EP1520297A2

EP1520297A2 - Integrated strip conductor arrangement

Info

Publication number: EP1520297A2
Application number: EP03749895A
Authority: EP
Inventors: Rudolf Strasser
Original assignee: Infineon Technologies AG
Current assignee: Infineon Technologies AG
Priority date: 2002-05-08
Filing date: 2003-03-19
Publication date: 2005-04-06
Also published as: CN100420016C; WO2003096419A3; CN1698201A; US7550854B2; WO2003096419A2; DE10220653A1; US20060202338A1

Abstract

The invention relates to an integrated strip conductor arrangement (12) consisting of several strip conductors (LB1 - LB3) crossing over each other at two overcrossing sections (20, 24), thereby ensuring an even flow of current in all three strip conductors, even at high frequencies.

Description

description

Integrated trace arrangement

The invention relates to an integrated interconnect arrangement. The conductor track arrangement connects, for example, components of an integrated circuit arrangement or is itself part of an integrated component.

Individual components cannot be separated mechanically from one another without destroying the components from an integrated arrangement. The three main types of integrated circuit arrangements are: monolithic circuit arrangements in which components are also arranged in a semiconductor that serves as a carrier.

Layer or film circuits using thin films on an insulating support. A distinction is made between thin-film and thick-film circuits. - Hybrid circuits, which are a combination of the aforementioned circuit types.

The manufacturing techniques for integrated arrangements include Layer application methods and layer structuring methods used. Examples of layer application methods are: screen printing in the case of thick-layer technology, or sputtering in the case of monolithic circuit arrangements and thin-layer circuits, the CVD method (Chemical Vapor Deposition) or the PVD method (Physical Vapor Deposition).

Layer structuring processes are, for example: - lithographic processes, or - etching processes. The conductor track of a conductor track arrangement has an electrical resistance of less than 10 ^"4 ohms per centimeter for direct current. The conductor tracks are usually made of aluminum, an aluminum alloy, copper or a copper alloy. These materials ensure that the conductor tracks have the lowest possible ohmic losses and eddy current losses and generate other power losses.

It is an object of the invention to provide a simply constructed, integrated conductor track arrangement which, in particular, has low power losses even at voltages or currents with a high frequency. Associated uses should also be specified.

The problem related to the conductor arrangement is achieved by the conductor arrangement specified in claim 1. Further developments are specified in the subclaims.

The invention is based on the consideration that, with increasing frequency in integrated interconnect arrangements, it becomes increasingly difficult due to electrodynamic phenomena to produce low-resistance connection arrangements or connection arrangements which cause low power losses.

The two main electrodynamic phenomena are the skin effect and the proximity effect. If alternating current flows through a conductor, an alternating magnetic field also occurs, which induces a counter voltage in the conductor that is greatest in the middle of the conductor. Because of this counter voltage, the current is distributed unevenly over the conductor. The current density increases from the center of the conductor to the edge. This phenomenon is called current displacement or skin or skin effect. Due to the current displacement, the conductor cross-section is only partially used by the alternating current. The reduction in the effective conductor cross section increases the effective resistance of the conductor. If currents of the same or opposite direction flow in adjacent conductors, in addition to the skin effect, a current displacement to the edge of the conductor arrangement or to the center of the conductor arrangement occurs due to the change in the magnetic fields. This increases the high-frequency resistance of the conductors in question again.

In addition, the invention is based on the consideration that the depth of penetration of the current into the conductor, for example for copper, is greater than two micrometers below a frequency of one gigahertz. This means that the structures mentioned so far, with structure widths of about two micrometers or smaller, have no significant influence on performance losses. However, if signals in the frequency range from one gigahertz to 50 gigahertz, for example, are to be transmitted, a considerable increase in the line resistance due to the current displacement mechanisms can be determined even with structure dimensions of less than two micrometers.

A simple parallel connection of conductor tracks, which also run spatially parallel, does not reduce the power losses because the middle conductor tracks of the conductor track arrangement cannot contribute to the current flow due to the current displacement mechanisms mentioned. As already explained, the current only flows in the outer conductor tracks.

The conductor track arrangement according to the invention therefore contains at least three electrically connected conductor tracks. An electrical insulating material is arranged between the conductor tracks. In addition, the conductor track arrangement contains at least two crossover sections arranged at different points on the longitudinal axis of the conductor track arrangement, at which conductor tracks of the conductor track arrangement cross. By crossing them several times, the conductor tracks of the conductor track arrangement can be twisted or twisted, for example, by all of the conductor tracks around the longitudinal axis of the conductor track arrangement, in the manner of interweaving, in which the conductor tracks progressively alternate over another conductor track in the direction of the longitudinal axis of the conductor track arrangement and are arranged under another conductor track, or arrange in the manner of a weave. Due to the crossovers, the conductor tracks assume different positions within the conductor track arrangement. The multiple crossing leads to the fact that each conductor track contributes to the current flow even at very high frequencies. The multiple crossings reduce the power losses, in particular the ohmic losses.

In a development of the conductor track arrangement according to the invention, the conductor tracks of the conductor track arrangement are lined up in one plane outside the crossover sections transversely to the longitudinal direction of the conductor track arrangement. Conductor tracks arranged in this way can be produced in a simple manner using the two-dimensional structuring methods of integrated technology that are usually used. In this way, the conductor tracks can be arranged next to one another in a metallization layer or also one above the other in different metallization layers.

In a next development, the conductor tracks are arranged in a metallization layer between adjacent crossover sections. The metallization layer is parallel to the main surface of a semiconductor substrate on which integrated components are located. The conductor tracks lying in a metallization layer are generated simultaneously, i.e. with the same separation and structuring processes.

In a further development of the conductor track arrangement with conductor tracks in a metallization layer, a conductor track is transverse to all other conductor tracks at the crossover sections. NEN the conductor arrangement arranged. The transverse conductor track or the other conductor tracks are arranged in a different metallization layer. This enables a crossover section to be produced with only two metallization layers. If the transverse conductor track lies in the additional metallization layer, only two additional contact holes are required. Because contacting in the area of the contact holes leads to additional resistance, the total resistance increases only insignificantly with only two contact holes per crossover section.

In another development, the other conductor tracks lie on or within the crossover sections in a different direction than outside the crossover sections. For example, the longitudinal direction of the conductor track at the crossover section initially changes by a certain amount in a certain direction. At the other end of the crossover section, the direction of the longitudinal axis of the conductor track changes again, the direction of the change in direction here being opposite to the first change in direction and the

The amount of change of direction remains the same. This measure ensures that the conductor track is offset in the crossover section. The offset creates space which is used by the conductor track which runs in the crossover section at right angles to the other conductor tracks. Overall, this arrangement determines the width of the conductor track arrangement only by the width of the conductor tracks and the width of the insulation between the conductor tracks. However, the other conductor tracks on the crossover section can also be arranged in a different way.

In an alternative development, the conductor tracks are arranged outside the crossover sections in different metallization layers. For example, the conductor tracks lie one above the other in the normal direction to a main surface of a semiconductor substrate of the integrated circuit arrangement. This measure makes it possible to Arrange NEN with a small footprint with respect to the surface of the semiconductor substrate. In addition, good capacitive decoupling can be achieved between the conductor tracks of the conductor track arrangement.

In a further development with conductor tracks in different metallization layers, a conductor track is arranged at the crossover sections in a contact hole transverse to all other conductor tracks. The contact hole preferably leads to a further metallization layer.

In a further development with the conductor track guided transversely to the other conductor tracks, the conductor tracks of the conductor track arrangement in the crossover sections are each led from one metallization layer into an adjacent metallization layer, for example uniformly into the one closer to the substrate or into the one further away from the substrate Metallization layer lying on the substrate.

In another development, the conductor track arrangement contains exactly two crossover sections. The number of contact holes within the conductor track arrangement can thereby be reduced. The manufacturing process is simplified and the power losses decrease.

In one embodiment, the two crossover sections are arranged at one third of the length of the conductor track arrangement and at two thirds of the length of the conductor track arrangement. This measure makes it possible for the current flow to be independent of the frequency, i.e. especially at very high frequencies, e.g. between one gigahertz and 50 gigahertz or higher, is evenly distributed on the conductor tracks.

In a next development of the integrated conductor track arrangement, all crossover sections have essentially the same structure. Alternatively or cumulatively, too the sections of the interconnect arrangement lying outside the crossover sections have identical spatial structures to one another. This measure simplifies the manufacturing process of the circuit arrangement because, for example, only mask patterns have to be defined for a crossover section. The same patterns are then used for all crossover sections.

In another development, each conductor track is arranged the same length between other conductor tracks. Alternatively or cumulatively, each conductor track is arranged the same length on the edge of the conductor track arrangement. These measures ensure that the current is evenly distributed over all conductor tracks even at frequencies in the gigahertz range.

In another development, the largest lateral dimension of a conductor track transverse to the longitudinal direction of the conductor track arrangement is less than ten micrometers or less than five micrometers. The length of the conductor track arrangement is alternatively or cumulatively less than ten millimeters or less than one millimeter. The area of application of the circuit arrangement is therefore not only in the thick-film area, in which thicknesses greater than 50 micrometers to about 1 millimeter are typically used, but also in the area of monolithic circuits and thin-film technology.

The invention also relates to the use of the conductor track arrangement as a coil and as a signal guide to an antenna of a transmitting part or from an antenna of a receiving part. The use as a coil offers the advantage that the quality of the coil and thus also the quality of an oscillating circuit containing the coil becomes very high even at frequencies in the gigahertz range. The use of the conductor track arrangement as part of the signal routing to an antenna or from an antenna now enables feeds which were previously carried out discretely into the circuit arrangement integrate. The highest frequencies of the circuit arrangement occur particularly in the area of the antenna, for example frequencies in the gigahertz range.

Further developments of the invention are explained below with reference to the accompanying drawings. In it show:

FIG. 1 shows a plan view of an integrated line, the conductor tracks of which are arranged outside of crossover sections in a metallization layer,

FIG. 2 shows a cross section through the integrated line of FIG. 1,

FIG. 3 shows a top view of an integrated line, the conductor tracks of which are arranged outside of crossover sections in three metallization layers, and

FIG. 4 shows a cross section through the integrated line of FIG. 3.

FIG. 1 shows a top view of an integrated circuit arrangement 10 which contains an integrated line 12. The integrated line 12 contains three conductor tracks LB1 to LB3, which are electrically connected in parallel in connection sections 14 and 16. An end section 18, a crossover section 20, a middle section 22, a crossover section 24 and an end section 26 lie between the connection sections 14 and 16 in the following order. In the end sections 18 and 26 and in the middle section 22, the conductor tracks LB1 to LB3 are parallel to one another an upper metallization layer 50, see also FIG. 2.

The crossover section 20 contains contact hole regions 28 and 30, at the bottom of which a section 32 of the conductor track LB1 ends. Section 32 is at right angles to a longitudinal axis 34 of line 12 below the conductor tracks LB2 and LB3 in a lower metallization layer 54, see also FIG. 2. At their other end, the contact hole regions 28 and 30 adjoin sections of the conductor track LB1 lying in the metallization layer 50, the sections of the conductor track LB1 starting from the end section 18 and Taper from the central section 22 to the contact hole areas 28 and 30 in the crossover area.

While the longitudinal direction of the conductor tracks LB1 to LB3 in the end sections 18, 26 and in the middle section 22 corresponds to the direction of the longitudinal axis 34, the conductor tracks LB2 and LB3 in the crossover section 20 are arranged obliquely to the longitudinal axis 34 at an angle between 20 and 60 degrees, for example of 30 degrees. The angle is dimensioned such that, seen over the length of the crossover section 20, there is exactly an offset of the conductor track LB2 or the conductor track LB3 from the width of a conductor track plus a distance A between adjacent conductor tracks. Because of the offset, the conductor track LB1 in the middle section 22 can assume the position that the conductor track LB3 has in the end section 18.

The crossover section 24 is structured in exactly the same way as the crossover section 20. In the crossover section 24 there are two contact hole regions 36 and 38, the contact hole bottom of which ends at a section 40 of the conductor track LB2. The section 40 is at right angles to the longitudinal axis 34. At its upper end, the contact hole regions are delimited by sections of the conductor track LB2 lying in the metallization layer 50. The conductor tracks LB1 and LB3 are arranged in the crossover section 24 parallel to one another, but obliquely to the longitudinal axis 34 at an angle of approximately 30 degrees such that the conductor track LB1 and the conductor track LB3 by one conductor track width and by the distance A between adjacent conductor tracks NEN be relocated. The above-described routing of the conductor tracks LB1 to LB3 results in a type of twisting of the conductor tracks LB1 to LB3. A length L1 of the end section 18, a length L2 of the middle section 22 and a length L3 of the end section 26 are the same, so that each conductor track LB1 to LB3 lies exactly in one end section 18 or in the middle section 22 between the other conductor tracks LB1 to LB3. For example, the conductor track LB3 is only in the middle section 2 between the conductor tracks LB1 and LB2. In the exemplary embodiment, the lengths L1, L2 and L3 are each 100 micrometers. In contrast, the crossover sections 20 and 24 are smaller than a fifth of this length, for example ten micrometers.

Widths B1, B2 and B3 of the conductor tracks LB1, LB2 and LB3 are the same in the end sections 18, 26 and in the middle section 22, for example one micrometer. An insulation distance A between adjacent conductor tracks LB1 to LB3 is, for example, 0.5 micrometers. The total width B of the line 12 results from the sum of the widths B1 to B3 and twice the insulation distance A, i.e. four micrometers in the exemplary embodiment.

A coordinate system 42 assigned to the circuit arrangement 10 shows an x-axis 44 lying in the plane of the drawing and coinciding with the direction of the longitudinal axis 34, a y-axis 46 lying at right angles to the x-axis 44 in the plane of the drawing and a y-axis 46 pointing in the normal direction to the plane of the drawing z-axis 48. FIG. 1 also shows the position of a cross-section I which intersects the line 12 in the xz plane. The cross section I cuts the conductor track LB1 in the end section 18, the conductor track LB2 in the middle section 22 and the conductor track LB3 in the end section 26.

FIG. 2 shows the cross section I through the line 12. Above the upper metallization layer 50 already mentioned with reference to FIG. 1 there is an insulating layer 49. Between the upper metallization layer 50 and the lower metallization layer 50 approximately 54 an insulating layer 52 is arranged. An insulation layer 56 is located below the lower metallization layer 54. A semiconductor substrate and possibly further metallization layers 58 and insulation layers are indicated by dots in FIG. The upper metallization layer 50, the insulation layer 52, the metallization layer 54, and the insulation layer 56 have thicknesses D1, D2, D3 and D4 in this order. The thicknesses D1 and D3 are the same in the exemplary embodiment and are, for example, 0.5 micrometers. The thicknesses D2 and D4 of the insulating layer are also the same in the exemplary embodiment and are, for example, one micrometer.

In other embodiments of the line 10, more than three conductor tracks are used. The number of crossover sections then increases accordingly. For example, there would be three crossover sections with four conductor tracks. However, there are also lines with more than ten conductor tracks.

FIG. 3 shows a top view of an integrated circuit arrangement 110 which contains an integrated line 112. The integrated line 112 contains three conductor tracks LBa to LBc, which are electrically connected in parallel in a connection section 114 at the left end of the line 112 or in a connection section (not shown) at the other end of the line 112. An end section 118, a crossover section 120, a middle section 122, a crossover section 124 and an end section 126 lie between the connection sections 114 and 116 in the following order.

Within the end sections 118, 126 and within the middle section 122, the conductor tracks LBa to LBc lie one above the other in three metallization layers 202, 206 and 210 in the normal direction of a semiconductor substrate of the circuit arrangement 110, see also FIG. 4. Accordingly, only the top ones are shown in FIG. 3 Conductor tracks shown, ie in the end 118 cut the conductor track LBa, in the middle section 122 the conductor track LBb and in the end section 126 the conductor track LBc.

In the crossover section 110, there is a bypass section 150 of the conductor track LBb on one side of the line 112, which is located in the metallization layer 206. With the help of the bypass section 150, the conductor track LBb is guided past a contact hole region 220, which is explained in more detail below with reference to FIG. 4.

A bypass section 152 of the conductor track LBc is located on the other side of the line 112. The bypass section 152 lies in the metallization layer 210. With the help of the bypass section 152, the conductor track LBc is guided past the contact hole region 220. Also located in

Crossover section 120 contact hole areas 222, 224 and 226, which are also shown in Figure 4.

The crossover region 124 is structured in exactly the same way as the crossover region 120. In the crossover region 124, the conductor track LBb is guided downward in a contact hole region 230, which is explained in more detail below with reference to FIG. A bypass section 160 of the conductor track LBc lies on one side of the line 112 in the crossover section 124 in the metallization layer 206. The bypass section 160 leads the conductor track LBc past the contact hole region 230 and then back to the longitudinal axis 134 of the line 112. On the other side of the line 112 is a bypass section 162 of the conductor track LBa in the crossover section 124. The bypass section 162 lies in the metallization layer 210 and leads the line LBa past the contact hole region 230.

The end section 118, the middle section 122 and the end section 126 have a length La, Lb and Lc. The lengths La, Lb and Lc are the same and are 50 micrometers in the exemplary embodiment. The crossover sections 120 and 124 are compared to the length of the end sections 118, 126 and the middle section 122 short, for example only ten micrometers. The conductor tracks LBa, LBb and LBc have widths Ba, Bb and Bc, which are the same and are, for example, one micrometer in the exemplary embodiment.

A coordinate system 172 shows an x-axis 174 which lies in the longitudinal direction 134 of the line 112. A y-axis 176 is at right angles to the x-axis 174. A z-axis 180 points in the normal direction of the drawing plane or in the normal direction of the main surface of a semiconductor substrate of the circuit arrangement 110. The position of a cross section II is shown in FIG , which lies in the xz plane and intersects all conductor tracks LBa to LBc in the end section 118, in the middle section 122 or in the end section 126.

FIG. 4 shows the cross section II through the line 112. In FIG. 4, an insulating layer 200, the metal layer 202, an insulating layer 204, the metal layer 206, an insulating layer 208, the metal layer 210, an insulating layer 212, from above to a semiconductor substrate (not shown), a metal layer 214 and an insulating layer 216 are shown. The insulation layers 200, 204, 208, 212 and 216 contain, for example, silicon dioxide as the insulation material. The metal layer 202, the insulating layer 204, the metal layer 206, the insulating layer 208, the metal layer 210, the insulating layer 212 and the metal layer 214 have thicknesses D5, D6, D7, D8, D9, D10 and DU in this order. The thicknesses D5, D7, D9 and DU of the metal layers are the same and are, for example, 0.5 micrometers. The thicknesses D6, D8 and D10 of the insulation layers are also the same and are, for example, one micrometer.

In the end section 118, in the middle section 122 or in the end section 126, the line 112 has a width W1 which results from the addition of the thicknesses D5 to D9, ie in the exemplary embodiment a width W1 of 3.5 micrometers. In the crossover area 120 or in the crossover area 124, on the other hand, the line 112 has a width W2 which results from the addition of the thicknesses D5 to DU, ie in the exemplary embodiment a width W2 of six micrometers.

In other exemplary embodiments, the bypass sections 150 to 162 lie on the same side of the line 112. The lower interconnect can also be routed upward in the crossover sections 120 and 124, respectively.

The number of conductor tracks of the type of line explained with reference to FIGS. 3 and 4 is limited by the number of metallization layers available. For example, four conductor tracks can be used, in which case three crossover sections are required. However, there are also integrated circuit arrangements with six or eight metallization layers, so that the number of conductor tracks can be increased further.

In summary, it can be stated that, in the exemplary embodiments, additional resistance is created by the contact hole or VIA structures. However, the overall conductance is increased even for high frequencies. The overall conductance can be increased further by increasing the conductor width B or the conductor width Wl by using additional conductor paths. If one were only to use parallel conductor tracks, widening the line would no longer have a positive effect from the point at which the penetration depth of the current is smaller than half the conductor track width of the conductor tracks in the line due to the skin effect or the proximity effect. Electrodynamic simulations with field calculation programs confirm this. This means that low-impedance connecting cables can be built even for high frequencies or that their conductance scales to a good approximation with the overall width of the cable.

Claims

claims

1. Integrated conductor track arrangement (12, 112),

with at least three electrically connected conductor tracks (LBl to LB3),

with an electrical insulating material (52) arranged between the conductor tracks (LB1 to LB3),

and with at least two crossover sections (20, 24) arranged at different points on the longitudinal axis (34) of the conductor track arrangement (12), at which conductor tracks (LB1 to LB3) of the conductor track arrangement (12) cross.

2. interconnect arrangement (12, 112) according to claim 1, by gekennz ei chnet that the interconnects (LBl to LB2) outside the crossing sections (20, 24) are lined up in one plane transverse to the longitudinal direction (34) of the interconnect arrangement (12) ,

3. interconnect arrangement (12, 112) according to claim 1 or 2, characterized in that the interconnects (LB1 to LB3) are arranged between adjacent crossover sections (20, 24) in a metallization layer (50).

4. The conductor track arrangement (12, 112) according to claim 3, characterized in that a conductor track (LB1) is arranged transversely to the other conductor tracks (LB2, LB3) at a crossover section (20),

and / or that the transversely arranged conductor track (LB1) and / or the other conductor tracks (LB2, LB3) are arranged in a different metallization layer (54).

5. conductor arrangement (12, 112) according to claim 4, because - by gekenn ze ichnet that the other conductor tracks (LB2, LB3) are arranged on a crossover section (20) in a different direction than outside the crossover section (20).

6. interconnect arrangement (12, 112) according to one of the preceding claims, characterized gekennz e i chnet that the interconnects (LBa to LBc) outside the crossover sections (120, 124) are arranged in different metallization layers (202, 206, 210).

7. The conductor track arrangement (12, 112) according to claim 6, characterized by the fact that a conductor track (LBa) is arranged in a contact hole (220) transversely to the other conductor tracks (LBb, LBc) at a crossover section (120) , and that the contact hole (220) preferably leads to a further metallization layer (214).

8. interconnect arrangement (12, 112) according to claim 7, characterized by gekennz e i chnet that the interconnects (LBa to LBc) in a crossover section (120) each from a metallization layer in an adjacent metallization layer.

9. interconnect arrangement (12, 112) according to one of the preceding claims, characterized gekennz ei chne t that the interconnect arrangement (12) contains only two crossing sections (20, 224), preferably at one third and two thirds of the length of the interconnect arrangement (12) lie.

10. interconnect arrangement (12, 112) according to one of the preceding claims, characterized in that the crossing sections (20, 24) are structured identically,

and / or that the sections (18, 22, 26) of the interconnect arrangement (12) lying outside the crossover sections (20, 24) have the same structure.

11. interconnect arrangement (12, 112) according to one of the preceding claims, characterized in that each interconnect (LB1 to LB3) is arranged the same length between other interconnects (LB1 to LB3),

and / or that each conductor track (LB1 to LB3) has the same length at the edge of the conductor track arrangement (12).

12. interconnect arrangement (12, 112) according to one of the preceding claims, characterized gekennz e i chnet that the interconnects (LBl to LB3) are arranged such that the same current flows through each interconnect (LBl to LB3).

13. trace arrangement (12, 112) according to any one of the preceding claims, characterized gekennz e i chnet that it is used to conduct a current with a frequency greater than one gigahertz or greater than 50 gigahertz or greater than 500 gigahertz.

14. trace arrangement (12, 112) according to one of the preceding claims, since you r c h g e k e nn z e i c hne t that the largest lateral dimension (B1 to B3) of a trace is less than ten microns or less than five microns,

and / or the length of the conductor track arrangement (129) is less than ten millimeters or less than one millimeter.

15. interconnect arrangement (12, 112) according to one of the preceding claims, characterized in that the interconnect arrangement is part of an integrated circuit arrangement (10, 110) which contains a multiplicity of electronic components in a semiconductor substrate.

16. conductor arrangement (12, 112) according to any one of the preceding claims, characterized gekennz ei that the conductor track arrangement (12) is used as a coil which has an inductance required for the functioning of a circuit arrangement,

and / or that the conductor track arrangement (12) is used as signal routing to an antenna of a transmitting part or as signal routing from an antenna of a receiving part.