Abstract:
A thermal type infrared ray imaging device has a plurality of cells arranged on a substrate each having a photothermal conversion part which converts an infrared ray into heat, and a thermoelectric conversion part which is provided below the photothermal conversion part and which converts the heat generated by the photothermal conversion part into an electric signal, a selection part which selects some cells among the plurality of cells, and an output part which outputs the electric signal generated by the thermoelectric conversion part of the selected cells. The photothermal conversion part includes a first photothermal conversion layer and a second photothermal conversion layer provided over and apart from the first photothermal conversion layer, which converts an infrared ray within a waveband different from the waveband of the first photothermal conversion layer into heat. The thermoelectric conversion part includes a first thermoelectric conversion part which converts the heat generated by the first photothermal conversion layer into the electric signal and a second thermoelectric conversion part which is thermally separated from the first thermoelectric conversion part, and which converts the heat generated by the second photothermal conversion layer into the electric signal.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS  
         [0001]    This application is based upon and claims the benefit of priority from the prior Japanese Patent Applications No. 2002-80066, filed on Mar. 22, 2002, the entire contents of which are incorporated herein by reference.  
         BACKGROUND OF THE INVENTION  
         [0002]    1. Field of the Invention  
           [0003]    The present invention relates to a thermal type infrared ray imaging device and a fabrication method thereof in which a plurality of cells are provided for each pixel.  
           [0004]    2. Related Background Art  
           [0005]    Recently, as a thermal type infrared ray image sensor in which a cooling apparatus is unnecessary, a bolometer type made of vanadium oxide using a micromachine technique and a pyroelectric type made of BST (Barium-Strontium-Titanate) type have been sold commercially. These products has a heat sensitive part for absorbing infrared ray to raise temperature, a support leg for thermally separating the heat sensitive part from a silicon substrate, a horizontal address line for selecting pixels, and a vertical signal line.  
           [0006]    This type of infrared ray image sensor absorbs the infrared ray radiated from objects at the heat sensitive part, and detects temperature rise of the heat sensitive part by resistance variation and capacitance variation. Because of this, the support pillar for supporting the heat sensitive part has a structure in which cross section is small and length is long, in order to enhance adiabatic effect.  
           [0007]    However, when the length of the support leg is long, the infrared ray is absorbed to convert the infrared ray into heat, thereby decreasing area of the heat sensitive part for converting the heat into an electric signal. That is, the length of the support leg and the area of the heat sensitive part are trade-off.  
           [0008]    When the area of the heat sensitive part decreases, dead area of image area increases. When a picture of a faraway small object is taken, a spot focused on an image area becomes about 14 μm of diffraction limit. Because of this, when this spot of 14 μm is focused on non-sensitive area, no picture can be taken. Accordingly, as shown in FIG. 24, Japanese patent Laid-open publication No. 209418/1998 and so on disclose a structure in which a heat sensitive part  123  is divided into a photothermal conversion part  125  and a heat sensitive conversion part  124 , and area of the heat sensitive conversion part  125  is enlarged. In FIG. 24, reference number  121  is a substrate, reference number  122  is a bonding pad, reference number  126  is a hollow part, reference number  127  is a support leg for supporting the heat sensitive part  123  on the substrate  121 , reference number  128  is a vertical signal line.  
           [0009]    It is possible to estimate emissivity of an object under test, by measuring intensity of a plurality of infrared rays radiated from the objects. Therefore, it is possible to easily identify materials, and to precisely measure absolute temperature. A method of performing the entire processings by image is disclosed in Japanese Laid-open publication No. 23261/1997 and Japanese Laid-open publication No. 188407/2000. A cooling type image sensor of HgCdTe or GaAlAs/GsAs system quantum well structure type is used in these documents. The sensor has a feature in which it is possible to easily obtain lamination structure, and an absorption waveband is very narrow. It is possible to selectively absorb the infrared ray of each waveband in each layer of the lamination layer.  
           [0010]    However, in a non-cooling type infrared ray image sensor, for example, Japanese application No. 201400/2001 discloses a method in which detection pixels of two wave lengths are alternately disposed for every line or every column. In the sensor disclosed in this document, a non-sensitive area increases at each waveband, and it becomes difficult to take a picture of a faraway small object.  
           [0011]    Conventionally, it is possible to estimate emissivity of the object under test by measuring a plurality of infrared rays emitted from objects. Therefore, it is possible to identify a material of the object under test, and to precisely measure the absolute temperature. However, there was a problem in which the non-sensitive area at each waveband increases, and it became difficult to take a picture of the faraway small object.  
         SUMMARY OF THE INVENTION  
         [0012]    An object of the present invention is to provide a thermal type infrared ray imaging device and a fabrication method thereof capable of obtaining excellent imaging properties by preventing increase of the non-sensitive area at each waveband.  
           [0013]    In order to achieve the foregoing object, a thermal type infrared ray imaging device, comprising:  
           [0014]    a plurality of cells arranged on a substrate each having a photothermal conversion part which converts an infrared ray into heat, and a thermoelectric conversion part which is provided below said photothermal conversion part and which converts the heat generated by said photothermal conversion part into an electric signal;  
           [0015]    a selection part which selects some cells among said plurality of cells; and  
           [0016]    an output part which outputs the electric signal generated by said thermoelectric conversion part of each of the selected cells,  
           [0017]    wherein said photothermal conversion part includes:  
           [0018]    a first photothermal conversion layer; and  
           [0019]    a second photothermal conversion layer provided over and apart from said first photothermal conversion layer, which converts an infrared ray within a waveband different from a waveband of said first photothermal conversion layer into heat,  
           [0020]    wherein said thermoelectric conversion part includes:  
           [0021]    a first thermoelectric conversion part which converts the heat generated by said first photothermal conversion layer into the electric signal; and  
           [0022]    a second thermoelectric conversion part which is thermally separated from said first thermoelectric conversion part, and which converts the heat generated by said second photothermal conversion layer into the electric signal.  
           [0023]    Furthermore, a thermal type infrared ray imaging device, comprising:  
           [0024]    a plurality of cells arranged on a substrate each having a photothermal conversion part which converts an incident infrared ray into heat, and a thermoelectric conversion part which is provided below said photothermal conversion part and which converts the heat generated by said photothermal conversion part into an electric signal;  
           [0025]    a selection part which selects some cells among said plurality of cells; and  
           [0026]    an output part which outputs the electric signal generated by said thermoelectric conversion part of each of the selected cells;  
           [0027]    wherein said photothermal conversion part has a plurality of photothermal conversion layers which convert infrared rays within different wavebands into heat, said photo thermal conversion layers being disposed apart from each other in a vertical direction; and  
           [0028]    said thermoelectric conversion part has a plurality of thermoelectric conversion parts which convert the heat generated by said plurality of photothermal conversion layers into the electric signals. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0029]    [0029]FIG. 1 is a cross section view showing a structure for one pixel of the thermal type infrared ray element of one embodiment according to the present invention.  
         [0030]    [0030]FIG. 2 is a top face view of the thermal type infrared ray imaging device of the present embodiment.  
         [0031]    [0031]FIGS. 3A and 3B are top face views extracting a thermoelectric conversion part and a photothermal conversion layer which are substantial parts of FIG. 2.  
         [0032]    [0032]FIG. 4 is a top surface view showing a layout of a thermal type infrared ray imaging device of the present embodiment.  
         [0033]    [0033]FIG. 5 is a conceptual view for explaining operation of the thermal type infrared ray imaging device of the present embodiment.  
         [0034]    [0034]FIG. 6 is a cross section view showing fabrication step of the thermal type infrared ray imaging device of the first embodiment of the present invention.  
         [0035]    [0035]FIG. 7 is a cross section view following to FIG. 6.  
         [0036]    [0036]FIG. 8 is a cross section view following to FIG. 7.  
         [0037]    [0037]FIG. 9 is a cross section view following to FIG. 8.  
         [0038]    [0038]FIG. 10 is a cross section view following to FIG. 9.  
         [0039]    [0039]FIG. 11 is a cross section view following to FIG. 10.  
         [0040]    [0040]FIG. 12 is a cross section view following to FIG. 11.  
         [0041]    [0041]FIG. 13 is a cross section view following to FIG. 12.  
         [0042]    [0042]FIG. 14 is a cross section view following to FIG. 13.  
         [0043]    [0043]FIG. 15 is a cross section view following to FIG. 14.  
         [0044]    [0044]FIG. 16 is a cross section view following to FIG. 15.  
         [0045]    [0045]FIG. 17 is a cross section view following to FIG. 16.  
         [0046]    [0046]FIG. 18 is a cross section view following to FIG. 17.  
         [0047]    [0047]FIG. 19 is a cross section view following to FIG. 18.  
         [0048]    [0048]FIG. 20 is a cross section view following to FIG. 19.  
         [0049]    [0049]FIG. 21 is a cross section view following to FIG. 20.  
         [0050]    [0050]FIG. 22 is a cross section view following to FIG. 21.  
         [0051]    [0051]FIG. 23 is a cross section view following to FIG. 22.  
         [0052]    [0052]FIG. 24 is a cross section view showing configuration of one pixel of a conventional thermal type infrared ray imaging device. 
     
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0053]    Hereinafter, one embodiment of a thermal type infrared ray imaging device according to the present invention will be described with reference to drawings.  
         [0054]    The thermal type infrared ray imaging device of one embodiment described hereinafter detects infrared ray of multiple wavelengths, and has a structure in which a plurality of pixels for detecting infrared rays are arranged in matrix shape.  
         [0055]    [0055]FIG. 1 is a cross section view showing a structure for one pixel of the thermal type infrared ray element of one embodiment according to the present invention. FIG. 2 is a top surface view of the thermal type infrared ray imaging device of the present embodiment, and FIGS. 3A and 3B are top surface views extracting a thermoelectric conversion part and an photothermal conversion layer which are substantial parts of FIG. 2.  
         [0056]    As shown in FIG. 1, a thermoelectric conversion part  17  (a second thermoelectric conversion part and a thermoelectric conversion part for second waveband) of the infrared ray detection pixels and a thermoelectric conversion part  18  (a first thermoelectric conversion part and a thermoelectric conversion part for first waveband) of the infrared detection pixels are provided at the state of floating on a hollow area  20  formed inside the single crystal silicon substrate  11   a , and are supported on the single crystal silicon substrate  11   a  by a support leg  12 . Here, the hollow area  20  is formed by selectively removing by etching, for example, a portion of the single crystal silicon substrate  11   a  of the SOI (Silicon On Insulator) substrate containing the single crystal silicon substrate  11   a , the embedded oxide film  11   b  band the single crystal silicon layer  11   c . Reference number  19   a  is a groove portion formed between the support leg  12  and the single crystal silicon substrate  11   a , and reference number  19   b  is a groove portion formed between the thermoelectric conversion parts  17  and  18 . It is possible to effectively perform temperature variation of the thermoelectric conversion part by the incident infrared ray, by providing the thermoelectric conversion parts  17  and  18  and the support leg  12  on the hollow structure  20 . Although reference number  11   b  is the buried oxide film on the SOI substrate as mentioned above, this film is also provided below under surface of the thermoelectric converters  17  and  18 .  
         [0057]    In FIG. 1, the thermoelectric conversion parts  17  and  18  look to be formed by being physically segmentalized. However, as shown in top surface view of FIG. 2, the thermoelectric conversion parts  17  and  18  are in reality formed on an all-in-one device region  10 . That is, the device region  10  is supported on the single crystal silicon substrate  11   a  by the support leg  12 , and grooves  19   b  with two stripes are formed on portions of the device region  10  in parallel to each other. The thermoelectric conversion part  17  is provided between the grooves  19   b  with two stripes, and the thermoelectric conversion part  18  is provided at outer area of the grooves  19   b . Reference number  11   d  is a device isolation insulation film provided between the thermoelectric conversion parts  17  and  18 , and the device isolation insulation film  11   d  is made of, for example, silicon dioxide.  
         [0058]    As shown in FIG. 3A, the thermoelectric conversion part  17  has thermoelectric conversion elements  17   a ,  17   b ,  17   c  and  17   d . The thermoelectric conversion elements  17   a ,  17   b ,  17   c  and  17   d  are connected in series by using connection wirings.  
         [0059]    The thermoelectric conversion elements  17   a ,  17   b ,  17   c  and  17   d  are consisted of diodes such as pn junction, respectively. The diodes are made of the single crystal silicon layer of the SOI substrate. A p layer and an n layer located at both ends of pn junction of the diode may be arranged in a direction parallel to the substrate surface, or may be laminated in a direction vertical to the substrate surface.  
         [0060]    As shown in FIG. 3B, the thermoelectric conversion part  18  has the thermoelectric conversion elements  18   a ,  18   b ,  18   c  and  18   d , and the thermoelectric conversion elements  18   a  and  18   b  are disposed at one side of two grooves  19   b , and the thermoelectric conversion elements  18   c  and  18   d  are disposed at the other side of two grooves  19   b.    
         [0061]    These thermoelectric conversion elements  18   a ,  18   b ,  18   c  and  18   d  are connected in series, similarly to the thermoelectric conversion part  17 . For example, these thermoelectric conversion elements  18   a ,  18   b ,  18   c  and  18   d  are consisted of diodes having pn junction formed in the silicon layer.  
         [0062]    As shown in FIG. 3A, the photothermal conversion layer  14   a  is supported by the support pillar  14   b  on the thermoelectric conversion elements  17   a ,  17   b ,  17   c  and  17   d  of the thermoelectric conversion part  17  (a second thermoelectric conversion part and a thermoelectric part for second waveband), and is provided spreading in a horizontal direction of the substrate. As shown in FIG. 3B, four photothermal conversion layers  13   a  are supported by the support pillar  13   b  on the thermal electric conversion elements  18   a ,  18   b ,  18   c  and  18   d , and are provided in the horizontal direction of the substrate.  
         [0063]    As shown in FIG. 1, the photothermal conversion layer  13   a  is disposed below the photothermal conversion layer  14   a . As the photothermal conversion layer  13   a , for example, BPSG (Bolon Phosphorus doped in Silicate Glass) or BSG (Bolon doped in Silicate Glass), PSG (Phosphorus doped in Silicate Glass) and so on are used. As the photothermal conversion layer  14   a , for example, a lamination film formed by laminating silicon nitride film on silicon dioxide), FSG (Fluorosis doped in Silicate Glass) and so on are used.  
         [0064]    Hereinafter, the support leg  12  will be explained in detail. The support leg  12  has wirings  12   a ,  12   b  and  12   c  are formed inside a support beam formed of an insulation film such as silicon dioxide or silicon nitride. The support leg  12  is disposed to surround the device region  10  between the single crystal silicon substrate  11   a and the device region  10  in which the thermoelectric electric conversion parts  17  and  18  are formed in order to support the device region.  
         [0065]    Heat conductance of the support leg  12  is not more than about 2× −7  W/K, and the support leg  12  thermally separates the device region  10  from the single crystal silicon substrate  11   a . The number of the support legs  12  may not be two pieces. The number of the support legs may be more than two or less than two, if necessary. The wirings  12   a  and  12   b  are output wirings for a first waveband and a second waveband, as described below in detail. The wiring  12   c  is a common input wiring for first waveband and the second waveband.  
         [0066]    The thermoelectric conversion part  18  has the thermoelectric conversion elements  18   a ,  18   b ,  18   c  and  18   d  connected in series in order. One end of the output wiring  12   a  is connected to the thermoelectric conversion element  18   d  disposed at the most outer side. The connection point of one end of the output wiring  12   a  is omitted in FIG. 2. The other end of the output wiring  12   a  is connected to a vertical signal wiring  15  for a first waveband.  
         [0067]    The thermoelectric conversion part  17  has thermoelectric conversion elements  17   a ,  17   b ,  17   c  and  17   d  connected in series in order. One end of the output wiring  12   b  is connected to the thermoelectric conversion element  17   d  disposed at the most outer side. The other end of the output wiring  12   b  is connected to a vertical signal wiring for second waveband  16 .  
         [0068]    As shown in FIG. 2, the vertical signal wiring for first waveband  15  and the vertical signal wiring for second waveband  16  are provided in parallel to each other, and these wirings  15  and  16  are commonly connected to a plurality of pixels disposed in column direction. On the other hand, one end of the input wiring  12   c  is connected to the thermoelectric conversion element  18   a  of the thermoelectric conversion part  18  disposed at the nearest location to input side (horizontal signal line side) and the thermoelectric conversion element  17   a  of the thermoelectric conversion part  17  disposed at the nearest location to input side (horizontal signal line side). The other end of the input wiring  12   c  is connected to a common horizontal signal line wiring (horizontal address line)  21  for the first and second wavebands. The horizontal signal wiring (horizontal address line)  21  is commonly connected to pixels disposed in row directions.  
         [0069]    [0069]FIG. 4 is a top surface view showing a layout of a thermal type infrared ray imaging device of the present embodiment. In FIG. 4, reference number  51  is an image area within which detection pixels of the above-mentioned infrared ray imaging devices are disposed in matrix shape. Reference number  52  is a vertical shift register circuit to which the horizontal address line  21  is connected. Reference number  53  is a horizontal shift register circuit to which the vertical signal wiring for first waveband  15  and the vertical signal wiring for second waveband  16  are connected, reference number  55  is a signal processing circuit for first waveband, reference number  56  is a signal processing circuit for second waveband, reference number  57  is a signal output circuit for first waveband, reference number  58  is a signal output circuit for second waveband, reference number  59  is a signal output pad for first waveband, reference number  60  is a signal output pad for second waveband, reference number  54  is a bonding pad for supplying drive pulses of the other shift register or an amplification circuit.  
         [0070]    Next, operation of the thermal type infrared ray imaging device of the present embodiment will be explained. FIG. 5 is a conceptual view for explaining operation of the thermal type infrared ray imaging device of the present embodiment. As shown in FIG. 5, reference number  32  is an infrared ray incident from outside. The infrared ray is concentrated by a lens  31  and incident to the image area  51  of the above-mentioned thermal type infrared ray imaging device.  
         [0071]    The infrared ray of second waveband (for example, waveband 8-12 μm) among the incident infrared ray is absorbed in the photothermal conversion layer  14   a  in order to perform heat conversion. The generated heat is transmitted to the thermoelectric conversion part  17  via the support pillar  14   b , and is converted into the electric signal by the thermoelectric conversion part  17 . The electric signal generated by this conversion is transmitted to the vertical signal wiring for second waveband  16  via the output wiring  12   b . And then via the horizontal shift register circuit  53  of FIG. 4, the electric signal is subjected to signal processings by the signal processing circuit  56  for second waveband, and then is outputted from the signal output pad for second waveband  60 .  
         [0072]    The infrared ray of first waveband (for example, waveband is 3-5 μm) not absorbed by the photothermal conversion layer  14   a  is absorbed by the photothermal conversion layer  13   a  in order to perform heat conversion. The generated heat is transmitted to the thermoelectric conversion part  18  via the support pillar  13   b  in order to perform conversion to electric signal. The electric signal generated by this conversion is transmitted to the vertical signal wiring for first waveband  15  via the output wiring  12   a , and is subjected to signal processings by the signal processing circuit for first waveband  55  via the horizontal shift register circuit  53  of FIG. 4. And then the electric signal is outputted from the signal output pad for first waveband  59  via the signal output circuit for first waveband  57 .  
         [0073]    Thus, according to the present embodiment, it is possible to separately detect and output the infrared ray of the first waveband and the infrared ray of the second waveband. Because of this, it is possible to estimate emissivity of the object under test by obtaining intensity of a plurality of infrared rays radiated from the object. Accordingly, it is possible to easily identify materials of the object and to precisely measure absolute temperature, thereby improving contrast of image of the infrared ray and colorizing the image.  
         [0074]    Especially, according to the present embodiment, when the infrared ray of first waveband and the infrared ray of second waveband are separately detected, the photothermal conversion layer corresponding to the infrared rays of a plurality of wavebands as shown in above-mentioned embodiment is doubly disposed in the direction vertical to the substrate surface, and further a plurality of thermoelectric conversion parts for converting the heat generated by the photothermal conversion layers into heat are disposed to be integrated to one pixel. Because of this, it is possible to prevent increase of non-sensitive area for the infrared rays within wavebands, and to sensitively take a picture of a faraway small object.  
         [0075]    Furthermore, the grooves  19   b  of two stripes are provided between the thermoelectric electric conversion parts  17  and  18 . Therefore, thermal isolation between both of the thermoelectric conversion parts  17  and  18  is ensured. It is possible to improve accuracy of heat sensitivity in the thermoelectric conversion part, thereby obtaining more excellent infrared ray image.  
         [0076]    As compared with the case where pixels having different sensitive wavelengths are alternatively arranged for every column known as the conventional technique, even if the imaging size and the number of pixels are the same, the image area becomes small. Therefore, it is possible to downsize optical mechanism and to realize multi-wavelength infrared ray image sensor at low price. Furthermore, when the image area size is the same, it is possible to enlarge the imaging size, and to realize high-sensitive and multi-wavelength infrared ray image sensor.  
         [0077]    In the above-mentioned embodiment, the photothermal conversion layer  14   a  of the upper layer converts into heat the infrared ray within waveband shorter than that of the photothermal conversion layer  13   a  of the lower layer. Thus, because the photothermal conversion layer  14   a  capable of absorbing the infrared ray within longer waveband to the upper layer portion through which the infrared ray passes on ahead is disposed, it is possible to effectively absorb the infrared ray within a long waveband which is more reflective in the upper layer, and to restrict deterioration of absorption efficiency such as reflection. Furthermore, the photothermal conversion layer  13   a  for absorbing the infrared ray within short waveband is provided to the lower layer portion. It is possible to effectively absorb in total the infrared rays within multiple-waveband.  
         [0078]    Furthermore, as a structure of the photothermal conversion layer, in the case where the photothermal conversion layer  14   a  with large area is provided to the upper layer, and the photothermal conversion layer  13   a  with small area is provided to the lower layer, fabrication process is easier than in the case where disposition of the upper layer and the lower layer is opposite. Even in this point, the structure of the present embodiment is desirable.  
         [0079]    Moreover, the photothermal conversion layer  14   a  of large area tends to absorb the infrared ray of longer wavelength, and the photothermal conversion layer  13   a  of small area tends to absorb the infrared ray of shorter wavelength. Because of this, it is possible to improve absorption efficiency of the infrared ray by enlarging the area of the photothermal conversion layer  14   a  of the upper layer more than that of the photothermal conversion layer  14   b  of the lower layer. Thus, the present embodiment excels in absorption efficiency of the infrared ray and fabrication process.  
         [0080]    Especially, it is desirable that the size of acceptance surface of the photothermal conversion layer  14   a  of the upper layer is not less than at least 10 μm per side, and the size of the acceptance surface of the photothermal conversion layer  14   b  of the lower layer is not less than at least 3 μm and is less than 8 μm.  
         [0081]    Next, fabrication method of the thermal type infrared ray imaging device of FIG. 1 will be explained. FIGS.  6 - 23  are cross section views of fabrication steps for explaining fabrication methods of the thermal type infrared ray imaging device of FIG. 1. Each view shows a cross section view cut off by A-A′.  
         [0082]    First of all, as shown in FIG. 6, an SOI substrate which is formed by laminating an buried silicon dioxide film  11   b  and a single crystal silicon layer  1   c  on a single crystal silicon support substrate  11   a  is prepared as a semiconductor substrate.  
         [0083]    Next, an STI (Shallow-Trench-Isolation) fabrication is performed, similarly to device isolation in general LSI fabrication steps. More specifically, as shown in FIG. 7, the device isolation area is prescribed by using photolithography. The single crystal silicon layer  11   c  of the device isolation area is removed by etching by using a technique such as RIE (Reactive-Ion-Etching). After then, the device isolation silicon dioxide film  11   d  is embedded by using a technique such as CVD (Chemical-Vapor-Deposition), and then is evened by using a technique such as CMP (Chemical-Mechanical-Polishing). At this time, the area of the support pillar is also defined as the device isolation area, and the device isolation silicon dioxide film lid is embedded.  
         [0084]    Next, a diode having pn junction is formed of the single crystal silicon layer  11   c . After forming the diode, the device isolation silicon dioxide film  11   d  may be formed.  
         [0085]    It is possible to use a technique such as injection of impurity ion, heat treatment activation and diffusion in order to form the diode. For example, when n+type silicon layer is formed on surface of p type silicon layer, impurity ion As may be injected by, for example, acceleration voltage 50 kv and the dose amount 5×10 15  cm −2 .  
         [0086]    FIGS.  7 - 23  show an example in which n type (p type) conduction type semiconductor layer  48   b  is selectively formed on a surface of a p type (n type) conduction type semiconductor layer  48   a , as a diode.  
         [0087]    The diode consisted of the p type conduction type semiconductor layer  48   a  and the n type conduction type semiconductor layer  48   b  of FIGS.  7 - 23  corresponds to diodes  17   a ,  17   b ,  17   c  and  17   d  of FIG. 3A constituting the thermoelectric conversion part  17  and diodes  18   a ,  18   b ,  18   c  and  18   d  of FIG. 3B constituting the thermoelectric conversion part  18 .  
         [0088]    Next, as shown in FIG. 8, after a metal layer such as aluminum is formed on the substrate, the metal layer is patterned by RIE and so on in order to form an input wiring  12   c  and an output wiring  12   a . The output wiring  12   a  is an output wiring for first waveband as explained in the first embodiment, and is connected to the diode shown in FIG. 3B at cross section location different from the cross section of FIG. 8. The input wiring  12   c  is a common input wiring for first and second wavebands, and connected to the diode  18   a  shown in FIG. 3B and the diode  17   a  shown in FIG. 3A at cross section location different from the cross section of FIG. 8.  
         [0089]    Next, as shown in FIG. 9, after an interlayer insulation film  11   e  such as silicon dioxide is formed on the substrate, an output wiring  12   b  is formed by using the metal film. The output wiring  12   b  is connected to the diode  17   d  at cross section location different from the cross section of FIG. 9 via a contact hole not shown.  
         [0090]    Next, as shown in FIG. 10, an interlayer insulation film  11   f  such as silicon dioxide is formed on the substrate including a top surface of the output wiring  12   b.    
         [0091]    Next, as shown in FIG. 11, connection wirings  15 ′ and  16 ′, the vertical signal wiring for first waveband  15  and the vertical signal wiring for second waveband  16  are formed on the upper surface of the interlayer insulation film  11   f . The connection wiring  15 ′ is a wiring for directly connecting diodes  18   a ,  18   b ,  18   c  and  18   d . The connection wiring  16 ′ is a wiring for directly connecting diodes  17   a ,  17   b ,  17   c  and  17   d . The connection wirings  15 ′ and  16 ′ are connected to the diodes via contact holes not shown.  
         [0092]    Next, as shown in FIG. 12, an interlayer insulation film  11   g  such as silicon dioxide is formed on the substrate so as to cover the connection wirings  15 ′ and  16 ′, the vertical signal wiring for first waveband  15  and the vertical signal wiring for second waveband  16 . Subsequently, as shown in FIG. 13, an interlayer insulation film  11   h  such as silicon dioxide is formed on the substrate.  
         [0093]    Next, as shown in FIG. 14, an etching hole  71  is formed from the interlayer insulation film  11   h  through the buried silicon dioxide film  11   b  by RIE by using etching mask not shown. The etching hole  71  is formed at surrounding area of the input wiring  12   c  and is also formed in the area between the thermoelectric conversion parts  17  and  18 .  
         [0094]    After then, as shown in FIG. 15, a sacrifice layer  72  is formed on the substrate by using CVD method. Material of the sacrifice layer  72  is amorphous silicon or polyimide. At this time, the sacrifice layer  72  is embedded in the etching hole  71  shown in FIG. 14.  
         [0095]    Next, as shown in FIG. 16, a mask not shown is provided on the sacrifice layer  72 . A portion of the sacrifice layer  72  is removed by etching by performing RIE using the mask. As a result, the sacrifice pattern  72 ′ is remained in a peripheral area of pixels (including areas on the output wirings  12   a  and  12   b  and the input wiring  12   c , and within the surrounding etching hole  71 ), and is remained in the etching hole  71  between the thermoelectric conversion part  17  and the thermoelectric conversion part  18 .  
         [0096]    Next, as shown in FIG. 17, for example, BPSG (Bolon-Phosphorus doped Silicate Glass) film  73  is formed on the substrate. Subsequently, as shown in FIG. 18, the BPSG film  73  is etched by using the mask. The BPSG pattern  73 ′ obtained as this result corresponds to the photothermal conversion layer  13   a  and the support pillar  13   b  of FIG. 1. In the present embodiment, the size of the BPSG pattern  73 ′ is 5 μm per side and the thickness thereof is about 0.4 μm.  
         [0097]    Next, as shown in FIG. 19, the sacrifice layer  74  is formed on the substrate by CVD method. Material of the sacrifice layer  74  is amorphous silicon or polyimide. Furthermore, as shown in FIG. 20, a mask not shown is provided on the sacrifice layer  74 . A portion of the sacrifice layer  74  is removed by etching by performing RIE using the mask. As a result, the sacrifice layer pattern  74 ′ remains in an area covering the BPSG pattern  73 ′ (including an areas on the output wiring  12   a  and the input wiring  12   c , and an area on the etching hole between the thermoelectric conversion parts  17  and  18 ).  
         [0098]    Next, as shown in FIG. 21, the laminate film  75  obtained by laminating the silicon dioxide film and the silicon nitride film is formed on the substrate. Furthermore, the laminate film  75  is etched by using the mask not shown. Therefore, the laminate film pattern  75  is formed as the photothermal conversion layer  14   a  and the support pillar  14   b  of FIG. 1. According to the present embodiment, the size of the laminate film pattern is 10 μm per side, and the thickness of the silicon dioxide film is about 0.4 μm, and the thickness of the silicon nitride film is about 0.2 μm. The laminate film pattern  75  is selectively removed by etching so as to be able to remove the material of the sacrifice layer by etching.  
         [0099]    Next, as shown in FIG. 22, in order to selectively remove the sacrifice layer pattern  72 ′,  74 ′ and the material of the sacrifice layer embedded in the etching hole  71 , the material of the sacrifice layer is etched by using alkalis etching liquid solution such as KOH or TMAH (Tetra-Methyl-Ammonium-Hydroxide). In this step, the interlayer insulation films  11   e - 11   h , the embedded silicon dioxide film  11   b , the BPSG patter  73 ′ and the laminate film pattern  75  are not etched. As a result, the single crystal silicon support substrate  11   a  of the bottom surface of the etching hole formed in FIG. 18 is exposed in order to form a void portion  19   a  and the grooves  19   b , a void between the BPSG pattern  73 ′ corresponding to the photothermal conversion layer  13   a  and the support pillar  13   b , and the laminate film  75  corresponding to the photothermal conversion layer  14   a  and the support pillar  14   b  is formed, and a void is formed below the BPSG pattern  73 ′ corresponding to the photothermal conversion layer  13   a.    
         [0100]    After then, as shown in FIG. 23, the etching liquid such as TMAH is supplied to the single crystal silicon support substrate  11   a  via the etching hole  71 , and the single crystal silicon support substrate  11   a  is subjected to anisotropic etching. A hollow portion is generated on the single crystal support substrate  11   a  under the pixels of the thermal type infrared ray imaging device in order to form the hollow structure  20 .  
         [0101]    By the above-mentioned steps, it is possible to form the thermal type infrared ray imaging device of the first embodiment for one pixel shown in FIG. 1. In the present embodiment, the thermal type infrared ray imaging device has 320×240 pixels, each pixel arranging in two dimension array shape, and being formed on the same procedure as the above-mentioned procedure.  
         [0102]    Although the image area  51  of FIG. 5 can be formed by the above-mentioned steps, area except for the image area  51  can be formed by the ordinary semiconductor process. In a sequence of etching steps of FIGS. 22 and 23, a protection layer is provided in order to prevent etching for these areas so that the area except for the image area  51  is not etched. As the protection layer, it is possible to use a silicon dioxide film formed by CVD as the protection layer.  
         [0103]    Thus, according to the present embodiment, the infrared ray of first waveband and the infrared ray of second waveband are separately detected. Because the infrared rays can be separately outputted, it is possible to precisely measure the intensity of a plurality of infrared rays radiate from the objects and to estimate emissivity of the object under test. Therefore, it is possible to easily identify the material of the object and to precisely measure the absolute temperature. Accordingly, it is possible to improve contrast of image by the infrared ray and to realize colorization of image.  
         [0104]    Especially, according to the present embodiment, in order to separately detect the infrared rays of first and second wavebands, the photothermal conversion layers corresponding to the infrared rays of a plurality of wavebands are doubly disposed in the direction vertical to the substrate surface, and a plurality of thermoelectric conversion parts for converting heat generated by the photothermal conversion layers into electric signal are disposed by integrating in one pixel. Therefore, it is possible to prevent increase of the non-sensitive areas for the infrared rays of the respective wavebands, and to sensitively take a picture of a faraway small object.  
         [0105]    Furthermore, it is possible to improve heat sensitive accuracy in the thermoelectric part by ensuring heat isolation between both the thermoelectric conversion parts, thereby obtaining more excellent infrared ray image.  
         [0106]    The present invention is not limited to the above-mentioned embodiment. For example, as a thermal separation structure, a structure providing the groove between a plurality of thermal electric conversion parts has been adopted. However, despite of such a structure, after a V shape groove is formed, it is possible to use the other structure such as the structure in which porous ceramics and so on is embedded in the V shape groove.  
         [0107]    It is possible to use an element except for a diode as a thermoelectric conversion part. For example, it is possible to use the other devices such as an enhanced type MOS transistor, a depletion type MOS transistor, a combination of these MOS transistors, a bolometer of vanadium oxide or amorphous silicon, and so on.  
         [0108]    Furthermore, according to the present embodiment, the hollow structure has been formed between the support substrate and the pixel of the thermal type infrared ray imaging device, by etching the single crystal silicon support substrate of the SOI substrate. However, besides the method and the structure using the SOI substrate, it may be possible to adopt a method and a structure of forming the insulation film such as oxide or nitride formed on the support substrate, and poly-crystal or mono-crystal silicon layer in order from bottom, and the surface of the support substrate and the insulation film are removed by etching in order to form the hollow structure.  
         [0109]    Furthermore, although aluminum has been used as a wiring material in the above-mentioned embodiment, it is possible to use the other metal material. Especially, the output wirings  12   a  and  12   b , the input wiring  12   c , the vertical signal wiring for first waveband  15  and the vertical signal wiring for second waveband  16  are formed of polycide structure at the same fabrication step as that of forming the gate electrode of the MOS transistor of the peripheral circuit, thereby simplifying fabrication process. The present invention is applicable to a poly-metal structure (laminate structure of a polysilicon layer and a metal layer). The poly-metal structure can be formed at the same fabrication step as that of the gate electrode of the MOS transistor of the peripheral circuit. If the poly-metal structure is adopted, it is possible to reduce thermal noise due to electric resistance of the wiring portion of the support leg (the output wirings  12   a  and  12   b  and the input wiring  12   c ), thereby improving sensitivity. In this case, as a laminate structure of the support leg wirings (the output wirings  12   a  and  12   b  and the input wiring  12   c ), for example, it is possible to form the laminate film made of a titan nitride film as a barrier metal and a tungsten film for low resistance on the polysilicon layer.  
         [0110]    Furthermore, it is possible to selectively leave the silicon nitride film on a side wall of the support leg wiring. In this case, it is possible to form the support leg wiring by using the same layer as the silicon nitride film formed on the gate sidewall of the MOS transistors of the peripheral circuit. Because of this, it is possible to drastically shorten the number of steps. Especially, it is possible to fabricate the high sensitive support structure at high yield and low cost, while getting the most out of compliance of process, by using the step of forming silicon nitride film and the step of forming the support leg wirings at the same layer as the gate electrode of the MOS transistor of the peripheral circuit.  
         [0111]    Besides, it is possible to modify the present invention at range which does not deviate from purposes of the present invention, if necessary.