The priority application number JP2007-304147, Image Sensor, Nov. 26, 2007, Mamoru Arimoto, Ryu Shimizu, Hayato Nakashima, Kaori Misawa, upon which this patent application is based is hereby incorporated by reference.
1. Field of the Invention
The present invention relates to an image sensor, and more particularly, it relates to an image sensor comprising an electrode for forming an electric field storing signal charges.
2. Description of the Background Art
An image sensor comprising an electrode for forming an electric field storing electrons (signal charges) is known in general.
A conventional general CMOS image sensor comprising a photodiode converting light incident by photoelectric conversion to electrons, an electrode for reading charges stored in the photodiode and a floating diffusion region for converting stored electrons to electric signals is disclosed in a non-patent document, Basics and Applications of a CCD/CMOS Image Sensor (pp. 189-191) by Kazuya Yonemoto, CQ publishing, (published in Feb. 1, 2004).
An image sensor according to a first aspect of the present invention comprises a charge storage portion for storing and transferring signal charges, a first electrode for storing the signal charges in the charge storage portion, a second electrode for transferring the signal charges to the charge storage portion, a voltage conversion portion for converting the signal charges to a voltage, a third electrode provided between the first electrode and the voltage conversion portion for transferring the signal charges stored in the charge storage portion to the voltage conversion portion and an impurity region provided under at least the first electrode, the second electrode and the third electrode for forming a path through which the signal charges transfer, wherein the impurity concentration of a region of the impurity region corresponding to a portion located under the first electrode is higher than the impurity concentration of a region of the impurity region corresponding to each of portions located under at least the second electrode and the third electrode.
A sensor unit according to a second aspect of the present invention comprises a charge storage portion for storing and transferring signal charges, a first electrode for storing the signal charges in the charge storage portion, a second electrode for transferring the signal charges to the charge storage portion, a voltage conversion portion for converting the signal charges to a voltage, a third electrode provided between the first electrode and the voltage conversion portion for transferring the signal charges stored in the charge storage portion to the voltage conversion portion and an impurity region provided under at least the first electrode, the second electrode and the third electrode for forming a path through which the signal charges transfer, wherein the impurity concentration of a region of the impurity region corresponding to a portion located under the first electrode is higher than the impurity concentration of a region of the impurity region corresponding to each of portions located under at least the second electrode and the third electrode.
A CMOS image sensor according to a third aspect of the present invention comprises a charge storage portion for storing and transferring signal charges, a first electrode for storing the signal charges in the charge storage portion, a second electrode for transferring the signal charges to the charge storage portion, a voltage conversion portion for converting the signal charges to a voltage, a third electrode provided between the first electrode and the voltage conversion portion for transferring the signal charges stored in the charge storage portion to the voltage conversion portion, a charge increasing portion for increasing the signal charges stored in the charge storage portion and an impurity region provided under at least the first electrode, the second electrode and the third electrode for forming a path through which the signal charges transfer, wherein the first electrode, the second electrode, the third electrode and the charge increasing portion are provided in a pixel, and the impurity concentration of a region of the impurity region corresponding to a portion located under the first electrode is higher than the impurity concentration of a region of the impurity region corresponding to each of portions located under at least the second electrode and the third electrode.
The foregoing and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.
Embodiments of the present invention will be hereinafter described with reference to the drawings.
A structure of a CMOS image sensor according to a first embodiment will be now described with reference to
The CMOS image sensor according to the first embodiment comprises an imaging portion 51 including a plurality of pixels 50 arranged in the form of a matrix, a row selection register 52 and a column selection register 53, as shown in
As to the sectional structure of the pixels 50 of the CMOS image sensor according to the first embodiment, element isolation regions 2 for isolating the pixels 50 from each other are formed on a surface of a p-type well region 1 formed on a surface of an n-type silicon substrate (not shown), as shown in
The PD portion 4 has a function of generating electrons in response to the quantity of incident light and storing the generated electrons. The PD portion 4 is formed to be adjacent to the corresponding element isolation region 2 as well as to the transfer channel 3. The FD region 5 has a function of holding a charge signal formed by transferred electrons and converting the charge signal to a voltage. The FD region 5 is formed to be adjacent to the corresponding the transfer channel 3. Thus, the FD region 5 is opposed to the PD portion 4 through the transfer channel 3.
A gate insulating film 6 made of SiO2 is formed on an upper surface of the transfer channel 3. A transfer gate electrode 7, a multiplier gate electrode 8, a transfer gate electrode 9, a storage gate electrode 10 and a read gate electrode 11 are formed on the gate insulating film 6 in this order from the side of the PD portion 4 toward the side of the FD region 5. A reset gate electrode 12 is formed on a position holding the FD region 5 between the read gate electrode 11 and the reset gate electrode 12 through the gate insulating film 6 and a reset drain region 13 is formed on a position opposed to the FD region 5 with the reset gate electrode 12 therebetween. The electron multiplying portion 3a is provided on a region of the transfer channel 3 located under the multiplier gate electrode 8, and the electron storage portion 3b is provided on a region of the transfer channel 3 located under the storage gate electrode 10. The transfer gate electrode 7, the multiplier gate electrode 8, the transfer gate electrode 9, the storage gate electrode 10 and the read gate electrode 11 are examples of the “fifth electrode”, the “fourth electrode”, the “second electrode”, the “first electrode” and the “third electrode” in the present invention respectively. The electron multiplying portion 3a is an example of the “charge increasing portion” in the present invention, and the electron storage portion 3b is an example of the “charge storage portion” in the present invention.
The transfer gate electrode 7 is formed between the PD portion 4 and the multiplier gate electrode 8. The read gate electrode 11 is formed between the storage gate electrode 10 and the FD region 5. The read gate electrode 11 is formed to be adjacent to the FD region 5.
According to the first embodiment, an impurity concentration of the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 is higher than the impurity concentration of each of regions of the transfer channel 3 located under the remaining electrodes other than the storage gate electrode 10. More specifically, under a condition where the gate insulating film 6 has a thickness of about 50 nm, for example, a peak concentration of the impurity in the impurity region (transfer channel 3) located under each of the remaining electrodes other than the storage gate electrode 10 is about 8.5×1016 cm−3, while a peak concentration of the impurity in the impurity region (electron storage portion 3b) located under the storage gate electrode 10 is about 2.5×1017 cm−3. For example, arsenic (As) is implanted as the impurity, and a depth of the peak concentration is located at a position of about 0.1 μm from a surface of the transfer channel 3. Thus, a potential of the region of the transfer channel 3 located under the storage gate electrode 10 is rendered higher than that of the region of the transfer channel 3 located under each of the remaining electrodes other than the storage gate electrode 10, when the same level signal is supplied (the same voltage is applied) to the electrodes respectively.
As shown in
In each pixel, when ON-state (high-level) clock signals φ1, φ3, φ4 and φ5 are supplied to the transfer gate electrodes 7 and 9 and the storage gate electrode 10 and the read gate electrode 11 through the wiring layers 20, 22, 23 and 24 respectively, voltages of about 2.9 V are applied to the transfer gate electrodes 7 and 9, the storage gate electrode 10 and the read gate electrode 11, as shown in
According to the first embodiment, the regions of the transfer channel located under the transfer gate electrodes 7 and 9 and the read gate electrode 11 respectively are controlled to potentials of about 4 V and the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 having an high concentration is controlled to a potential of about 6 V, when the voltages of about 2.9 V are applied (high-level clock signals are supplied) to the transfer gate electrodes 7 and 9, the storage gate electrode 10 and the read gate electrode 11 respectively.
When an ON-state (high-level) clock signal φ2 is supplied to the multiplier gate electrode 8 through the wiring layer 21, a voltage of about 24 V is applied to the multiplier gate electrode 8. Thus, the region of the transfer channel 3 located under the multiplier gate electrode 8 is controlled to a high potential of about 25 V when the ON-state (high-level) clock signal φ2 is supplied to the multiplier gate electrode 8. The voltage applied when supplying the ON-state (high-level) clock signal φ2 to the multiplier gate electrode 8 is an example of the “third voltage” in the present invention.
When OFF-state (low-level) clock signals φ1, φ2, φ3, φ4 and φ5 are supplied to the transfer gate electrode 7, the multiplier gate electrode 8, the transfer gate electrode 9, the storage gate electrode 10 and the read gate electrode 11 respectively, voltages of about 0 V (OFF-state voltages) are applied to the transfer gate electrode 7, the multiplier gate electrode 8, the transfer gate electrode 9 and the storage gate electrode 10 and the read gate electrode 11. At this time, according to the first embodiment, the regions of the transfer channel 3 located under the transfer gate electrode 7, the multiplier gate electrode 8, the transfer gate electrode 9 and the read gate electrode 11 are controlled to potentials of about 1.5 V, and the potential of the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 having a high concentration is controlled to a potential of about 3.5 V. Each of the voltages (about 0 V) applied when supplying the OFF-state (low-level) clock signals φ1, φ2, φ3, φ4 and φ5 to each of the electrodes is an example of the “first voltage” in the present invention.
According to the first embodiment, the potential (about 3.5 V) of the storage gate electrode 10 in supplying the OFF-state clock signal φ4 to the storage gate electrode 10 is rendered higher than the potentials (about 1.5 V) of the transfer channel 3 located under the transfer gate electrode 9 and the read gate electrode 11 in supplying the OFF-state clock signals φ3 and 5 to the transfer gate electrode 9 and the read gate electrode 11. The potential (about 3.5 V) of the storage gate electrode 10 in supplying the OFF-state clock signal φ4 to the storage gate electrode 10 is rendered lower than the potentials (about 4 V) of the transfer channel 3 located under the transfer gate electrode 9 and the read gate electrode 11 in supplying the ON-state clock signals φ3 and φ5 to the transfer gate electrode 9 and the read gate electrode 11.
The FD region 5 is controlled to a potential of about 5 V. The reset drain region 13 is controlled to a potential of about 5 V and has a function as an ejecting portion of electrons held in the FD region 5.
The transfer gate electrode 7 has a function of transferring electrons generated by the PD portion 4 to the electron multiplying portion 3a located on the region of the transfer channel 3 located under the multiplier gate electrode 8 through the region of the transfer channel 3 located under the transfer gate electrode 7 by supplying the ON-state signal to the transfer gate electrode 7. The region of the transfer channel 3 located under the transfer gate electrode 7 has a function as an isolation barrier dividing the PD portion 4 and the region (electron multiplying portion 3a) of the transfer channel 3 located under the multiplier gate electrode 8 from each other when the OFF-state (low-level) clock signal φ1 is supplied to the transfer gate electrode 7.
A high electric field is applied to the electron multiplying portion 3a located on the region of the transfer channel 3 located under the multiplier gate electrode 8 by supplying the ON-state signal to the multiplier gate electrode 8. Then the speed of the electrons transferred from the PD portion 4 through the region of the transfer channel 3 located under the transfer gate electrode 7 is increased by the high electric field generated in the electron multiplying portion 3a and the electrons transferred from the PD portion 4 are multiplied by impact ionization with atoms in the impurity region.
The transfer gate electrode 9 has a function of transferring the electrons between the region (electron multiplying portion 3a) of the transfer channel 3 located under the multiplier gate electrode 8 and the electron storage portion 3b provided on the region of the transfer channel 3 located under the storage gate electrode 10 when the ON-state signal is supplied. When the OFF-state signal is supplied to the transfer gate electrode 9, on the other hand, the transfer gate electrode 9 functions as a charge transfer barrier for suppressing transfer of the electrons between the electron multiplying portion 3a located under the multiplier gate electrode 8 and the electron storage portion 3b located under the storage gate electrode 10.
The read gate electrode 11 has a function of transferring the electrons stored in the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 to the FD region 5 by being supplied with the ON-state (high-level) signal. Further, the read gate electrode 11 has a function of dividing the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 and the FD region 5 from each other when the OFF-state (low-level) signal is supplied to the read gate electrode 11.
As shown in
The CMOS image sensor according to the first embodiment is so formed as to reduce the number of wires and the number of transistors for decoding by the aforementioned circuit structure. Thus, the overall CMOS image sensor can be downsized. In this circuit structure, the read gate electrodes 11 are on-off controlled every row, while the remaining gate electrodes other than the read gate electrodes 11 are simultaneously on-off controlled with respect to the overall pixels 50.
An electron transferring operation and an electron multiplying operation of the CMOS image sensor according to the first embodiment will be now described with reference to
When light is incident upon the PD portion 4, the electrons are generated in PD portion 4 by photoelectric conversion. In a period A shown in
In a period B, a voltage of about 2.9 V is applied to the transfer gate electrode 9 and a voltage of about 0 V is thereafter applied to the multiplier gate electrode 8. Thus, electrons are transferred from the electron multiplying portion 3a (about 1.5 V) under the multiplier gate electrode 8 to the region of the transfer channel 3 located under the transfer gate electrode 9 having a higher potential (about 4V). In a period C, a voltage of about 0 V is thereafter applied to the transfer gate electrode 9. Thus, electrons are transferred from the region (about 1.5 V) of the transfer channel 3 located under the transfer gate electrode 9 to the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10, having a higher potential (about 3.5 V). At this time, according to the first embodiment, electrons are stored in the electron storage portion 3b in the state of controlling so as to applying the OFF-state voltage to each electrode.
In a period D, a voltage of about 2.9 V is applied to the read gate electrode 11, to control the potential of the region of the transfer channel 3 located under the read gate electrode 11 to a potential of about 4 V. At this time, the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 is controlled to a potential of about 3.5 V, and hence electrons are transferred to the FD region 5 controlled to a higher potential through the region (about 4V) of the transfer channel 3 located under the read gate electrode 11. Thus, the electron transferring operation is completed.
In the electron multiplying operation, the operations of the periods A to C in
The electrons are transferred to the electron multiplying portion 3a to be multiplied in the aforementioned manner. The transfer gate electrode 9 is brought into an OFF-state in a period G, thereby completing the electron multiplying operation. The aforementioned operation in the periods A to C and the periods E to G (electron transferring operation between the electron multiplying portion 3a and the electron storage portion 3b) is controlled to be performed a plurality of times (about 400 times, for example), whereby the electrons transferred from the PD portion 4 are multiplied to about 2000 times. A charge signal by thus multiplied and stored electrons is read as a voltage signal through the FD region 5 and the signal line 25 by the aforementioned read operation.
According to the first embodiment, as hereinabove described, the impurity concentration of the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 is rendered higher than that of the region of the transfer channel 3 located under each of the remaining electrodes other than the storage gate electrode 10, whereby the potential of the electron storage portion 3b is higher than that of the region of the transfer channel 3 located under each of the remaining electrodes when applying the same voltage (supplying the same level signal) to the remaining electrodes respectively and hence the larger number of electrons can be held. Therefore, the amount of signals to read noise is increased by multiplying electrons, and hence a signal-to-noise ratio in low level illuminance can be improved. Additionally, the multiplied electrons can be held and hence noise can be inhibited from increase resulting from increase in the ratio of noise to signals in the signal-to-noise ratio.
According to the aforementioned first embodiment, the potential (about 3.5 V) of the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 in supplying the OFF-state clock signal φ4 thereto is rendered higher than the potentials (about 1.5 V) of the regions of the transfer channel 3 located under the transfer gate electrode 9 and the read gate electrode 11 in supplying the OFF-state clock signals φ3 and φ5 thereto, whereby electrons can be held in the electron storage portion 3b without bringing the storage gate electrode 10 into an ON-state. At this time, the potentials (about 1.5 V) of the regions of the transfer channel 3 located under the transfer gate electrode 9 and the read gate electrode 11 are lower than the potential (about 3.5 V) of the electron storage portion 3b, and hence the height of a potential barrier between the region of the transfer channel 3 located under the transfer gate electrode 9 and the electron storage portion 3b and the height of a potential barrier between the region of the transfer channel 3 located under the read gate electrode 11 and the electron storage portion 3b are increased. Therefore, electrons can be reliably inhibited from moving from the electron storage portion 3b. Further, electrons can be held in the state where the storage gate electrode 10 remains in the OFF-state. In other words, electrons can be reliably held in the state of applying no voltage to the storage gate electrode 10.
According to the aforementioned first embodiment, the potential (about 3.5 V) of the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 in supplying the OFF-state signal thereto is rendered lower than the potential (about 4 V) of the region of the transfer channel 3 located under the read gate electrode 11 in supplying the ON-state signal thereto, whereby the potential difference between the electron storage portion 3b in the OFF-state and the FD region 5 can be formed when the read gate electrode 11 is in the ON-state, and electrons can be further easily transferred. In other words, a transfer effieciency of electrons can be increased by the potential difference between the electron storage portion 3b in the OFF-state and the FD region 5.
According to the aforementioned first embodiment, the potential (about 3.5 V) of the region (electron storage portion 3b) of the transfer channel 3 located under the storage gate electrode 10 in supplying the OFF-state clock signal φ4 thereto is rendered lower than the potential (about 4 V) of the region of the transfer channel 3 located under the transfer gate electrode 9 in supplying the ON-state clock signal φ3 thereto, whereby electrons can be transferred to the electron multiplying portion 3a while remaining the storage gate electrode 10 in the OFF-state, and hence the electrons stored in the electron storage portion 3b can be easily multiplied.
According to the aforementioned first embodiment, the electron multiplying operation by transferring electrons from the electron storage portion 3b to the electron multiplying portion 3a and the electron transferring operation by transferring electrons from the electron multiplying portion 3a to the electron storage portion 3b are alternately repeatedly performed in the state of supplying the OFF-state signal to the storage gate electrode 10, whereby both operations of the electron transferring operation and the electron multiplying operation can be performed while remaining the storage gate electrode 10 in the OFF-state. Therefore, control can be inhibited from complication.
According to the aforementioned first embodiment, the regions of the transfer channel 3 located under the transfer gate electrode 7, the multiplier gate electrode 8, the transfer gate electrode 9 and the read gate electrode 11 have the same impurity concentration, whereby the potentials of the transfer channel 3 located under the transfer gate electrode 7, the multiplier gate electrode 8, the transfer gate electrode 9 and the read gate electrode 11 are the same when the same voltage is applied to the respective electrodes. In other words, the potential changes of the regions of the transfer channel 3 located under the respective electrodes when applying the ON-state voltages and the OFF-state voltages to the respective electrodes are also the same, and hence the electron transferring operation can be easily controlled.
Referring to
The electron transferring operation of the CMOS image sensor according to the second embodiment will be now described. As shown in
The electron multiplying operation of the CMOS image sensor according to the second embodiment will be now described. As shown in
Thus, the electron transferring and multiplying operations are performed by bringing the storage gate electrode 10 into the ON-state, according to the second embodiment. Similarly to the first embodiment, the operation in the periods A, B and H to L (transfer operation between the electron multiplying portion 3a and the electron storage portion 3b) is controlled to be performed a plurality of times (about 400 times, for example), thereby multiplying electrons transferred from the PD portion 4 to about 2000 times.
According to the second embodiment, as hereinabove described, the CMOS image sensor is so formed that electrons are stored by bringing the storage gate electrode 10 into the ON-state, whereby the electron storage portion 3b is maintained at a high potential due to an elevated concentration and hence a larger number of electrons can be held in the electron storage portion 3b. Therefore, electrons can be reliably held even when the electrons are multiplied to reach the larger number. At this time, the potential difference between the regions of the transfer channel 3 located under the transfer gate electrode 9 and the read gate electrode 11 supplied with the OFF-state signals and the electron storage portion 3b brought into the ON-state are larger than the potential difference between the regions of the transfer channel 3 located under the transfer gate electrode 9 and the read gate electrode 11 supplied with the OFF-state signals and the electron storage portion 3b in bringing the storage gate electrode 10 into the OFF-state. Therefore, the height of a potential barrier between the region of the transfer channel 3 located under the transfer gate electrode 9 and the electron storage portion 3b and the height of a potential barrier between the region of the transfer channel 3 located under the read gate electrode 11 and the electron storage portion 3b are relatively increased, and hence electrons can be reliably held in the electron storage portion 3b.
According to the aforementioned second embodiment, the potential (6 V) of the region of the transfer channel 3 located under the storage gate electrode 10 in bringing the storage gate electrode 10 into the ON-state is higher than the potentials (4 V) of the regions of the transfer channel 3 located under the transfer gate electrode 9 and the read gate electrode 11 in bringing the transfer gate electrode 9 and the read gate electrode 11 into the ON-states, and hence electrons can be easily held in the electron storage portion 3b also when the storage gate electrode 10 is brought into the ON-state.
Although the present invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the spirit and scope of the present invention being limited only by the terms of the appended claims.
For example, while each of the aforementioned first and second embodiments is applied to the active CMOS image sensor amplifying a charge signal in each pixel 50 as an exemplary image sensor, the present invention is not restricted to this but is also applicable to a passive CMOS image sensor not amplifying a charge signal in each pixel.
While the regions of the transfer channel 3 located under the transfer gate electrode 7, the transfer gate electrode 9 and the read gate electrode 11 are controlled to potentials of about 4 V when the transfer gate electrode 7, the transfer gate electrode 9 and the read gate electrode 11 are in the ON-states in each of the first and second embodiments, the present invention is not restricted to this but the regions of the transfer channel 3 located under the transfer gate electrode 7, the transfer gate electrode 9 and the read gate electrode 11 may be controlled to different potentials when the transfer gate electrode 7, the transfer gate electrode 9 and the read gate electrode 11 are in the ON-states. In this case, the potentials of the regions of the transfer channel 3 located under the transfer gate electrode 9 and the read gate electrode 11 in the ON-states must be controlled to be higher than that of the region of the transfer channel 3 located under the storage gate electrode 10 in the OFF-state.
While the transfer channel 3, the PD portion 4 and the FD region 5 are formed on the surface of the p-type well region 1 formed on the surface of the n-type silicon substrate (not shown) in each of the aforementioned first and second embodiments, the present invention is not restricted to this but the transfer channel 3, the PD portion 4 and the FD region 5 may be formed on the surface of the p-type silicon substrate.
While the electrons are employed as the signal charges in each of the aforementioned first and second embodiments, the present invention is not restricted to this but holes may alternatively be employed as the signal charges by entirely reversing the conductivity type of the substrate impurity and the polarities of the applied voltages.
While As (arsenic) is implanted so that the region of the transfer channel 3 located under the storage gate electrode 10 has a high concentration in each of the aforementioned first and second embodiments, the present invention is not restricted to this but an impurity or a dopant other than As (arsenic) may be implanted.
While the ON-state voltage is applied to the region (electron multiplying portion 3a) of the transfer channel 3 located under the multiplier gate electrode 8 and the ON-state voltage is applied to the transfer gate electrode 7 to transfer electrons when transferring the electrons from the PD portion 4 in each of the aforementioned first and second embodiments, the present invention is not restricted to this but ON-state voltages may be applied to the electrodes successively from the transfer gate electrode 7 to transfer electrons when transferring electrons from the PD portion 4. More specifically, an ON-state voltage is applied to the transfer gate electrode 7 to transfer electrons from the PD portion 4 to the region of the transfer channel 3 located under the transfer gate electrode 7 in a period A, as shown in
While each of the aforementioned first and second embodiments of the present invention is applied to the CMOS image sensor employed as an exemplary image sensor, the present invention is not restricted to this but is also applicable to a sensor unit, other than the image sensor, performing sensing by generating electrons. For example, the CMOS image sensor according to each of the first and second embodiments can alternatively be operated as a sensor unit by arranging a charge generating portion 40 in place of the PD portion 4 as in another modification of the first and second embodiments shown in
Number | Date | Country | Kind |
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2007-304147 | Nov 2007 | JP | national |