electrodes <NUM> in a pair are formed on both ends of the drive beam 4A, and detection electrodes <NUM> in a pair are formed on both ends of the detection beam 4B. In addition, a drive signal wire <NUM>, an interelectrode signal wire <NUM>, and a detection signal wire <NUM> as lead wires are formed on the supporting substrate <NUM> and the beams <NUM>. The drive signal wire <NUM> is connected to the drive electrodes <NUM>. In addition, the interelectrode signal wire <NUM> connects the detection electrodes <NUM> to each other on the detection beam 4B. The detection signal wire <NUM> is connected to one detection electrode <NUM>.

A voltage signal that drives the beams <NUM> is applied to the drive electrodes <NUM> through the drive signal wire <NUM>. In addition, a voltage signal generated from one detection electrode <NUM> by the vibrations of the beams <NUM> is sent to the other detection electrode <NUM> through the interelectrode signal wire <NUM>. In addition, voltage signals from the detection electrodes <NUM> in the pair are collectively output through the detection signal wire <NUM>.

As illustrated in <FIG> which is a cross-sectional view taken along the line A-A of <FIG>, the drive beam 4A principally includes the Si active layer <NUM> of the supporting substrate <NUM>. A lower electrode layer <NUM> is formed on the Si active layer <NUM>, and a piezoelectric element <NUM> is formed on the lower electrode layer <NUM>. In the middle of the drive beam 4A, the lower electrode layer <NUM> and the piezoelectric element <NUM> are removed to pass the interelectrode signal wire <NUM>. An insulating layer which is not illustrated is disposed between the interelectrode signal wire <NUM> and the Si active layer <NUM>. In <FIG>, the illustration of the BOX layer is omitted.

The lower electrode layer <NUM> includes a conductive material (for example, a metal such as aluminum or copper). The same applies to the drive electrodes <NUM> and the detection electrodes <NUM>. The piezoelectric element <NUM> includes, for example, a material (material exhibiting piezoelectric properties) such as lead zirconate titanate (PZT). The piezoelectric element <NUM> has a property of extending and contracting in a longitudinal direction (direction orthogonal to a thickness direction) when a voltage having a predetermined polarity is applied in the thickness direction.

As illustrated in <FIG>, the drive electrodes <NUM> in the pair are formed on the piezoelectric element <NUM> at the edge portions of each through-hole <NUM>. A piezoelectric layer is formed of the lower electrode layer <NUM>, the piezoelectric element <NUM>, and the drive electrodes <NUM>. The drive electrodes <NUM> and the lower electrode layer <NUM> vibrate and deform the drive beam 4A which applies a voltage to the piezoelectric element <NUM>.

More specifically, a stress is applied to the piezoelectric layer in the direction of extending in a longitudinal direction (direction along the x axis) and extending in a surface direction (direction along the y axis) by applying a voltage having a polarity that allows the drive electrodes <NUM> to be positive and the lower electrode layer <NUM> to be negative (hereinafter referred to as "positive polarity"), as illustrated in <FIG>. As a result, a face, on which the lower electrode layer <NUM> is formed, of the Si active layer <NUM> extends, and the drive beam 4A is warped in an upwardly convex manner (in the +z direction).

In contrast, a stress is applied to the piezoelectric layer in the direction of contracting in the longitudinal direction (direction along the x axis) and contracting in the surface direction (direction along the y axis) by applying a voltage having a polarity that allows the drive electrodes <NUM> to be negative and the lower electrode layer <NUM> to be positive (hereinafter referred to as "negative polarity"), as illustrated in <FIG>. As a result, the face, on which the lower electrode layer <NUM> is formed, of the Si active layer <NUM>, contracts, and the drive beam 4A is warped in a downwardly convex manner (in the -z direction).

It will be appreciated that a piezoelectric element may be used that has the properties of contracting in the longitudinal direction by applying a voltage between both the drive electrodes <NUM> and the lower electrode layer <NUM> so as to allow a side closer to the drive electrodes <NUM> to be positive and a side closer to the lower electrode layer <NUM> to be negative, and of extending in the longitudinal direction by applying a voltage between both the drive electrodes <NUM> and the lower electrode layer <NUM> so as to allow the side closer to the drive electrodes <NUM> to be negative and the side closer to the lower electrode layer <NUM> to be positive. In such a case, application of a voltage having a positive polarity results in downwardly convex warpage while application of a voltage having a negative polarity results in upwardly convex warpage. As described above, the drive beam 4A may be bent and vibrated due to the extension and contraction of the piezoelectric layer.

In any case, a deformation illustrated in <FIG> can be caused by applying a voltage having a predetermined polarity between the drive electrodes <NUM> and the lower electrode layer <NUM>. The degree of the deformation depends on the value of an applied voltage. A polarization action varies according to a material included in the piezoelectric element (according to, for example, a bulk or a thin film), and therefore, the polarity of the voltage and the relationship of extension and contraction may reverse with respect to the foregoing.

In contrast, the detection electrodes <NUM> in the pair are formed at the edges of each through-hole <NUM>, on the detection beam 4B, to come into contact with the piezoelectric element <NUM>, as illustrated in <FIG> which is a cross-sectional view taken along the line B-B of <FIG>. A piezoelectric layer is formed of the lower electrode layer <NUM>, the piezoelectric element <NUM>, and the detection electrodes <NUM>. When the detection beam 4B is vibrated due to the vibration of the drive beam 4A described above, the piezoelectric element <NUM> included in the detection beam 4B is deformed, and a potential difference is generated between the detection electrodes <NUM> and the lower electrode layer <NUM>. In <FIG>, the illustration of the BOX layer is omitted.

More specifically, a stress is applied to the piezoelectric layer in the direction of extending in a longitudinal direction (direction along the y axis) and extending in a surface direction (direction along the x axis) when the detection beam 4B is warped in an upwardly convex manner (in the +z direction), as illustrated in <FIG>. As a result, a voltage having a polarity that allows the detection electrodes <NUM> to be positive and the lower electrode layer <NUM> to be negative (hereinafter referred to as "positive polarity") is generated.

In contrast, a stress is applied to the piezoelectric layer in the direction of contracting in the longitudinal direction (direction along the y axis) and contracting in the surface direction (direction along the x axis) when the detection beam 4B is warped in a downwardly convex manner (in the -z direction), as illustrated in <FIG>. As a result, a voltage having a polarity that allows the detection electrode <NUM> to be negative and the lower electrode layer <NUM> to be positive (hereinafter referred to as "negative polarity") is generated.

It will be appreciated that a piezoelectric element may be used that has properties in which contraction in a longitudinal direction results in occurrence of a potential difference that allows a side closer to the detection electrodes <NUM> to be positive and a side closer to the lower electrode layer <NUM> to be negative while extension in the longitudinal direction results in occurrence of a potential difference that allows the side closer to the detection electrodes <NUM> to be negative and the side closer to the lower electrode layer <NUM> to be positive. In such a case, warpage in a downwardly convex manner results in generation of a voltage having a positive polarity while warpage in an upwardly convex manner results in generation of a voltage having a negative polarity. As described above, the detection beam 4B may be bent, thereby resulting in extension and contraction of the piezoelectric layer and in generation of a voltage.

In any case, occurrence of a deformation illustrated shown in <FIG> can result in generation of a voltage having a predetermined polarity between the detection electrodes <NUM> and the lower electrode layer <NUM>. The magnitude of the voltage depends on the detection beam 4B. A polarization action varies according to a material included in the piezoelectric element (according to, for example, a bulk or a thin film), and therefore, the relationship between the extension and contraction and the polarity of the voltage may reverse with respect to the foregoing.

For example, when a sinusoidally varying voltage is applied between the drive electrodes <NUM> and the lower electrode layer <NUM>, the drive beam 4A is sinusoidally vibrated. In response to the vibration of the drive beam 4A, the detection beam 4B is also vibrated. When the detection beam 4B is vibrated, a sinusoidally varying potential difference is generated between the drive electrodes <NUM> and the lower electrode layer <NUM>.

In addition, when the frequency of a sinusoidal voltage applied between the drive electrodes <NUM> and the lower electrode layer <NUM> is increased or decreased, the frequencies of the vibrations of the drive beam 4A and the detection beam 4B are also increased or decreased, and the frequency of a voltage signal generated between the detection electrodes <NUM> and the lower electrode layer <NUM> is also increased or decreased. The vibration amplitude of the beams <NUM> is increased as the frequencies of the vibrations of the drive beam 4A and the detection beam 4B approach the resonance frequency of the beams <NUM>. When the frequencies of the vibrations of the drive beam 4A and the detection beam 4B become the resonance frequency of the beams <NUM>, the vibration amplitude of beam <NUM> becomes the greatest.

As described above, the beams <NUM> are configured so that the adsorption of a constitutive substance on the substance adsorption film <NUM> results in a variation in vibration frequency (for example, resonance frequency). In addition, the vibration frequencies of the beams <NUM> vary according to the degree of the adsorption of the constitutive substance on the substance adsorption film <NUM>. As a result, the frequencies at which the vibration amplitudes of the beams <NUM> are the greatest also vary. Conversely, a change from a state in which the substance adsorption film <NUM> does not adsorb the constitutive substance to a state in which the substance adsorption film <NUM> adsorbs the constitutive substance can be detected by determining a variation in vibration frequency at which the amplitudes of the voltage signals of the detection electrodes <NUM> and the lower electrode layer <NUM> are the greatest.

The potential difference generated between the detection electrodes <NUM> and the lower electrode layer <NUM> becomes a voltage signal, which is output through the interelectrode signal wire <NUM> and the detection signal wire <NUM>. The output voltage signal is regarded as information about the vibration frequencies of the beams <NUM>, and variations in the vibration frequencies of the beams <NUM> are detected based on the information, whereby the inclusion of a substance adsorbed by the substance adsorption film <NUM> in gas passing through the through-holes <NUM> can be detected.

In the supporting substrate <NUM>, the lower electrode layer <NUM> is formed on the Si active layer <NUM>, and an insulating layer <NUM> is formed on the lower electrode layer <NUM>, as illustrated in <FIG>. However, the lower electrode layer <NUM> and the insulating layer <NUM> are removed around each through-hole <NUM>, as illustrated in <FIG>. However, the lower electrode layer <NUM> forming the drive beam 4A and the detection beam 4B, which is not removed, is connected to the lower electrode layer <NUM> on the supporting substrate <NUM>.

In addition, the lower electrode layer <NUM> is removed in a region S in which the drive signal wire <NUM> and the detection signal wire <NUM> are wired on the supporting substrate <NUM>. This is because a parasitic capacitance is prevented from being generated between the drive signal wire <NUM> and the detection signal wire <NUM>, and the lower electrode layer <NUM>, thereby inhibiting the appropriate input of voltage signals into the piezoelectric layers of the drive beam 4A and the detection beam 4B.

As illustrated in <FIG>, a signal processing circuit <NUM> is disposed in the substance detecting element <NUM>. The signal processing circuit <NUM> is connected to one drive signal wire <NUM> and seven detection signal wires <NUM>. The drive signal wire <NUM> from the signal processing circuit <NUM> is branched into <NUM> wires, which are connected to the drive electrodes <NUM> in the pairs of the respective through-holes <NUM>. In other words, the drive signal wires <NUM> that are electrically connected to the respective drive electrodes <NUM> formed on both the ends of the drive beams 4A are drawn to the outside of the drive beams 4A and unified into one. In addition, the seven detection signal wires <NUM> from the respective through-holes <NUM> are independently connected to the signal processing circuit <NUM>. The signal processing circuit <NUM> inputs and outputs a voltage signal on the basis of the potential of the lower electrode layer <NUM>.

The signal processing circuit <NUM> outputs, for example, a sinusoidal voltage signal to the drive electrodes <NUM> corresponding to each through-hole <NUM> through the drive signal wires <NUM>, and inputs, through the detection signal wire <NUM>, the voltage signal output from the detection electrode <NUM> corresponding to each through-hole <NUM>. The signal processing circuit <NUM> detects variations in the vibration frequencies (for example, resonance frequencies) of the beams <NUM> on the basis of the input voltage signal. In the substance detecting element <NUM>, the adsorption of a constitutive substance can be detected, for example, in a unit of a nanogram.

In the substance detecting element <NUM>, the beams <NUM> are disposed in each through-hole <NUM>, and the kinds of the substance adsorption films <NUM> supported by the respective pairs of beams <NUM> are different. The signal processing circuit <NUM> inputs, through the detection signal wires <NUM>, a voltage signal output from the detection electrodes <NUM> of each through-hole <NUM>, and detects a variation in the vibration frequency of each beam <NUM>, that is, the adsorption of a constitutive substance on the substance adsorption film <NUM> corresponding to the beam <NUM>, on the basis of the input voltage signal. The signal processing circuit <NUM> includes a memory, and the detection result of the constitutive substance of each substance adsorption film <NUM> is stored in the memory.

As illustrated in <FIG>, the substance detecting element <NUM> according to the present embodiment includes an interface <NUM> for a memory card for the electronic instrument <NUM> such as a smartphone. It is assumed that there are substance detecting elements 1A and 1B for different specified substances to be detected, as the substance detecting elements <NUM>.

The substance detecting element 1A is connected to the electronic instrument <NUM> via the interface <NUM>. The electronic instrument <NUM> can read the detection result of a constitutive substance, stored in the memory of the signal processing circuit <NUM> of the substance detecting element 1A. The electronic instrument <NUM> reads the data of the memory of the signal processing circuit <NUM> of the substance detecting element 1A inserted into the interface <NUM>, and analyzes a substance to be detected on the basis of the read data.

It is assumed that for example, the constitutive substances to be detected of the substance detecting element 1A are 1a to <NUM>. In addition, it is assumed that the constitutive substances of a certain chemical substance A are 1a, 1b, and 1c, and the constitutive substances of another chemical substance B are 1a, 1d, 1e, and 1f. When the chemical substance A is included in gas, the detection results of the chemical substance A indicate the detections of 1a, 1b, 1c as illustrated in <FIG>. When the chemical substance B is included in gas, the detection results of the chemical substance B indicate the detections 1a, 1d, 1e, and 1f, as illustrated in <FIG>. The electronic instrument <NUM> stores the reference patterns of the chemical substances to be detected, and performs the pattern matching of an actual detection result and the reference patterns to specify a chemical substance included in gas.

In the present embodiment, the pattern matching is performed with the patterns based on the presence or absence of the constitutive substances. However, the present disclosure is not limited thereto. It is also acceptable to determine the adsorption degree of a constitutive substance on the substance adsorption film <NUM> according to variations in the vibration frequencies of the beams <NUM>, to generate a pattern according to the content ratio of the constitutive substance in a chemical substance, and to perform pattern matching with the pattern to specify the chemical substance.

Since the substance detecting elements 1A and 1B are produced by MEMS, the very small substance detecting elements 1A and 1B can be produced. Accordingly, the substance detecting elements 1A and 1B can be allowed to be in conformity with, for example, the standards of a small mini SD card. As a result, it is also possible to prepare, for example, the substance detecting elements 1A and 1B with the different combinations of the detectable constitutive substances, to replace the substance detecting element 1A with the substance detecting element 1B, as the substance detecting element <NUM> mounted to the electronic instrument <NUM>, and to increase the number of the combinations of the detectable chemical substances.

The substance detecting element <NUM> is used for detecting various chemical substances that can be included in gas. With regard to the substance detecting element <NUM>, for example, the substance detecting element <NUM> is placed in the flow of gas, and is used for detecting a constitutive substance constituting a chemical substance included in the gas passing through the through-hole <NUM>, as illustrated in <FIG>. In such a case, the beams <NUM> which support the substance adsorption film <NUM> which adsorbs the constitutive substance do not close the whole of the through-hole <NUM> but close a part of the through-hole <NUM>. Thus, the beams <NUM> prevent the gas including the chemical substance to be detected from remaining in the through-hole <NUM> to help the gas to pass through the through-hole <NUM>.

In accordance with the present embodiment, a chemical substance can be more efficiently detected because the substance adsorption film <NUM> is disposed in each through-hole <NUM> through which gas including the chemical substance passes, and is configured so that the gas including the chemical substance to be detected easily passes through the periphery of the substance adsorption film <NUM>, as described in detail above.

In the embodiment described above, the width W1 (the length in the lateral direction) of the drive beam 4A and the width W1 (the length in the lateral direction) of the detection beam 4B may be equal to each other, as illustrated in <FIG>, which is not according to the invention and is present for illustration purposes only. As illustrated in <FIG>, the width W2 of drive beam 4A is set to be wider than the width W1 of the detection beam 4B. As illustrated in <FIG>, it is also acceptable to set the width of the drive beam 4A at W2 and the width of the detection beam 4B at W <NUM>, to shorten the diameter of the through-hole <NUM>, and to shorten the length L1 of the drive beam 4A to L2. In such a manner, the vibration frequencies of all the beams <NUM> can be set at higher levels to reduce the influence of vibrations from the outside, and variations in the vibration frequencies of the beams <NUM> per unit weight of an adsorbed constitutive substance can be increased to improve the accuracy of the detection of the adsorption of the constitutive substance.

The widths and lengths of the beams <NUM> are desirably determined based on a relationship with respect to the size of each through-hole <NUM>, required for the flow of gas.

In the present embodiment, each beam <NUM> is fixed to at least two edges of each through-hole <NUM>. In such a manner, the beams <NUM> can be stably retained, and the vibration frequencies of the beams <NUM> can be increased, in comparison with a cantilever <NUM>.

In the embodiment described above, the beams <NUM> are fixed to the four edges of each through-hole <NUM>. As illustrated in <FIG>, which is not according to the invention and is present for illustration purposes only, a beam <NUM> may be a cantilever. In such a case, the vibration frequency of the beam <NUM> is desirably increased by increasing the width or thickness of the beam <NUM>. A drive electrode <NUM> and a detection electrode <NUM> may be disposed together on one end of the beam <NUM> (one end fixed to an edge of the through-hole <NUM>).

As illustrated in <FIG>, which is not according to the invention and is present for illustration purposes only, a beam <NUM> fixed to two edges of a through-hole <NUM> may also be used. In such a case, drive electrodes <NUM> and detection electrodes <NUM> may be disposed together on both ends of the beam <NUM>.

As illustrated in <FIG>, which is not according to the invention and is present for illustration purposes only, a beam <NUM> fixed to three edges of a through-hole <NUM> may also be used. In such a case, drive electrodes <NUM> in a pair may be arranged on two of the ends of the beam <NUM>, and a detection electrode <NUM> may be arranged on the remainder of the ends.

In the embodiment described above, the beams <NUM> are configured so that the two doubly supported beams, which are the drive beam 4A and the detection beam 4B, are coupled to each other at the middles of the doubly supported beams. In such a manner, the entire beams <NUM> are vibrated by the one drive beam 4A, and the vibrations of the beams <NUM> are detected by the other detection beam 4B, whereby wire-saving can be achieved for the wiring of a circuit that drives the beams <NUM> and the wiring of a circuit that detects the vibrations of the beams <NUM>.

In the embodiment described above, the drive beam 4A and the detection beam 4B are orthogonal to each other. In such a manner, the vibration of the drive beam 4A can be prevented from being inhibited by the detection beam 4B. However, the drive beam 4A and the detection beam 4B need not be orthogonal to each other but may intersect each other.

In the embodiment described above, the drive electrodes <NUM> are disposed on both the ends of the drive beam 4A, and the detection electrodes <NUM> are disposed on both the ends of the detection beam 4B.

In the embodiment described above, the detection electrodes <NUM> are connected to each other through the interelectrode signal wire <NUM>. In such a manner, the detection signal wires <NUM> drawn from the detection electrodes <NUM> can be unified into one, and therefore, wire-saving can be achieved on the supporting substrate <NUM>.

In the embodiment described above, the drive signal wire <NUM>, connected to the drive electrodes <NUM>, is drawn to the outside, and the drive signal wire <NUM>, from the signal processing circuit <NUM>, is branched into the wires, which are input into the drive electrodes <NUM>. In such a manner, the drive signal wire <NUM> from the signal processing circuit <NUM> can be unified into one, and therefore, wire-saving can also be achieved for the drive signal wire <NUM> connected to drive electrodes <NUM>.

In the embodiments described above, the through-holes <NUM> are disposed in the supporting substrate <NUM>, the pair of beams <NUM> is disposed in each through-hole <NUM>, and the kinds of the substance adsorption films <NUM> supported by the respective pairs of beams <NUM> are different. In such a manner, a chemical substance can be specified based on the detection patterns of constitutive substances.

In the embodiment described above, the number of the through-holes <NUM> or the pairs of the beams <NUM> is seven. However, the present disclosure is not limited thereto. The number of the through-holes <NUM> or the pairs of the beams <NUM> may be six or less, or may be eight or more. The number of the through-holes <NUM> or the pairs of the beams <NUM> may depend on the number of constitutive substances to be detected.

In the embodiment described above, each through-hole <NUM> has a circular shape. However, the present disclosure is not limited thereto. Each through-hole may have an elliptical or rectangular shape, or may have an outer diameter of a combination of curved and straight lines.

In the embodiment described above, the substance to be detected is a chemical substance constituting an odor. However, the present disclosure is not limited thereto. For example, an odorless chemical substance included in gas may be detected.

In the embodiment described above, the chemical substance is included in gas. However, the present disclosure is not limited thereto. The present disclosure can also be applied to the detection of a substance in liquid.

In the embodiment described above, the substance detecting element 1A is produced using an SOI wafer. However, the present disclosure is not limited thereto. The substance detecting element may be produced using another wafer.

In the embodiment described above, the lower electrode layer <NUM> and the piezoelectric element <NUM> are disposed on the approximately entire surface of the beams <NUM>. However, the present disclosure is not limited thereto. The lower electrode layer <NUM> and the piezoelectric element <NUM> may be disposed only on the portions on which the drive electrodes <NUM> and the detection electrodes <NUM> are formed.

In the embodiment described above, the detection electrodes <NUM> formed on both the ends of the detection beam 4B are connected to each other through the interelectrode signal wire <NUM>. However, the present disclosure is not limited thereto. Separate detection signal wires <NUM> may be drawn from the detection electrodes <NUM>, may be disposed, and may be configured to output separate voltage signals.

The foregoing describes some example embodiments for explanatory purposes. Although the foregoing discussion has presented specific embodiments, persons skilled in the art will recognize that changes may be made in form and detail without departing from the scope of the invention. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense. This detailed description, therefore, is not to be taken in a limiting sense, and the scope of the invention is defined only by the included claims, along with the full range of equivalents to which such claims are entitled.

This application claims the priority of <CIT>.

Claim 1:
A substance detecting element (<NUM>) comprising:
a supporting substrate (<NUM>) in which a through-hole (<NUM>) is disposed;
a plate-shaped beam (<NUM>) that comprises a piezoelectric element (<NUM>), extending from an edge of the through-hole (<NUM>) toward an opposite edge to close a part of the through-hole (<NUM>), supporting a substance adsorption film (<NUM>) to which a substance to be detected adheres, and extending and contracting due to application of a voltage, the beam (<NUM>) being bent and vibrated due to the extension and contraction of the piezoelectric element (<NUM>);
drive electrodes (<NUM>) provided for applying a voltage to the piezoelectric element (<NUM>) to vibrate and deform the beam; and
detection electrodes (<NUM>) provided for outputting a voltage generated in the piezoelectric element (<NUM>) for detecting information about a vibration frequency of the beam (<NUM>),
the beam (<NUM>) comprising an elongated plate-shaped first beam (4A) having both ends fixed to edges of the through-hole (<NUM>) and provided with the drive electrodes (<NUM>) on both ends and an elongated plate-shaped second beam (4B) having both ends fixed to edges of the through-hole (<NUM>) and provided with the detection electrodes (<NUM>) on both ends, the second beam (4B) intersecting the first beam (4A),
the first beam (4A) and the second beam (4B) being coupled to each other at respective middles of the first beam (4A) and the second beam (4B),
characterized in that
a width of the first beam (4A) is set to be wider than a width of the second beam (4B).