The present disclosure relates to an imaging device and an electronic device, for example, to an imaging device and an electronic device that can obtain better pixel signals.
Imaging devices such as complementary metal oxide semiconductor (CMOS) image sensors and charge coupled devices (CCDs) are widely used in digital still cameras, digital video cameras, and the like.
For example, light incident on a CMOS image sensor is subjected to photoelectric conversion in a photodiode (PD) included in a pixel. Then, a charge generated in the PD is transferred to floating diffusion (FD) through a transfer transistor, and converted into a pixel signal having a level according to an amount of received light.
Meanwhile, in a conventional CMOS image sensor, since a scheme of sequentially reading pixel signals from respective pixels row by row, a so-called rolling shutter scheme is generally employed, distortion has sometimes occurred in an image due to a difference in exposure timing.
Therefore, for example, Patent Document 1 discloses a CMOS image sensor that employs a scheme of reading pixel signals from all pixels simultaneously by providing a charge holding part in each pixel, a so-called global shutter scheme, the CMOS image sensor having an all pixel simultaneous electronic shutter function. By employing the global shutter scheme, exposure timing becomes the same for all the pixels, making it possible to avoid the occurrence of distortion in an image.
Since pixel layout is limited in a case where a configuration in which the charge holding part is provided in the pixel is employed, an aperture ratio decreases, and there is a concern that sensitivity of the PD may decrease or capacity of the PD and the charge holding part may decrease. Moreover, there is a concern that optical noise may be generated by light incident into the charge holding part while holding a charge.
The present technology has been made in view of such a situation, and makes it possible to obtain better pixel signals.
An imaging device according to one aspect of the present technology includes: a photoelectric conversion part configured to convert received light into a charge; a holding part configured to hold a charge transferred from the photoelectric conversion part; and a light shielding part configured to shield light between the photoelectric conversion part and the holding part, in which the photoelectric conversion part, the holding part, and the light shielding part are formed in a semiconductor substrate having a predetermined thickness, and the light shielding part of a transfer region that transfers the charge from the photoelectric conversion part to the holding part is formed as a non-penetrating light shielding part that does not penetrate the semiconductor substrate, and the light shielding part other than the transfer region is formed as a penetrating light shielding part that penetrates the semiconductor substrate.
An electronic device according to one aspect of the present technology includes: an imaging device including: a photoelectric conversion part configured to convert received light into a charge; a holding part configured to hold a charge transferred from the photoelectric conversion part; and a light shielding part configured to shield light between the photoelectric conversion part and the holding part, the photoelectric conversion part, the holding part, and the light shielding part being formed in a semiconductor substrate having a predetermined thickness, the light shielding part of a transfer region that transfers the charge from the photoelectric conversion part to the holding part being formed as a non-penetrating light shielding part that does not penetrate the semiconductor substrate, and the light shielding part other than the transfer region being formed as a penetrating light shielding part that penetrates the semiconductor substrate; and a processing unit configured to process a signal from the imaging device.
The imaging device according to one aspect of the present technology includes the photoelectric conversion part that converts received light into a charge, the holding part that holds a charge transferred from the photoelectric conversion part, and the light shielding part that shields light between the photoelectric conversion part and the holding part. The photoelectric conversion part, the holding part, and the light shielding part are formed in a semiconductor substrate having a predetermined thickness, and the light shielding part of a transfer region that transfers the charge from the photoelectric conversion part to the holding part is formed as a non-penetrating light shielding part that does not penetrate the semiconductor substrate, and the light shielding part other than the transfer region is formed as a penetrating light shielding part that penetrates the semiconductor substrate.
The electronic device according to one aspect of the present technology includes the imaging device.
According to one aspect of the present technology, better pixel signals can be obtained.
Note that advantageous effects described here are not necessarily restrictive, and any of the effects described in the present disclosure may be applied.
A mode for carrying out the present technology (hereinafter referred to as an embodiment) will be described below.
Configuration of Imaging Device
The CMOS image sensor 30 includes a pixel array part 41, a vertical drive part 42, a column processing part 43, a horizontal drive part 44, and a system control part 45. The pixel array part 41, the vertical drive part 42, the column processing part 43, the horizontal drive part 44, and the system control part 45 are formed on a semiconductor substrate (chip) which is not shown.
In the pixel array part 41, unit pixels (pixel 50 in
In the pixel array part 41, furthermore, pixel drive lines 46 are formed along a horizontal direction in the drawing (arrangement direction of pixels in a pixel row) for each row of the matrix pixel array, and vertical signal lines 47 are formed along a vertical direction in the drawing (arrangement direction of pixels in a pixel column) for each column. One end of each pixel drive line 46 is connected to an output end corresponding to each row of the vertical drive part 42.
The CMOS image sensor 30 further includes a signal processing part 48 and a data storage part 49. The signal processing part 48 and the data storage part 49 may be an external signal processing part provided on a substrate different from the CMOS image sensor 30, for example, processing by a digital signal processor (DSP) or software, or may be mounted on the same substrate as the CMOS image sensor 30.
The vertical drive part 42 is a pixel drive part that includes a shift register, an address decoder, or the like, and drives respective pixels of the pixel array part 41 in a manner of driving all pixels at the same time, pixels of respective rows, or the like. This vertical drive part 42 includes a reading scanning system, a sweeping scanning system, or batch sweep, and batch transfer, although illustration of the specific configuration thereof is omitted.
The reading scanning system sequentially selects and scans the unit pixels of respective rows of the pixel array part 41 in order to read signals from the unit pixels. In a case of row drive (rolling shutter operation), regarding sweeping, sweeping scan is performed on a read row on which reading scan is performed by the reading scanning system in advance of the reading scan by a time of a shutter speed. Furthermore, in a case of global exposure (global shutter operation), batch sweeping is performed in advance of batch transfer by a time of the shutter speed.
By this sweeping, unnecessary charges are swept (reset) from the photoelectric conversion elements of the unit pixels of the read row. Then, a so-called electronic shutter operation is performed by sweeping (resetting) unnecessary charges. Here, the electronic shutter operation is an operation of discarding the light charges of the photoelectric conversion elements and newly starting exposure (starting accumulation of light charges).
The signal read by the reading operation by the reading scanning system corresponds to the light amount incident after the immediately preceding reading operation or the electronic shutter operation. In a case of row drive, a period from a reading timing by the immediately preceding reading operation or a sweeping timing by the electronic shutter operation to a reading timing by the current reading operation is a light charge accumulation period (exposure period) in the unit pixel. In a case of global exposure, a period from the batch sweeping to the batch transfer is the accumulation period (exposure period).
A pixel signal output from each unit pixel of the pixel row selected and scanned by the vertical drive part 42 is supplied to the column processing part 43 through each of the vertical signal lines 47. The column processing part 43 performs predetermined signal processing on the pixel signal output from each unit pixel of the selected row through the vertical signal line 47 for each pixel column of the pixel array part 41, and temporarily holds the pixel signal subjected to signal processing.
Specifically, the column processing part 43 performs at least noise removal processing, for example, correlated double sampling (CDS) processing as the signal processing. Pixel-specific fixed pattern noise such as reset noise and threshold variation of amplification transistors is removed by the correlated double sampling performed by the column processing part 43. Note that it is possible to cause the column processing part 43 to have, for example, an analog-digital (AD) conversion function in addition to the noise removal processing, and to output a signal level as a digital signal.
The horizontal drive part 44 includes a shift register, an address decoder, and the like, and selects the unit circuits corresponding to the pixel column of the column processing part 43 sequentially. The pixel signals subjected to signal processing by the column processing part 43 are sequentially output to the signal processing part 48 by the selection and scanning performed by the horizontal drive part 44.
The system control part 45 includes a timing generator that generates various timing signals and the like, and controls driving of the vertical drive part 42, the column processing part 43, the horizontal drive part 44, and the like on the basis of the various timing signals generated by the timing generator.
The signal processing part 48 has at least an addition processing function, and performs various types of signal processing such as addition processing on the pixel signal output from the column processing part 43. When the signal processing part 48 performs signal processing, the data storage part 49 temporarily stores data necessary for the processing.
Structure of Unit Pixel
Next, specific structure of the unit pixel 50 arranged in a matrix in the pixel array part 41 of
With a pixel 50a that shows
First, with reference to
As shown in
Note that the image sensor 30 is a so-called back-illuminated CMOS image sensor in which a back surface opposite to a front surface of the semiconductor substrate 63 where the wiring layer 61 is provided on the semiconductor substrate 63 (surface facing upward in
The wiring layer 61 is, for example, supported by a substrate support (not shown) disposed thereunder, and has a configuration in which a plurality of wires 71 that performs processing such as reading a charge of the PD 51 formed in the semiconductor substrate 63 is embedded in an interlayer insulating film 72.
Furthermore, in the wiring layer 61, a TRX gate 73 constituting a transfer transistor is disposed below the semiconductor substrate 63 via the oxide film 62 in a region between the PD 51 and the charge holding part 54. In response to application of a predetermined voltage to the TRX gate 73, a charge accumulated in the PD 51 is transferred to the charge holding part 54.
The oxide film 62 has insulating properties and insulates a surface side of the semiconductor substrate 63. In the semiconductor substrate 63, an N-type region constituting the PD 51 and an N-type region constituting the charge holding part 54 are formed.
Furthermore, a surface pinning layer 74-1 is formed on a back side of the PD 51 and the charge holding part 54, and a surface pinning layer 74-2 is formed on a front side of the PD 51 and the charge holding part 54. Moreover, in the semiconductor substrate 63, an interpixel separation region 75 for separating the pixel 50a and another adjacent pixel 50a is formed so as to surround an outer periphery of the pixel 50a.
The light shielding layer 64 is formed by embedding a light shielding part 76 including a material having light shielding properties in a high dielectric constant material film 77. For example, the light shielding part 76 includes a material such as tungsten (W), aluminum (Al), or copper (Cu), and is connected to GND which is not shown. The high dielectric constant material film 77 includes a material such as silicon dioxide (SiO2), hafnium oxide (HfO2), tantalum pentoxide (Ta2O5), or zirconium dioxide (ZrO2).
Furthermore, the light shielding part 76 includes a lid part 76A disposed to cover the semiconductor substrate 63, and an embedded part 76B embedded in a vertical groove formed in the semiconductor substrate 63 to surround the PD 51 and the charge holding part 54. In other words, the lid part 76A is formed substantially in parallel to each layer constituting the pixel 50a, and the embedded part 76B is formed to a predetermined depth to extend in a direction substantially orthogonal to the lid part 76A.
Here, besides a configuration in which the embedded part 76B of the light shielding part 76 is formed in the interpixel separation region 75 to surround the PD 51 and the charge holding part 54, the embedded part 76B may have a configuration in which, for example, the embedded part 76B forms a periphery of the charge holding part 54 or a configuration in which the embedded part 76B is formed between the PD 51 and the charge holding part 54. In other words, it is required at least that the embedded part 76B is formed between the PD 51 and the charge holding part 54, and that the PD 51 and the charge holding part 54 are separated by the embedded part 76B.
Furthermore, in the light shielding part 76, an aperture 76C for allowing light to enter the PD 51 is formed. In other words, the aperture 76C is formed in a region corresponding to the PD 51, and other regions, for example, regions where the charge holding part 54, an FD 55, or the like are formed are shielded by the light shielding part 76.
Furthermore, in an example shown in
In other words, the light shielding part cannot be formed in the region between the PD 51 and the charge holding part 54, which is used for charge transfer, but by forming the embedded part 76B outside the region, it is possible to effectively suppress light leaking into the charge holding part 54 from a region other than the PD 51 of the same pixel 50a.
In the following description, the light shielding part 76 is described as the penetrating light shielding part 76 so as to penetrate the semiconductor substrate 63, and the light shielding part 76 that does not penetrate the semiconductor substrate 63 is described as the non-penetrating light shielding part 76. In
In the color filter layer 65, filters that transmit light of color corresponding to each pixel 50a are disposed, and for example, filters that transmit green, blue, and red light are disposed in the so-called Bayer array in each pixel 50a.
The on-chip lens 66 is a small lens for concentrating, on the PD 51, incident light incident on the pixel 50a.
As described above, the pixel 50a includes the light shielding part 76 in which the embedded part 76B is formed at least between the PD 51 and the charge holding part 54. With this configuration, as shown by hollow arrows in
About Light Incident into Charge Holding Region>
With the pixel 50a shown in
The configuration of the pixel 50 for reducing an influence of a light component from the wiring layer 61 side in order to further suppress generation of optical noise that is expected to be generated in a case where light leaks into the charge holding region 68 will be described.
Other Configurations of Pixel
When the pixel 50b shown in
The thickness of the charge holding part 54b of the pixel 50b shown in
Thus, PLS can be suppressed by only forming the thickness T3 of the charge holding part 54b and the pinning layer 74-1b to be equal to or less than the thickness T2 that is half the thickness of the semiconductor substrate 63.
With reference to
Accordingly, such a structure makes it possible to reduce the influence of the light reflected by the wiring layer 61, and to prevent generation of optical noise that is expected to be generated in a case where light leaks into the charge holding region 68.
Configuration of Light Shielding Part
As described above, providing the light shielding part 76, particularly the embedded part 76B between the PD 51 and the charge holding part 54b makes it possible to prevent the generation of optical noise that is expected to be generated in a case where light penetrates the PD 51 and leaks into the charge holding region 68.
Furthermore, forming the charge holding part 54b with the thickness equal to or less than half the thickness of the semiconductor substrate 63 makes it possible to prevent the generation of optical noise that is expected to be generated in a case where light is reflected by the wiring layer 61 and leaks into the charge holding region 68.
Meanwhile, the embedded part 76B provided between the PD 51 and the charge holding part 54b is provided, for example, as the light shielding part 76 that does not penetrate the semiconductor substrate 63 as shown in
Meanwhile, with reference to
Therefore, a configuration of the embedded part 76B to prevent the light reflected by the wiring layer 61 from leaking into the charge holding part 54b without hindering the transfer of a charge from the PD 51 to the charge holding part 54b will be described.
An OFD 121 is positioned at the lower right in the diagram. The OFD 121 represents a drain connected to a reset gate of the PD 51. The OFD 121 is connected to the PD 51 via an OFG gate 122.
The charge holding region 68b is disposed on an upper side of the PD 51. When the pixel 50b is viewed from below, a TRX gate 73b is disposed in a region where the charge holding region 68b (charge holding part 54b) is disposed. The TRX gate 73b is provided to control the transfer of a charge from the PD 51 to the charge holding part 54b.
A floating diffusion region 125 (FD 125) is disposed on a left side of the charge holding region 68b in the diagram via the TRX gate 73b. A TRG gate 124 is provided to transfer a charge from the charge holding part 54b to the floating diffusion region 125.
A light shielding part 76B-1 is formed in an upper portion of the charge holding region 68b (upper side in the diagram). Although both ends of this light shielding part 76B-1 are partially formed in a non-penetrating manner because a transistor or the like is disposed, basically, to prevent light leakage between pixels, the light shielding part 76B-1 is formed as a penetrating light shielding part penetrating the semiconductor substrate 63.
Similarly, a light shielding part 76B-3 is formed in a lower portion of the PD region 67 (lower side in the diagram), and a region where the transistor 123 and the like are disposed is formed in a non-penetrating manner, but basically, to prevent light leakage between pixels, the light shielding part 76B-3 is formed as a penetrating light shielding part penetrating the semiconductor substrate 63.
The penetrating light shielding part 76B-3 is a light shielding part provided between the pixels 50b and is the same as the penetrating light shielding part 76B-1 although denoted with a different reference symbol for convenience of description.
A light shielding part 76B-2 is formed in a boundary part between the charge holding region 68b and the PD 51. The light shielding part 76B-2 will be described later with reference to
Furthermore, a light shielding part 76B-4 disposed in a region where the transistor 123 on the left side in
Between the pixels 50b, light leaking between pixels is shielded by the penetrating light shielding part 76B except for a part where transistors are disposed and the like. Furthermore, light leaking from the PD 51 side to the charge holding part 54b is shielded and light reflected by the wiring layer 61 is also shielded by the light shielding part 76B that is penetrating except for some part between the PD region 67 (PD 51) and the charge holding region 68b (charge holding part 54b).
In other words, in the pixel 50b shown in
An exemplary cross-sectional configuration of the pixel 50b in the cross section of arrow A-B shown in
Moreover, the light shielding part 76B-2 disposed between the PD region 67 and the charge holding region 68b will be described with reference to
Out of a region from a position P3 to a position P5 where the PD 51 is disposed, the light shielding part 76B-2 disposed in a region from the position P3 to a position P4 is penetrating, and the light shielding part 76B-2 disposed in a region from the position P4 to the position P5 is non-penetrating.
In an example shown in
In
Thus, part of the light shielding part 76B-2 disposed between the PD region 67 and the charge holding region 68b is formed as a penetrating light shielding part penetrating the semiconductor substrate 63, and the light shielding part 76B-2 disposed in a region where a transistor or the like is disposed and a region for transferring a charge from the PD 51 to the charge holding part 54b is formed as a non-penetrating light shielding part that does not penetrate the semiconductor substrate 63.
It is possible to prevent the light reflected by the wiring layer 61 from leaking into the charge holding part 54b by making part of the light shielding part 76B-2 disposed between the PD region 67 and the charge holding region 68b a penetrating light shielding part.
Furthermore, since a part for transferring a charge from the PD 51 to the charge holding part 54b is a non-penetrating light shielding part, the transfer is not hindered. In other words, a region from the position P4 to the position P5 is a non-penetrating light shielding part, and the transfer can be performed from this aperture. For example, when a size from the position P3 of the end of the PD 51 to the position P5 of the end of the OFG gate 122 is 1, this aperture is required at least to be formed to have a size of 1/5 or more.
Furthermore, the light shielding part 76B-2 (non-penetrating light shielding part 76-2) formed in the part of the aperture is required at least to be formed, for example, at a depth as shown in
As shown in
Alternatively, as shown in
In a case where the non-penetrating light shielding part 76B-2 is provided to suppress PLS, P-type ion implantation that ensures holes in the non-penetrating light shielding part 76B-2 is required. For this reason, as shown in
Meanwhile, as shown in
Since the transfer characteristic is a trade-off with the number of saturated electrons, balance between suppression of PLS and the number of saturated electrons is considered, and the digging amount of the non-penetrating light shielding part 76B-2 is designed to obtain performance required for the pixel 50b.
Other Configurations of Pixel
Other configurations of the pixel 50 will be described.
Parts similar to parts of the pixel 50b shown in
As described with reference to
However, there is a possibility that the pixel 50c shown in
Moreover, as in a pixel 50d shown in
There is a possibility that the performance of suppressing PLS is lower in the configuration of the pixel 50d shown in
The light shielding part 76B-4 and the light shielding part 76B-5 that have been formed between the PD regions 67 are effective in suppressing color mixture that is generated if light leaks from one PD 51 into the other PD 51, but in terms of preventing light leakage from the PD 51 to the charge holding part 54b and light leakage from the wiring layer 61, the light shielding part 76B-4 and the light shielding part 76B-5 may be deleted. The light shielding part 76B-4 and the light shielding part 76B-5 that have been formed between the PD regions 67 can be formed as needed.
The light shielding part 76B-6 and the light shielding part 76B-7 formed between the charge holding regions 68b are non-penetrating light shielding parts because the TRX gate 73b is disposed and the TRG gate 124 is disposed.
Providing the light shielding part 76 also between the charge holding regions 68b makes it possible to prevent light leaking from the one charge holding region 68b to the other charge holding region 68b, and to suppress PLS more.
By disposing the charge holding region 68g-1 at a position shifted by a half pitch with respect to the PD region 67g-1, a TRG gate 124g-1 can be disposed in a central portion of the charge holding region 68g-1 (TRX gate 73g-1). The TRG gate 124g-1 disposed in a central portion of the charge holding region 68b-1 makes it possible to shorten a transfer length in the charge holding region 68b-1 and to improve transfer efficiency.
The configuration in which the light shielding parts 76B-4 and 76B-5 formed between the PDs 51 have been deleted is similar to the pixel 50e shown in
As in the pixel 50e shown in
The configuration in which the light shielding part 76B-6-1 (light shielding part 76B-6-2) and the light shielding part 76B-7-1 (light shielding part 76B-7-2) are added between the charge holding regions 68i is similar to the pixel 50f shown in
As in the pixel 50f shown in
The TRY gate 201j of the unit pixel 50j shown in
The TRY gate 201j is provided, the TRY gate 201j is turned on when transferring a charge from the PD 51 to a charge holding part 54j, and thereafter turned off such that the charge does not flow back to the PD 51, thereby preventing the charge from flowing back to the PD 51.
Furthermore, the TRY gate 201j has a memory function of accumulating a charge. The memory function of the TRY gate 201j may be provided in the charge holding region 68j, or may be provided separately from the charge holding region 68j.
In the pixel 50j having such a configuration, the TRY gate 201j functions as a gate when transferring a charge from the PD 51 to the charge holding part 54j, and also functions as a gate for preventing a charge from flowing back from the charge holding part 54j to the PD 51.
Furthermore, the TRX gate 201j functions as a gate when transferring a charge from the PD 51j to the charge holding part 54j, and also functions as a gate for causing the charge holding part 54j to hold a charge.
In the pixel 50k shown in
Thus, it is possible to have a configuration in which the TRX gate 73k-1 is positioned on the adjacent pixels 50k. In a case of such disposition, a charge from a PD 51k-1 is transferred to the TRX gate 73k-1 disposed on a left side of the TRY gate 201k-1 through the TRY gate 201k-1 disposed in an upper right portion.
In the pixel 50m shown in
In the pixel 50n shown in
Thus, the pixel 50 can also include the TRY gate 201.
Meanwhile, as described above, the non-penetrating light shielding part, for example, with reference to
Thus, a cross section of the pixel 50p when the TRX gate 73p is formed in a shape projecting to the PD 51 side is as shown in
Thus, in addition to covering the charge holding region 68, the TRX gate 73 may be formed in a shape to extend to the PD region 67 side. Furthermore, a part to extend may be a part where the light shielding part 76 is non-penetrating, in other words, the aperture opened for transfer of the charge holding part 54 from the PD 51.
Note that also in a case of the configuration of the pixel 50r shown in
Thus, forming the gate to project into the PD region 67 makes it possible to prevent the transfer efficiency from the PD 51 to the charge holding part 54 from being lowered.
About Disposition of Transistor
Thus, in the pixel 50 to which the present technology is applied, in the light shielding part 76B-2 formed between the PD region 67 and the charge holding region 68, a part in which the transistor is disposed and a part for transferring a charge from a PD part 51 to the charge holding part 54 are formed as non-penetrating light shielding parts, and other parts are formed as penetrating light shielding parts. For example, as the transistor 123, which is formed as a non-penetrating light shielding part, transistors as shown in
In a region of the transistor 123, a reset (RST) transistor 301, an amplification (AMP) transistor 302, and a selection (SEL) transistor 303 are disposed.
The reset transistor 301 is connected between a power source Vrst, not shown, and the FD 125, and resets the FD 125 by applying a drive signal RST to a gate electrode. The amplification transistor 302, in which a drain electrode is connected to a power source Vdd, not shown, and a gate electrode is connected to the FD 125 and reads a voltage of the FD 125.
The selection transistor 303, in which, for example, a drain electrode is connected to a source electrode of the amplification transistor 302 and a source electrode is connected to a vertical signal line, and a drive signal SEL is applied to a gate electrode to select the pixel 50 from which the pixel signal should be read. Note that it is possible to employ a configuration in which the selection transistor 303 is connected between the power source Vdd and the drain electrode of the amplification transistor 302.
Furthermore, it is also possible to employ a configuration in which a plurality of pixels 50 shares the transistor 123.
The reset transistor 301 is disposed across a part of the non-penetrating light shielding part of a light shielding part 76B-2-1 of a pixel 50b-1, and a part of the non-penetrating light shielding part of a light shielding part 76B-2-2 of a pixel 50b-2 between the pixel 50b-1 and the pixel 50b-2.
The amplification transistor 302 is disposed between the pixel 50b-1 and the pixel 50b-2. The selection transistor 303 is disposed between a pixel 50b-3 and a pixel 50b-4.
A dummy 331 may be disposed across a part of the non-penetrating light shielding part of a light shielding part 76B-2-3 of the pixel 50b-3, and a part of the non-penetrating light shielding part of a light shielding part 76B-2-4 of the pixel 50b-4 between the pixel 50b-3 and the pixel 50b-4. The dummy 331 is disposed when it is desired to ensure symmetry or the like. Furthermore, instead of the dummy 331, a transistor for switching conversion efficiency may be disposed.
Thus, an example shown in
Thus, the configuration in which a plurality of pixels shares the transistor 123 can enlarge a region allocated to one transistor. Enlarging the region allocated to one transistor allows a configuration in which a distance between a source and a drain of the transistor can be extended, and a configuration in which a leak can be prevented.
Furthermore, as shown in
Furthermore, the configuration in which the plurality of pixels shares the transistor 123 allows miniaturization.
About Disposition Position of On-Chip Lens
Next, a disposition position of the on-chip lens 66 will be described.
Each of
Furthermore, in
Furthermore, with reference to the pixel 50b shown in
In the pixel 50b shown in
Note that in
For example, the charge holding region 68 that is shielded is disposed next to the PD region 67, and the on-chip lens 66 may be formed in the charge holding region 68 as well. In other words, the on-chip lens 66 itself can be formed large.
In the pixel 50b shown in
In the pixel 50b shown in
Thus, by narrowing the opened region 401b to a region where light can be concentrated by the on-chip lens 66b, it can be assumed that the F-number sensitivity is slightly reduced, but since a useless PLS component can be cut, an influence by the PLS component can be suppressed more.
The on-chip lens 66c is disposed at a position as far as possible from a transfer part that transfers a charge from the PD 51 to the charge holding part 54, in other words, the light shielding part 76B-2 formed in a non-penetrating manner to perform the transfer, the position where the concentrated light diameter of the on-chip lens 66c fits in the opened region 401c. Thus, PLS can be improved by disposing the on-chip lens 66c at a position away from the non-penetrating light shielding part (transfer part).
In the pixel 50b shown in
Thus, by narrowing the opened region 401d to a region where light can be concentrated by the on-chip lens 66d, it can be assumed that the F-number sensitivity is slightly reduced, but since a useless PLS component can be cut, the influence by the PLS component can be suppressed more.
For example, as in the pixel 50b shown in
Therefore, as shown in
In
The example shown in
In a case where the pixels 50b are arranged in an array in this manner, respective pixels 50b are the same in that the opened region 401d is provided on a lower left side in the pixel 50b, and the on-chip lens 66d is formed in the opened region 401d. Accordingly, the example shown in
The example shown in
Accordingly, respective pixels 50b arranged in an array are the same in that the opened region 401d is provided on a lower left side in the pixel 50b, and that the on-chip lens 66d is formed in the opened region 401d. Accordingly, the example shown in
In a case where the pixels 50b are arranged in an array in this manner, the opened region 401d is provided, for example, on a lower left side in the pixel 50b-1, and an on-chip lens 66d-1 is formed in an opened region 401d-1. In the pixel 50b-3 adjacent to the pixel 50b-1 in the vertical direction, an opened region 401d-3 is provided on an upper left side, and an on-chip lens 66d-3 is formed in the opened region 401d-3.
In the example shown in
In a case where the pixels 50b are arranged in an array in this manner, the opened region 401d is provided, for example, on a lower right side in the pixel 50b-1, and the on-chip lens 66d-1 is formed in the opened region 401d-1. In the pixel 50b-2 adjacent to the pixel 50b-1 in the lateral direction, an opened region 401d-2 is provided on a lower left side, and an on-chip lens 66d-2 is formed in the opened region 401d-2.
In the example shown in
Exemplary disposition of the on-chip lens 66 shown in
Accordingly, the disposition of the on-chip lens 66 shown in
Furthermore, by increasing the region allocated to the PD 51 and the charge holding part 54, the number of saturated electrons (dynamic range) can be increased. However, as described above, since optical symmetry cannot be maintained and there is a possibility that sensitivity and spatial resolution decrease, those may be decreased in some product, and it is necessary to employ signal processing or the like that do not decrease them as appropriate in some cases.
About Manufacturing
Manufacturing of the pixel 50 described above will be described with reference to
First, in the pixel 50b shown in
In step S11, an SOI substrate is set. Here, a case where the SOI substrate is used and a charge accumulation layer is n-type will be described as an example, but the present technology can also be applied to a case where a bulk substrate is used and the charge accumulation layer is p-type, or the like.
Furthermore, in step S11, a well of a transistor is also formed by ion implantation. Furthermore, an etching stopper layer 501 is also formed.
In step S12, the PD 51 and the charge holding part 54b, which are n-type regions, are formed by ion implantation. In a case where a p-type region is produced in the charge holding region 68b, the p-type region is produced in step S12.
In step S13, the OFG gate 122 and the TRX gate 73 are formed. Gate portions of these transistors are formed, for example, by polysilicon deposition by CVD and patterning of lithography.
In step S14, a hole-accumulation diode (HAD) is formed by ion implantation. The HAD is formed by generating the p-type pinning layer 74-1 in the PD 51. Dark current can be significantly suppressed by forming the HAD.
In step S15, the OFD 121, which is an n-type region, is formed by ion implantation.
Moreover, in step S16, the wiring layer 61 is stacked.
In step S17 (
In step S19, a layer on a back side of the etching stopper layer 501 of the semiconductor substrate 63 is etched by wet etching. At this time, the etching stopper layer 501 is exposed by stopping the etching with the etching stopper layer 501 containing high-concentration p-type impurities.
Moreover, after the etching stopper layer 501 is removed, the back surface of the semiconductor substrate 63 is polished by a chemical mechanical polishing (CMP) method, whereby the back side of the semiconductor substrate 63 is thinned.
Thus, after the PD region 67 and the charge holding region 68 are formed, the light shielding part 76 is formed. In the description of the formation of the light shielding part 76, as shown in
As shown in step S20 (
In step S21, a portion corresponding to the light shielding part 76 to penetrate is dug a little. The light shielding part 76 to penetrate is the light shielding part 76B-3 positioned below the pixel 50b-1 and the light shielding part 76B-1 positioned above the pixel 50b-1 shown in
In step S22, the non-penetrating light shielding part 76 and the penetrating light shielding part 76 are dug. The penetrating light shielding part 76, which has already been dug a little, is further dug and becomes penetrating.
In step S23, the light shielding part 76 is formed by filling the dug part with a metal such as tungsten.
Note that in the digging, after a resist is first formed on the back surface of the semiconductor substrate 63, the resist layer is exposed and developed such that the aperture is formed in a region where the embedded part 76B of the light shielding part 76 is to be formed. Then, dry etching is performed using the resist layer as a mask to form a trench part. By repeating this process, the non-penetrating trench part and the penetrating trench part are formed.
Moreover, the high dielectric constant material film 77 is deposited on the side surface and bottom surface of the trench part and the back surface of the semiconductor substrate 63. Subsequently, the light shielding part 76 is deposited from the back side of the high dielectric constant material film 77 on the back surface and in the trench part 84.
With this process, the lid part 76A is formed on the back side of the high dielectric constant material film 77, and the light shielding part 76 in which the embedded part 76B is formed inside the trench part 84 is formed.
The light shielding part 76 is formed, for example, by performing chemical vapor deposition (CVD) using tungsten as a material. Then, the light shielding part 76 is processed by dry etching to open the aperture 76C. Thereafter, for example, an atomic layer deposition (ALD) method is used to stack and planarize the high dielectric constant material film 77 with respect to the light shielding part 76.
Thereafter, a normal method is used to form the color filter layer 65 and the on-chip lens 66. Thus, the pixel 50b is manufactured.
The present technology makes it possible to reduce the influence of unnecessary light components. Furthermore, it is possible to manufacture pixels that can reduce the influence of unnecessary light components.
Electronic Device
The present technology is not limited to application to an imaging apparatus, but is applicable to all electronic devices that use the imaging apparatus in an image fetching unit (photoelectric conversion part) including an imaging apparatus such as a digital still camera and a video camera, a mobile terminal device having an imaging function such as a mobile phone, and a copying machine that uses the imaging apparatus in an image reader, and the like. Note that a modular form to be mounted on an electronic device, in other words, a camera module is used as the imaging apparatus in some cases.
Then, a configuration is used in which the DSP circuit 603, the frame memory 604, the display device 605, the recording device 606, the operation system 607, and the power supply system 608 are interconnected via a bus line 609. A CPU 610 controls each unit in the imaging apparatus 600.
The lens group 601 takes in incident light (image light) from a subject and forms an image on an imaged surface of the imaging device 602. The imaging device 602 converts a light amount of the incident light with which an image is formed on the imaged surface by the lens group 601 into an electric signal in pixel unit and outputs the electric signal as a pixel signal. As this imaging device 602, the imaging device (image sensor) according to the above-described embodiment can be used.
The display device 605 includes a panel type display device such as a liquid crystal display device or an organic electro luminescence (EL) display device, and displays a moving image or a still image that is imaged by the imaging device 602. The recording device 606 records the moving image or the still image imaged by the imaging device 602 on a recording medium such as a video tape or a digital versatile disk (DVD).
The operation system 607 issues operation commands for various functions possessed by the imaging apparatus under an operation of a user. The power supply system 608 appropriately supplies various power sources that serve as operation power sources for the DSP circuit 603, the frame memory 604, the display device 605, the recording device 606, and the operation system 607 to these supply targets.
Such an imaging apparatus 600 is applied to a camera module for mobile devices such as a video camera, a digital still camera, and a mobile phone. Then, in this imaging apparatus 600, the imaging device according to the embodiment described above can be used as the imaging device 602.
In the present specification, the system represents an entire device including a plurality of devices.
Note that effects described in the present specification are merely illustrative and not restrictive, and other effects may be produced.
Note that the embodiment of the present technology is not limited to the embodiment described above, and various modifications may be made without departing from the spirit of the present technology.
Note that the present technology can also have the following configurations.
Number | Date | Country | Kind |
---|---|---|---|
2017-055309 | Mar 2017 | JP | national |
This application is a continuation of U.S. patent application Ser. No. 17/202,929, filed Mar. 16, 2021, which is a continuation of U.S. patent application Ser. No. 16/491,017, filed Sep. 4, 2019, now U.S. Pat. No. 10,991,753, which is a national stage application under 35 U.S.C. 371 and claims the benefit of PCT Application No. PCT/JP2018/009144 having an international filing date of Mar. 9, 2018, which designated the United States, which PCT application claimed the benefit of Japanese Patent Application No. 2017-055309 filed 22 Mar. 2017, the entire disclosures of each of which are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
10991753 | Kumagi et al. | Apr 2021 | B2 |
20120012965 | Maeda | Jan 2012 | A1 |
20130070131 | Ohkubo | Mar 2013 | A1 |
20140131779 | Takeda | May 2014 | A1 |
20140327051 | Ahn et al. | Nov 2014 | A1 |
20140346628 | Okazaki | Nov 2014 | A1 |
20150181187 | Wu et al. | Jun 2015 | A1 |
20160056199 | Kim et al. | Feb 2016 | A1 |
20160099268 | Minowa | Apr 2016 | A1 |
20160225815 | Um et al. | Aug 2016 | A1 |
20210202565 | Kumagi et al. | Jul 2021 | A1 |
Number | Date | Country |
---|---|---|
102208425 | Oct 2011 | CN |
110419107 | May 2023 | CN |
2007-227643 | Sep 2007 | JP |
2008-060198 | Mar 2008 | JP |
2008-091771 | Apr 2008 | JP |
2008-103647 | May 2008 | JP |
2013-065688 | Apr 2013 | JP |
2014-096490 | May 2014 | JP |
2014-229810 | Dec 2014 | JP |
2015-023259 | Feb 2015 | JP |
2015-061192 | Mar 2015 | JP |
2016181532 | Oct 2016 | JP |
20160085623 | Jul 2016 | KR |
20160088471 | Jul 2016 | KR |
WO 2016152512 | Sep 2016 | WO |
Entry |
---|
International Search Report and Written Opinion for International (PCT) Patent Application No. PCT/JP2018/009144, dated Jun. 5, 2018, 9 pages. |
Official Action for U.S. Appl. No. 16/491,017, dated Sep. 2, 2020, 14 pages. |
Notice of Allowance for U.S. Appl. No. 16/491,017, dated Sep. 2, 2020, 14 pages. |
Notice of Allowance for U.S. Appl. No. 17/202,929, dated Jan. 5, 2023, 9 pages. |
Corrected Notice of Allowance for U.S. Appl. No. 17/202,929, dated Mar. 15, 2023, 2 pages. |
Number | Date | Country | |
---|---|---|---|
20230261030 A1 | Aug 2023 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 17202929 | Mar 2021 | US |
Child | 18139778 | US | |
Parent | 16491017 | US | |
Child | 17202929 | US |