EP1103031A1

EP1103031A1 - Semiconductor component having a passivation

Info

Publication number: EP1103031A1
Application number: EP99945847A
Authority: EP
Inventors: Josef Willer; Paul-Werner Von Basse; Thomas Scheiter
Original assignee: Infineon Technologies AG
Current assignee: Infineon Technologies AG
Priority date: 1998-07-09
Filing date: 1999-07-01
Publication date: 2001-05-30
Also published as: JP3527708B2; US20010019168A1; JP2002520841A; CN1308751A; BR9911980A; KR20010071808A; CN1135493C; US6664612B2; WO2000003345A1; UA46173C2; RU2001103636A; RU2195048C2; KR100413860B1

Abstract

The invention relates to a component having a passivation comprised of at least two passivation double layers of which the top layer is deposited on a planar surface of the layer located thereunder. The passivation double layers are comprised of two layers made of different dielectric materials, e.g. silicon oxide and silicon nitride. The respective thicknesses of the individual passivation layers can be adapted to the dimensions of the structuring of the layer on which the passivation is deposited. A reliable passivation is thus obtained which is especially suited for finger print sensors which measure in a capacitive manner.

Description

description

Semiconductor device with passivation

The present invention relates to a semiconductor component which is provided on its upper side with a resistant, flat passivation, as is particularly suitable as a cover layer of constant thickness with a flat contact surface for capacitively measuring fingerprint sensors.

If a surface of a semiconductor component is exposed to the surrounding atmosphere and, as in the case of a fingerprint sensor, is exposed to mechanical abrasion, it is necessary to passivate this surface in such a way that the functionality of the component is retained. Such passivation is critical, in particular, in the case of capacitively measuring micromechanical components in which an outer upper surface exposed to wear and tear must maintain a constant / distance from conductor surfaces integrated in the component. Particularly in the case of fingerprint sensors, in which this outer upper side forms the contact surface for a fingertip, it is important that this contact surface is completely flat and guarantees a fixed Z-distance between the finger tip and the conductor surfaces provided for the measurement, even under prolonged use. In the manufacture of microelectronic components, e.g. B. in the material system of silicon, silicon oxide layers and silicon nitride layers are common passivations. The top side of the semiconductor components is usually provided with 7 connection contacts and conductor tracks for the electrical wiring. Different metallization levels can be present, each consisting of structured metal layers and separated from one another by dielectric material (intermediate oxides). An oxide layer is usually applied to the top of the top metallization level. B. from a plasma using CVD (chemical vapor deposition) from an SiH ₄ / N ₂ 0 atmosphere at about 400 ° C, typically about 300 nm is deposited thick. A further passivation layer made of silicon nitride (Si ₃ N ₄ ) can be deposited from a plasma by means of CVD under an SiH ₄ / NH ₃ / N2 atmosphere, likewise at about 400 ° C. in a typical thickness of 550 nm. Since the metallization level is structured, the passivation, which is deposited over the entire area, does not have a flat top side, but is uneven on the flanks of the metallization.

With fingerprint sensors in particular, it has been shown that sodium diffusion, caused by touching the sensors, can occur. This may be due to the fact that the passivation has defects which lead to degradation through the occurrence of so-called pinholes. On the other hand, even largely conformally deposited layers have growth joints in the corners between the vertical flanks and the surfaces parallel to the layer plane, which appear due to increased etching rates and where the barrier effect of the passivation can be significantly weakened. The barrier effect cannot be improved sufficiently by applying thicker layers, since the sensitivity of capacitively measuring components decreases too much due to the increased thickness of the passivation layer.

The object of the present invention is to provide a semiconductor component which is passivated in such a way that the upper side is flat and maintains a constant / distance from an integrated metallization layer.

This object is achieved with the component with the features of / claim 1. Refinements result from the dependent claims.

In the semiconductor component according to the invention, a multilayer passivation is present, which consists of at least two passivation double layers and whose uppermost passivation double layer is applied to a flat surface of the passivation double layer located underneath. The Passivation double layers can each be formed by a passivation layer made of an oxide, preferably silicon oxide, and a passivation layer made of a nitride, preferably silicon nitride. With just two such passivation double layers, an unexpectedly significant improvement in the passivation properties of the passivation is achieved. However, there can also be more than two passivation double layers. The passivation double layers are composed of two layers of different dielectric materials, it being possible for different passivation double layers to consist of different pairs of materials. The respective thicknesses of the individual passivation layers can be adapted to the respective dimensions of the component, in particular the dimensions of the structuring of the layer to which the passivation is applied.

There follows a detailed description of the component according to the invention with reference to FIGS. 1 and 2, which show cross-sectional intermediate products of the production of a typical component of this type. In Figure 1, a semiconductor body 1 is shown in cross section, the z. B. can be a substrate with semiconductor layers grown thereon; a dielectric layer 2 as intermediate metal oxide or as the lowest passivation of the semiconductor material z. B. from BPSG

(Borophosphosilicate glass); a structured lower metallization level 4 shown as an example; a further dielectric layer 3, which electrically isolates the metallization level 4 from the next metallization level 5, the metallizations at certain points by vertical

Contacts can be connected to each other; the further metallization level 5, which here forms the uppermost metallization level; and the passivation to be described in more detail below.

Three layers of this passivation are first drawn in in FIG. A first passivation double layer is consists of layers 6 and 7, of which the lower passivation layer 6 z. B. a conventional oxide that can be deposited as in the manner described above, may be. The second passivation layer 7 of this first passivation double layer is another dielectric material; if the first passivation layer 6 is an oxide, the second passivation layer 7 is preferably a nitride, which can also be deposited as described at the beginning. A first passivation layer of another is applied to this first passivation double layer during manufacture

Passivation double layer, e.g. B. again an oxide, deposited somewhat thicker. The latter layer 8 is removed somewhat, e.g. can be done by means of CMP (chemical mechanical polishing). Alternatively or in addition, an etching process can be used. This results in a very flat surface of this layer 8.

In addition to the layer structure shown in FIG. 1, FIG. 2 shows the ground back first passivation layer 8 of the second passivation double layer with a flat upper side. The second passivation layer 9 of the second passivation double layer is deposited very evenly over the entire surface of the layer 8. Layer 9 is preferably a nitride again. The layer sequence oxide-nitride-oxide-nitride results in this preferred embodiment of the passivation according to the invention.

Instead of just two passivation double layers, there can also be several passivation double layers. The position at which the top side of such a passivation double layer is leveled depends on the respective / application and in particular on the layer thicknesses and the dimensions of the structure in the upper metallization level 5. If appropriate, a further layer can be applied on the top side as a special cover . This is of particular interest when the upper passivation layer is not has sufficient hardness to be sufficiently resistant to mechanical abrasion.

The fact that the component has at least two passivation double layers applied one above the other and at least the uppermost passivation double layer, which acts as an amorphous diffusion barrier, is deposited on a largely flat surface, so that the top passivation double layer has no edge-dependent diffusion paths good passivation achieved. The combination of several layers prevents the formation of diffusion paths that could arise from pinholes that cannot be completely avoided.

During production, the passivation layer provided for leveling the top side can also be produced in two separate process steps. The etching back or grinding back of this layer is then carried out until a very flat surface is achieved, regardless of whether a thickness of this layer intended for this passivation layer remains or not. If the layer has been sanded back too far, in particular up to the top of the passivation layer underneath, a layer of the material of this sanded-back layer is applied again, this newly applied layer now being given a very flat surface. A manufacturing process can e.g. B. in the deposition of the first passivation double layer of typically 300 nm oxide and 550 nm nitride, a / deposition of an approximately 500 nm thick oxide layer, a selective CMP step with stop on the previously deposited nitride layer and the complete deposition of the second passivation double layer of typically 300 nm oxide and 550 nm nitride exist. Further process steps for structuring the passivation in side areas and for making the necessary electrical connections can follow.

Claims

claims

1. Semiconductor component with a semiconductor body (1) which carries a layer (5) structured with gaps, - in which a passivation consisting of at least two superposed passivation double layers (6, 7; 8, 9) is present, which the structured layer (5 ) on the side facing away from the semiconductor body (1) and fills the spaces in the structured layer (5), - in which each passivation double layer is formed from two passivation layers of different dielectric materials and - in which at least the passivation double layer (8, 9), which is furthest away from the semiconductor body, is applied in a uniform thickness to a leveled top of the preceding passivation double layer (6, 7).

2. The component according to claim 1, wherein a passivation double layer (6, 7) contains a passivation layer made of oxide (6) and a passivation layer made of nitride (7).

3. Component according to / claim 1 or 2, wherein the structured layer (5) is a metallization layer and is applied to at least one layer made of a dielectric on an upper side of the semiconductor body (1).

4. The component according to claim 3, in which the metallization layer forms conductive surfaces of a capacitively measuring fingerprint sensor and in which the passivation double layer (8, 9) furthest away from the metallization layer has a surface which forms a contact surface for a fingertip.