US20180226307A1

US20180226307A1 - SYSTEM AND METHOD FOR ELECTRICAL TESTING OF THROUGH SILICON VIAS (TSVs)

Info

Publication number: US20180226307A1
Application number: US15/943,076
Authority: US
Inventors: Alberto Pagani
Original assignee: STMicroelectronics SRL
Current assignee: STMicroelectronics SRL
Priority date: 2017-01-31
Filing date: 2018-04-02
Publication date: 2018-08-09
Also published as: CN108376653B; CN108376653A; CN207925459U; US9966318B1

Abstract

A substrate includes first and second semiconductor layers doped with opposite conductivity type in contact with each other at a PN junction to form a junction diode. At least one through silicon via structure, formed by a conductive region surrounded laterally by an insulating layer, extends completely through the first semiconductor layer and partially through the second semiconductor layer with a back end embedded in, and in physical and electrical contact with, the second semiconductor layer. A first electrical connection is made to the first through silicon via structure and a second electrical connection is made to the first semiconductor layer. A testing current is applied to and sensed at the first and second electrical connections in order to detect a defect in the at least one through silicon via structure.

Description

CROSS REFERENCE TO RELATED APPLICATION

This application is a divisional of U.S. application for patent Ser. No. 15/420,319 filed Jan. 31, 2017, the disclosure of which is incorporated by reference.

TECHNICAL FIELD

The present invention relates to a system and to a method for electrical testing of through silicon vias (TSVs).

BACKGROUND

FIG. 1 shows a schematic and simplified cross-sectional view of an electronic integrated circuit wafer 1 comprising: a substrate 3 made of semiconductor material, a first dielectric layer 4, a second dielectric layer 5 and a passivation dielectric layer 6. Integrated on and within the substrate 3 are electronic components (such as, for example, transistor devices 3 a ). Integrated within the first dielectric layer 4 are conductive contacts 4 a (for example, made source/drain/gate regions) and other structures (such as transistor gates 4 b ) surrounded by an insulating material. Integrated within the second dielectric layer 5 are metal interconnect lines 5 a and metal vias 5 b on a plurality of metallization levels (M1-Mn) that are surrounded by an insulating material, wherein the interconnect lines and vias are electrically connected to the contacts 4 a and other structures of the first dielectric layer 4. The passivation dielectric layer 6 includes contact pads 7 which are electrically connected to the interconnect lines and vias of the second dielectric layer 5. The top surface of the passivation dielectric layer 6 is the front face of the wafer 1. The bottom surface of the substrate 3 is the back face of the wafer 1.
It is common to utilize Through-Silicon Via or Through-Semiconductor Via (collectively “TSV”) technology in the fabrication of integrated circuits. A TSV is an interconnection of conductive material that extends vertically through the integrated circuit chip so as to enable electrical connection of elements of the circuit, integrated at various levels of the structure of the integrated circuit chip, with an external face (front and/or back) of the integrated circuit. The TSV is developed vertically through the integrated circuit chip (for example, through the substrate 3 and other included layers of the wafer 1 in such a way that, at the end of the manufacturing process, the TSV is accessible from the external face of the integrated circuit chip.
FIG. 1 shows a number of examples of the use of a TSV 9. Each TSV 9 forms a conductive interconnection that extends vertically through the substrate 3 and possibly traverses (fully or partially) one or more of the layers 4, 5 and 6. In particular, by way of example, FIG. 1 shows: a TSV 9 which extends through the layer 4 and partially through the substrate 3; a TSV 9 that extends at least partially through the layer 5, through the layer 4 and partially through the substrate 3; and a TSV 9 that extends through the layers 4 and 5 and partially through the substrate 3.
For example, the TSVs 9 may be obtained as described in United States Patent Application Publication No. 2005/0101054 (incorporated by reference), or as described in “Wafer Level 3-D ICs Process Technology”, by Chuan Seng Tan, Ronald J. Gutmann and L. Rafael Reif, pp. 85-95, Springer-Verlag New York Inc. (incorporated by reference).
In the overall fabrication process, the substrate 3 with electronic components and the first dielectric layer 4 are provided through appropriate fabrication processes designated by the acronym FEOL (Front End of Line). The second dielectric layer 5 and passivation dielectric layer 6, however, are provided through appropriate fabrication processes designated by the acronym BEOL (Back End of Line). The illustration in FIG. 1 is at an intermediate stage of fabrication before the wafer is diced into individual integrated circuit chips. Thus, after the BEOL, the manufacturing process may further include the wafer dicing operation.
FIG. 2 shows the wafer 1 at a subsequent stage in the manufacturing process. Here, a step of thinning the back surface of the substrate 3 (with known techniques of lapping, or “back grinding”) of the wafer 1 has been performed to expose a portion of the back end 9 b of each TSV 9. After completion of the thinning process, the substrate 3 has a reduced thickness in comparison to the intermediate stage of FIG. 1, for example a thickness of less than 100
In a next step of the manufacturing processes, the wafer 1 may be diced (for example, at the lines 10) so as to define a plurality of chips 12, each of which contains a respective electronic integrated circuit. Following dicing, the chips are packaged to form integrated circuit devices.
At the end of the manufacturing process, each TSV 9 will accordingly traverse through the entire thickness of the substrate 3 as shown in FIG. 2, providing for a direct electrical connection from the back side of the chip 12 to one or more of the included electronic components, the first dielectric layer 4, the second dielectric layer 5, and the contact pads 8. The use of TSV technology is particularly advantageous for providing three-dimensional packaging structures for the electronic integrated circuits (referred to in the art as “3D-packaging techniques” or 3D/2.5D integration techniques). In such structures, plural chips are stacked one on top of the other using the TSVs 9 to support electrical connections between the stacked chips as well as with the outside of the package.
In the light of the critical aspects of the production process, and given the nature of electrical interconnection performed by the TSVs 9, it would be advantageous to be able to verify proper TSV operation at a point of the manufacturing process preferably before performing dicing of the wafer 1. Such verification of proper TSV operation would include verification of the resistance of the path offered to the electric current circulating through the through TSVs and moreover the detection of possible leakages, defects and parasitic phenomena, for example, in regard to the substrate 3. Such TSV testing is, however, difficult at the stage of manufacturing shown in FIG. 1 because the back end 9 b of each TSV 9 is still contained within the body of the substrate 3 and thus is not directly available to be probed.
U.S. Pat. No. 9,111,895 (incorporated by reference) teaches a TSV testing structure and methodology that can be used at the stage of manufacturing shown in FIG. 1. With reference to FIG. 3, the substrate 3 is doped with a first conductivity type dopant (for example, P type). The TSV 9 has its back end 9 b embedded in the substrate 3. The TSV 9 is formed by a conductive region 16 (for example, made of a metal material such as copper) surrounded laterally by an insulating layer 18 (for example, made of an insulating material such as silicon oxide). A region 20 within the substrate 3 at the back end 9 b of the TSV 9 is doped with a second conductivity type dopant (for example, N type). The metal material of the TSV conductive region 16 is in direct physical and electrical contact with the region 20 but is isolated from the P-type substrate 3 by the combination of the lateral insulating layer 18 and underlying N-type region 20. The N-type region 20 forms with P-type substrate 3 a PN semiconductor junction (i.e., a junction diode 22) having an anode terminal provided by the substrate 3 and a cathode terminal provided by the region 20. Electrical connection to the anode terminal is made through an electrical contact 24 made to the substrate 3 while electrical connection to the cathode terminal is made through an electrical contact 26 made to the conductive region 16 of the TSV 9. The electrical contacts 24 and 26 may be implemented, for example, using electrically conductive structures (contacts, lines, vias) present within the layers 4 and 5 as well as the pads 7 in the layer 6.
In use, the presence of the junction diode 22 at the back end 9 b of the TSV 9, accessible through the electrical contacts 24 and 26 and their associated pads 7 in the layer 6, enables the electrical testing of the TSV 9 to be carried out. For example, in a test procedure a test current is circulated for application to the junction diode 22 and the test current (or corresponding voltage) is measured. More specificly, in one testing implementation the junction diode 22 is forward biased so as to enable the passage of the test current through the conductive region 16 of the TSV 9. It is thus possible to evaluate, using a test apparatus coupled to the associated pads 7, the resistance offered by TSV 9 under test to the passage of the test current. In particular, it is possible to measure a resistance of a differential type causing the test current to assume two distinct values and thus measure two corresponding differences of potential. The measured differences of potential can be evaluated to determine a fault of the TSV 9 under test. Chips with fauty TSVs 9 can be identified and then discarded following the thinning of the substrate 3 and subsequent dicing operations.
FIG. 4 shows a schematic and simplified view of the testing apparatus for performing a wafer-level testing of electrical characteristics. The wafer 1 is mounted to a chuck 30. A probe head 32 is arranged with a plurality of probes 34 can be actuated so as to approach the front face of the wafer 1 and cause the plurality of probes 34 to be placed into physical and electrical contact with the pads 7 of the wafer 1. The probe head 32 is mounted to a support 36 (for example, a printed circuit board). The probe head 32, probes 34 and support 36 form a device known to those skilled in the wafer test art as a probe card 38. FIG. 3 illustrates the physical and electrical contacting of the probes 34 with the pads 7 of the wafer 1. It is through the probes that the test current is applied and the potential measurements are made under the direction and control of connected Automated Test Equipement (ATE). As known in the art, ATE is configured to perform automatic procedures for testing and electrical sorting the various chips within the wafer 1 (before the corresponding dicing operation is performed) so as to select the chips that are operating properly for their subsequent packaging. This operation is known as “Electrical Wafer Sort” (EWS) or “Wafer Sort” (WS) and envisages execution of appropriate electrical tests on the electronic integrated circuits, and in this case the TSVs 9, in the various chips.
Although FIG. 3 illustrates a preferred implementation where the probes 34 make physical and electrical contact with the pads 7, it will be understood that in alternative implementations the probe 34 may alternatively make physical and electrical contact directly with the front end 9 a of the TSVs 9. This can be accomplished, for example, in situations where the TSVs extend up to layer 6 (and are exposed through the layer 6) or in situations where testing is performed prior to BEOL processing and the formation of layers 5 and 6.
Details of possible testing scenarios, as well as other related TSV testing structures, are provided in U.S. Pat. No. 9,111,895 and will not be repeated here.

SUMMARY

In an embodiment, an apparatus comprises: a semiconductor substrate including a first semiconductor layer of a first conductivity type and a second semiconductor layer of a second conductivity type opposite the first conductivity type, said first and second semiconductor layers in contact with each other at a PN junction to form a junction diode; a first through silicon via structure comprising a conductive region surrounded laterally by an insulating layer, said first through silicon via structure extending completely through the first semiconductor layer and partially through the second semiconductor layer with a back end of the first through silicon via structure embedded in the second semiconductor layer with the conductive region in physical and electrical contact with second conductivity type doped semiconductor material of the second semiconductor layer; a first electrical connection made to a front end of the first through silicon via structure; and a second electrical connection made to first conductivity type doped semiconductor material of the first semiconductor layer.
In an embodiment, a method is presented for testing a wafer including a semiconductor substrate comprising a first semiconductor layer of a first conductivity type and a second semiconductor layer of a second conductivity type opposite the first conductivity type, said first and second semiconductor layers in contact with each other at a PN junction to form a junction diode, said wafer further including a first through silicon via structure comprising a conductive region surrounded laterally by an insulating layer, said first through silicon via structure extending completely through the first semiconductor layer and partially through the second semiconductor layer with a back end of the first through silicon via structure embedded in the second semiconductor layer with the conductive region in physical and electrical contact with second conductivity type doped semiconductor material of the second semiconductor layer.
The method for testing comprises: generating a testing current applied to flow through the first through silicon via structure; and sensing said testing current at the first semiconductor layer in order to detect a fault in the first through silicon via structure. The method for testing further comprises: generating a testing current applied to flow through the first through silicon via structure; and sensing said testing current at the first semiconductor layer in order to confirm correct operation of said first through silicon via structure.
In an embodiment, a method is presented for testing a wafer including a semiconductor substrate comprising a first semiconductor layer of a first conductivity type and a second semiconductor layer of a second conductivity type opposite the first conductivity type, said first and second semiconductor layers in contact with each other at a PN junction to form a junction diode, said wafer further including a first and second through silicon via structures each comprising a conductive region surrounded laterally by an insulating layer, said first and second through silicon via structures extending completely through the first semiconductor layer and partially through the second semiconductor layer with a back end of the first and second through silicon via structures embedded in the second semiconductor layer with the conductive region in physical and electrical contact with second conductivity type doped semiconductor material of the second semiconductor layer.
The method for testing comprises: generating a testing current applied to flow through the first through silicon via structure; and sensing said testing current at the second through silicon via structure in order to confirm correct operation of said first and second through silicon via structures.
The method for testing comprises: generating a testing current applied to flow through the first through silicon via structure; and sensing an absence of said testing current at the second through silicon via structure in order to detect a fault in at least one of the first and second through silicon via structures.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the present invention, preferred embodiments thereof are now described, purely by way of non-limiting example and with reference to the attached drawings, wherein:

FIG. 1 is a schematic cross-section of a wafer of semiconductor material, in which through vias are provided, at an intermediate stage of a manufacturing process;

FIG. 2 is a schematic cross-section of the wafer of FIG. 1 at an end stage of the manufacturing process;

FIG. 3 illustrates a TSV testing structure and methodology as taught by U.S. Pat. No. 9,111,895;

FIG. 4 is a schematic illustration of part of a testing apparatus for electrical testing of a wafer of semiconductor material;

FIG. 5 is a schematic cross-section of a wafer of semiconductor material, in which through vias are provided, at an intermediate stage of a manufacturing process;

FIG. 6 illustrates an improved TSV testing structure and methodology using the wafer of FIG. 5; and

FIGS. 7A-7E illustrate testing scenarios using the improved TSV testing structure and methodology of FIG. 6.

DETAILED DESCRIPTION

FIG. 5 shows a schematic and simplified cross-sectional view of an electronic integrated circuit wafer 1′ comprising: a substrate 3′ of semiconductor material, a first dielectric layer 4, a second dielectric layer 5 and a passivation dielectric layer 6. The substrate 3′ comprises a first layer 3 n of semiconductor material doped with a first conductivity type dopant (for example, N type) and a second layer 3 p of semiconductor material doped with a second conductivity type dopant (for example, P type). The formation of a substrate 3′ having opposite conductivity type doped layers 3 n and 3 p in contact with each other as shown may be accomplished using a number of different techniques, known to those skilled in the art, including dopant implantation with diffusion or epitaxial growth with insitu doping or subsequent implantation and diffusion. Although layers 3 n and 3 p are shown in the example of FIG. 5 as being doped n-type and p-type, respectively, it will be understood that the layers could alternatively be doped p-type and n-type, respectively. Still further, the layer 3 p could be implemented in an embodiment as a doped well structure contained within the layer 3 n.
Integrated on and within the substrate layer 3 p are electronic components (such as, for example, transistor devices 3 a ). Integrated within the first dielectric layer 4 are contacts 4 a (for example, made source/drain/gate regions) and other structures (such as transistor gates 4 b ) surrounded by an insulating material. Integrated within the second dielectric layer 5 are interconnect lines 5 a and vias 5 b on a plurality of metallization levels (M1-Mn) that are surrounded by an insulating material, wherein the interconnect lines and vias are electrically connected to the contacts 4 a and other structures of the first dielectric layer 4. The passivation dielectric layer 6 includes contact pads 7 which are electrically connected to the interconnect lines and vias of the second dielectric layer 5. The top surface of the passivation dielectric layer 6 is the front face of the wafer 1′. The bottom surface of the substrate 3 is the back face of the wafer 1′.
Through-Silicon Via or Through-Semiconductor Via (collectively “TSV”) technology is further used to form an interconnection of conductive material that extends vertically through the integrated circuit chip so as to enable electrical connection of elements of the circuit, integrated at various levels of the structure of the integrated circuit chip, with an external face (front and/or back) of the integrated circuit. The TSV is developed vertically through the integrated circuit chip (for example, through the substrate substrate 3′ and other included layers of the wafer 1′ in such a way that, at the end of the manufacturing process the TSV is accessible from the external face of the integrated circuit chip.
FIG. 5 shows a number of examples of the use of a TSV 9. Each TSV 9 forms a conductive interconnection that extends vertically through the substrate 3′ and possibly traverses (fully or partially) one or more of the layers 4, 5 and 6. In particular, by way of example, FIG. 1 shows: a TSV 9 which extends through the first dielectric layer 4 and partially through the substrate 3′ (for example, completely through layer 3 p and partially through layer 3 n ); a TSV 9 that extends at least partially through the second dielectric layer 5, through the first dielectric layer 4 and partially through the substrate 3′ (for example, completely through layer 3 p and partially through layer 3 n ); and a TSV 9 that extends through the first and second dielectric layers 4 and 5 and partially through the substrate 3′ (for example, completely through layer 3 p and partially through layer 3 n ).
In the overall fabrication process, the substrate 3′ with electronic components and the first dielectric layer 4 are provided through appropriate processes designated by the acronym FEOL (Front End of Line). The second dielectric layer 5 and passivation dielectric layer 6, however, are provided through appropriate processes designated by the acronym BEOL (Back End of Line). The illustration in FIG. 5 is at an intermediate stage of fabrication before subsequent substrate 3′ thinning (compare to FIG. 2) and before the wafer 1′ is diced into individual integrated circuit chips. Thus, after the BEOL, the manufacturing process may further include the substrate thinning and wafer dicing operations.
Reference is now made to FIG. 6 which illustrates an improved TSV testing structure and methodology that can be used at the stage of manufacturing shown in FIG. 5. With reference to FIG. 6, each TSV 9 passes completely through the layer 3 p of the substrate 3′ and has its back end 9 b embedded in the layer 3 n of the substrate 3′. Each TSV 9 is formed by a conductive region 16 (for example, made of a metal material such as copper) surrounded laterally by an insulating/dielectric layer 18 (for example, made of an insulating material such as silicon oxide). In this configuration, distinct from the prior art implementation of FIG. 3, the conductive region 16 of the TSV 9 is in direct physical and electrical contact with the n-type doped semiconductor material of the substrate layer 3 n. The layer 3 p forms with layer 3 n of the substrate 3′ a PN semiconductor junction (i.e., a junction diode 22′) having an anode terminal formed by the substrate layer 3 p and a cathode terminal formed by the substrate layer 3 n. Electrical connection to the anode terminal is made through an electrical contact 24 made to the substrate layer 3 p while electrical connection to the cathode terminal is made through an electrical contact 26 made to the conductive region 16 of the TSV 9. The electrical contacts 24 and 26 may be implemented, for example, using electrically conductive structures (contacts, vias, lines) present within the layers 5 and 6 as well as the pads 7 in the layer 6.
In use, the presence of the junction diode 22′ formed by the PN junction of layer 3 p /3 n, accessible through the electrical contacts 24 and 26 and their associated pads 7 in the layer 6, enables the electrical testing of the included TSVs 9 to be carried out. In a test procedure using the testing apparatus of FIG. 3, for example, a current 50 is applied by the ATE and probe card 38 to node A at a selected one of the included TSVs 9 and first sensed at node B associated with the anode of the junction diode 22′. If no current is detected by the ATE at node B as shown in a simplified example with FIG. 7A (or if only a very small reverse bias leakage current is detected at node B), then it can be concluded that the TSV 9 at node B, as well as other TSVs electrically coupled to the substrate layer 3 n, is properly laterally insulated from the substrate layer 3 p by the insulating/dielectric layer 18. Conversely, if current 50 is detected at node B as shown in a simplified example with FIG. 7B, this indicates a failure (reference 60) of the lateral isolation (formed by insulating layer 18) of one or more of the TSVs electrically coupled to the substrate layer 3 n. Then, sensing by the ATE is further performed at node C at another of the included TSVs 9. If the current 50 applied to node A is detected by the ATE at the node C as shown in a simplified example with FIG. 7C, then it can be concluded that the TSVs associated with nodes A and C are properly conducting current flow. Conversely, if the current 50 applied to node A is not detected by the ATE at node C, this indicates a fault (reference 62) due to a defect in the construction of at least one of the TSVs 9 (for example, due to interruption of the conductive region 16 of the TSV 9, as shown in a simplified example with FIG. 7D, or presence on an insulating film at the back end 9 b of the TSV 9, as shown in a simplified example with FIG. 7E). Chips with fauty TSVs 9 can be identified and then discarded following the thinning of the substrate 3 and subsequent dicing operations.
In order to provide some control over which TSVs 9 are grouped together for testing, trench isolation structures 40 may be formed in the substrate 3′. The trench isolation structures 40 extend through the substrate layer 3 p and eventually at least partially into the substrate layer 3 n. The trench isolation structures 40 delimit a region of the substrate layer 3 p and thus define a set of TSVs which are subject to a common testing. This set of TSVs may be a subset of the TSVs integrated in the chip 12, or all TSVs of the chip 12, or TSVs belonging to a plurality of chips 12 of the wafer. Alternatively, the trench isolation structures 40 may be omitted. In other embodiments, trench isolation structures may be provided for other reasons unrelated to the TSV testing disclosed herein.
The method of forming the TSVs 9 may, for example, comprise a masking of the substrate 3′ followed by an anisotropic etch to forming an opening extending through the layer 3 p and partially into the layer 3 n. Then, the side wall and bottom of the opening is lined by an insulating layer (for example, using a conformal dielectric deposition or a thermal oxidation). An anisotropic etch is then performed to remove the insulating layer at the bottom of the opening. A barrier layer (for example, TiN) may be deposited in the opening and the opening is then subsequently filled with a conductive material, for example using a damascene and polishing operation or other known techniques.
This method for electrical testing of TSVs 9 can be applied to a 3D chip 12 as shown in FIG. 5 that comprises active integrated electronic components such as transistor devices 3 a or it can be applied to a 2. 5 D chip 12 as shown in FIG. 6, also called interposer or silicon interposer, that does not include active integrated electronic components in layer 3 p. Considering a 3D chip 12, this method for electrical testing of TSVs 9 can be applied using a BIST (Built-In Self Test) circuit embedded in the 3D chip 12 (for example using circuitry like the transistor devices 3 a in layer 3 p connected as needed to the TSVs and layer 3 p ) as shown in FIG. 5, or without any BIST circuit, using only the ATE that is linked or connected to the 3D chip 12 from the outside as shown in FIG. 6. With respect to considering a 2.5D chip 12, this testing method is applied by an ATE because active integrated electronic components are, in general, absent in the interposer.
Moreover, this method for electrical testing of TSVs 9, can be applied to any other through via in any semiconductor substrate, and thus it is not limited to silicon substrates.
The foregoing description has provided by way of exemplary and non-limiting examples providing a full and informative description of the exemplary embodiment of this invention. However, various modifications and adaptations may become apparent to those skilled in the relevant arts in view of the foregoing description, when read in conjunction with the accompanying drawings and the appended claims. However, all such and similar modifications of the teachings of this invention will still fall within the scope of this invention as defined in the appended claims.

Claims

1. A method for testing a wafer including a semiconductor substrate comprising a first semiconductor layer of a first conductivity type and a second semiconductor layer of a second conductivity type opposite the first conductivity type, said first and second semiconductor layers in contact with each other at a PN junction to form a junction diode, said wafer further including a first through silicon via structure comprising a conductive region surrounded laterally by an insulating layer, said first through silicon via structure extending completely through the first semiconductor layer and partially through the second semiconductor layer with a back end of the first through silicon via structure embedded in the second semiconductor layer with the conductive region in physical and electrical contact with the second semiconductor layer, the method for testing comprising:

generating a testing current applied to flow through the first through silicon via structure; and

sensing said testing current at the first semiconductor layer in order to detect a fault in the first through silicon via structure.

2. The method of claim 1, wherein said fault is a defect in the insulating layer laterally surrounding the conductive region of the first through silicon via structure.

3. The method of claim 1, wherein the method for testing further comprises sensing an absence of said testing current at the first semiconductor layer in order to confirm correct operation of said first through silicon via structure.

4. The method of claim 1, wherein the wafer further comprises a second through silicon via structure comprising a conductive region surrounded laterally by an insulating layer, said second through silicon via structure extending completely through the first semiconductor layer and partially through the second semiconductor layer with a back end of the second through silicon via structure embedded in the second semiconductor layer with the conductive region in physical and electrical contact with the second semiconductor layer, the method for testing further comprising:

sensing an absence of said testing current at the second through silicon via structure in order to detect a fault in at least one of the first and second through silicon via structures.

5. The method of claim 4, wherein said fault is a discontinuity of the conductive region of at least one of the first and second through silicon via structures.

6. The method of claim 4, wherein said fault is an extension of the insulating layer laterally surrounding the conductive region to insulating said conductive region of at least one of the first and second through silicon via structures from the second semiconductor layer.

7. The method of claim 1, wherein the wafer further comprises a second through silicon via structure comprising a conductive region surrounded laterally by an insulating layer, said second through silicon via structure extending completely through the first semiconductor layer and partially through the second semiconductor layer with a back end of the second through silicon via structure embedded in the second semiconductor layer with the conductive region in physical and electrical contact with the second semiconductor layer, the method for testing further comprising:

sensing said testing current at the second through silicon via structure in order to confirm correct operation of said first and second through silicon via structures.

8. A method for testing a through silicon via, wherein the through silicon via comprises a conductive region surrounded laterally by an insulating layer, said through silicon via extending completely through a first semiconductor layer doped with a first conductivity type and partially through a second semiconductor layer doped with a second conductivity type, wherein a back end of the conductive region is in physical and electrical contact with the second semiconductor layer, the method comprising:

generating a testing current that is applied to the conductive region to flow into the second semiconductor layer; and

sensing said testing current flowing in the first semiconductor layer in order to detect a fault in the through silicon via.

9. A method for testing a through silicon via, wherein the through silicon via comprises a conductive region surrounded laterally by an insulating layer, said through silicon via extending completely through a first semiconductor layer doped with a first conductivity type and partially through a second semiconductor layer doped with a second conductivity type, wherein a back end of the conductive region is in physical and electrical contact with the second semiconductor layer, the method comprising:

sensing an absense of said testing current flowing in the first semiconductor layer in order to confirm correct operation of the through silicon via.

10. A method for testing through silicon vias, wherein a first through silicon via comprises a first conductive region surrounded laterally by a first insulating layer and a second through silicon via comprises a second conductive region surrounded laterally by a second insulating layer, said first and second through silicon vias extending completely through a first semiconductor layer doped with a first conductivity type and partially through a second semiconductor layer doped with a second conductivity type, wherein a back end of each of the first and second conductive regions is in physical and electrical contact with the second semiconductor layer, the method comprising:

generating a testing current that is applied to the first conductive region to flow into the second semiconductor layer; and

sensing said testing current flowing in the second conductive region in order to detect a fault in at least one of the first and second through silicon vias.

11. A method for testing through silicon vias, wherein a first through silicon via comprises a first conductive region surrounded laterally by a first insulating layer and a second through silicon via comprises a second conductive region surrounded laterally by a second insulating layer, said first and second through silicon vias extending completely through a first semiconductor layer doped with a first conductivity type and partially through a second semiconductor layer doped with a second conductivity type, wherein a back end of each of the first and second conductive regions is in physical and electrical contact with the second semiconductor layer, the method comprising::

sensing said testing current flowing in the second conductive region in order to confirm correct operation of the first and second through silicon vias.