Patent Description:
Power semiconductor module arrangements often include at least one semiconductor substrate arranged in a housing. A semiconductor arrangement including a plurality of controllable semiconductor elements (e.g., two IGBTs in a half-bridge configuration) is arranged on each of the at least one substrates. Each substrate usually comprises a substrate layer (e.g., a ceramic layer), a first metallization layer deposited on a first side of the substrate layer and a second metallization layer deposited on a second side of the substrate layer. The controllable semiconductor elements are mounted, for example, on the first metallization layer. The second metallization layer may optionally be attached to a base plate. The controllable semiconductor devices are usually mounted onto the semiconductor substrate by soldering or sintering techniques.

Electrical lines or electrical connections are used to connect different semiconductor devices. Such electrical lines and electrical connections may include metal and/or semiconductor material. The housings of power semiconductor module arrangements are generally permeable to gases to a certain extent. Some gases such as sulfur containing gases, for example, may react with metallic components inside the housing. This leads to a chemical degradation of these components which may result in a failure of individual components and ultimately of the whole semiconductor arrangement.

Document <CIT> discloses an electronic module having a module housing and a protective mass located in the module housing. The protective compound has a matrix and a reaction partner which is distributed in the matrix and which is designed to form a chemical pollutant consisting of sulfur or a sulfur which is introduced into an interior space of the module housing penetrates to chemically react and thereby prevent the sulfur from causing corrosion of a component of the electronic module to be protected.

Document <CIT> discloses an airtight configuration for keeping down the permeation of corrosive gas from silicone adhesive, and for preventing corrosive gas from entering the case. An electronic device mounted on vehicle, the electronic device has at least one of a portion connecting components, and a portion sealing the clearance or hole where exists in the electronic device. The at least one of the connection portion and the seal portion is constituted by using adhesive or sealant which has at least one of a function adsorbing corrosive gas and a function trapping corrosive gas with chemical reaction.

Document <CIT> discloses a power semiconductor module with a base plate which is designed as a ceramic substrate metallized at least on the inside of the module and which has a mounting surface facing the interior of the module, on which a power semiconductor circuit with at least one power semiconductor chip is arranged; at least one stiffening rib serving to stiffen the base plate, which projects beyond the mounting surface, and which is fixedly connected to the base plate or formed integrally therewith.

There is a need for a semiconductor module arrangement that offers protection for the semiconductor components arranged therein against corrosion such that the overall lifetime of the power semiconductor module arrangement is increased.

In accordance with the present invention, there is provided a first power semiconductor module according to claim <NUM>.

In accordance with the present invention, there is provided a second power semiconductor module according to claim <NUM>.

Also in accordance with the present invention, there is provided a first method for producing a power semiconductor module according to claim <NUM>.

Also in accordance with the present invention, there is provided a second method for producing a power semiconductor module according to claim <NUM>.

In the following detailed description, reference is made to the accompanying drawings. The drawings show specific examples in which the invention may be practiced. It is to be understood that the features and principles described with respect to the various examples may be combined with each other, unless specifically noted otherwise. In the description as well as in the claims, designations of certain elements as "first element", "second element", "third element" etc. are not to be understood as enumerative. Instead, such designations serve solely to address different "elements". That is, e.g., the existence of a "third element" does not require the existence of a "first element" and a "second element". An electrical line or electrical connection as described herein may be a single electrically conductive element, or include at least two individual electrically conductive elements connected in series and/or parallel. Electrical lines and electrical connections may include metal and/or semiconductor material, and may be permanently electrically conductive (i.e., non-switchable). A semiconductor body as described herein may be made from (doped) semiconductor material and may be a semiconductor chip or be included in a semiconductor chip. A semiconductor body has electrically connecting pads and includes at least one semiconductor element with electrodes.

Referring to <FIG>, a cross-sectional view of a power semiconductor module arrangement <NUM> is illustrated. The power semiconductor module arrangement <NUM> includes a housing <NUM> and a semiconductor substrate <NUM> (dielectric substrate). The semiconductor substrate <NUM> includes a dielectric insulation layer <NUM>, a (structured) first metallization layer <NUM> attached to the dielectric insulation layer <NUM>, and a (structured) second metallization layer <NUM> attached to the dielectric insulation layer <NUM>. The dielectric insulation layer <NUM> is disposed between the first and second metallization layers <NUM>, <NUM>.

Each of the first and second metallization layers <NUM>, <NUM> may consist of or include one of the following materials: copper; a copper alloy; aluminum; an aluminum alloy; any other metal or alloy that remains solid during the operation of the power semiconductor module arrangement. The semiconductor substrate <NUM> may be a ceramic substrate, that is, a substrate in which the dielectric insulation layer <NUM> is a ceramic, e.g., a thin ceramic layer. The ceramic may consist of or include one of the following materials: aluminum oxide; aluminum nitride; zirconium oxide; silicon nitride; boron nitride; or any other dielectric ceramic. For example, the dielectric insulation layer <NUM> may consist of or include one of the following materials: Al<NUM>O<NUM>, AlN, SiC, BeO or Si<NUM>N<NUM>. For instance, the substrate <NUM> may, e.g., be a Direct Copper Bonding (DCB) substrate, a Direct Aluminium Bonding (DAB) substrate, or an Active Metal Brazing (AMB) substrate. Further, the substrate <NUM> may be an Insulated Metal Substrate (IMS). An Insulated Metal Substrate generally comprises a dielectric insulation layer <NUM> comprising (filled) materials such as epoxy resin or polyimide, for example. The material of the dielectric insulation layer <NUM> may be filled with ceramic particles, for example. Such particles may comprise, e.g., Si<NUM>O, Al<NUM>O<NUM>, AlN, or BN and may have a diameter of between about <NUM> and about <NUM>. The substrate <NUM> may also be a conventional printed circuit board (PCB) having a non-ceramic dielectric insulation layer <NUM>. For instance, a non-ceramic dielectric insulation layer <NUM> may consist of or include a cured resin.

The semiconductor substrate <NUM> is arranged in a housing <NUM>. In the example illustrated in <FIG>, the semiconductor substrate <NUM> forms a ground surface of the housing <NUM>, while the housing <NUM> itself solely comprises sidewalls and a cover. This is, however, only an example. It is also possible that the housing <NUM> further comprises a ground surface and the semiconductor substrate <NUM> is arranged inside the housing <NUM>. According to another example, the semiconductor substrate <NUM> may be mounted on a base plate (see, e.g., <FIG>). In some power semiconductor module arrangements <NUM>, more than one semiconductor substrate <NUM> is arranged on a single base plate. A base plate may form a ground surface of the housing <NUM>, for example.

One or more semiconductor bodies <NUM> may be arranged on the at least one semiconductor substrate <NUM>. Each of the semiconductor bodies <NUM> arranged on the at least one semiconductor substrate <NUM> may include a diode, an IGBT (Insulated-Gate Bipolar Transistor), a MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor), a JFET (Junction Field-Effect Transistor), a HEMT (High-Electron-Mobility Transistor), or any other suitable controllable semiconductor element.

The one or more semiconductor bodies <NUM> may form a semiconductor arrangement on the semiconductor substrate <NUM>. In <FIG>, only two semiconductor bodies <NUM> are exemplarily illustrated. The second metallization layer <NUM> of the semiconductor substrate <NUM> in <FIG> is a continuous layer. The first metallization layer <NUM> is a structured layer in the example illustrated in <FIG>. "Structured layer" in this context means that the first metallization layer <NUM> is not a continuous layer, but includes recesses between different sections of the layer. Such recesses are schematically illustrated in <FIG>. The first metallization layer <NUM> in this example includes three different sections. Different semiconductor bodies <NUM> may be mounted on the same or to different sections of the first metallization layer <NUM>. Different sections of the first metallization layer may have no electrical connection or may be electrically connected to one or more other sections using, e.g., bonding wires <NUM>. Electrical connections <NUM> may also include bonding ribbons, connection plates or conductor rails, for example, to name just a few examples. The one or more semiconductor bodies <NUM> may be electrically and mechanically connected to the semiconductor substrate <NUM> by an electrically conductive connection layer <NUM>. Such an electrically conductive connection layer may be a solder layer, a layer of an electrically conductive adhesive, or a layer of a sintered metal powder, e.g., a sintered silver powder, for example.

The power semiconductor module arrangement <NUM> further includes terminal elements <NUM>. The terminal elements <NUM> are electrically connected to the first metallization layer <NUM> and provide an electrical connection between the inside and the outside of the housing <NUM>. The terminal elements <NUM> may be electrically connected to the first metallization layer <NUM> with a first end, while a second end <NUM> of the terminal elements <NUM> protrudes out of the housing <NUM>. The terminal elements <NUM> may be electrically contacted from the outside at their second end <NUM>. Such terminal elements <NUM>, however, are only an example. The components inside the housing <NUM> may be electrically contact from outside the housing <NUM> in any other suitable way. For example, terminal elements <NUM> may be arranged closer or adjacent to the sidewalls of the housing <NUM>. It is also possible that terminal elements <NUM> protrude vertically or horizontally through the sidewalls of the housing <NUM>. It is even possible that terminal elements <NUM> protrude through a ground surface of the housing <NUM>.

The semiconductor bodies <NUM> each may include a chip pad metallization, e.g., a source, drain, anode, cathode or gate metallization. A chip pad metallization generally provides a contact surface for electrically connecting the semiconductor body <NUM>. The chip pad metallization may electrically contact a connection layer <NUM>, a terminal element <NUM>, or an electrical connection <NUM>, for example. A chip pad metallization may consist of or include a metal such as aluminum, copper, gold or silver, for example. The electrical connections <NUM> and the terminal elements <NUM> may also consist of or include a metal such as copper, aluminum, gold, or silver, for example.

The above mentioned components, as well as other components of the semiconductor arrangement inside the housing <NUM>, may corrode when they come into contact with corrosive gases. Corrosive gases may include, e.g., sulfur or sulfur-containing compounds. Corrosive gases in the surrounding area of the power semiconductor module arrangement <NUM> may penetrate into the inside of the housing <NUM>. The housings <NUM> that are used for power semiconductor module arrangements <NUM> are usually not fully protected against protruding gases. Further, corrosive gases may enter the housing <NUM> when the housing <NUM> is opened or during production before the housing <NUM> is closed, for example. Inside the housing <NUM>, the corrosive gases may form acids or solutions, for example, in combination with moisture that is present inside the housing <NUM>. The corrosive gases or the resulting solutions may cause a corrosion of some or all of the components. During the corrosion process, the metallic constituents of the components may be oxidized to their respective sulfides. The sulfide formation may alter the electrical properties of the components or may result in the formation of new conductive connections and in short circuits within the power semiconductor module arrangement <NUM>.

Examples for corrosive gases are hydrogen sulfide (H<NUM>S), carbonyl sulfide (OCS), or gaseous sulfur (S<NUM>). Generally, it is also possible that sulfur gets to the inside of the housing <NUM> as constituent of a solid material or liquid.

Components including one or more metals such as copper (e.g., first metallization layer <NUM>, electrical connection <NUM>, terminal element <NUM>, connection layer <NUM>, chip pad metallization), silver (e.g., first metallization layer <NUM>, electrical connection <NUM>, terminal element <NUM>, connection layer <NUM>, chip pad metallization), or lead (e.g. connection layer <NUM> including leaded solder), may be particularly sensitive to corrosion. Other metals such as aluminum, for example, may have a thin oxide layer covering their surface area, which may provide at least a certain amount of protection against corrosive gases.

The power semiconductor module arrangement <NUM> generally further includes a casting compound <NUM>. The casting compound <NUM> may consist of or include a silicone gel, a silicone, polyurethane, epoxy, or polyacrylate based isolation material, or may be a rigid molding compound, for example. The casting compound <NUM> may at least partly fill the interior of the housing <NUM>, thereby covering the components and electrical connections that are arranged on the semiconductor substrate <NUM>. The terminal elements <NUM> may be partly embedded in the casting compound <NUM>. At least their second ends <NUM>, however, are not covered by the casting compound <NUM> and protrude from the casting compound <NUM> through the housing <NUM> to the outside of the housing <NUM>. The casting compound <NUM> is configured to protect the components and electrical connections inside the power semiconductor module <NUM>, in particular inside the housing <NUM>, from certain environmental conditions and mechanical damage. However, corrosive gases are usually able to penetrate through the casting compound <NUM>. The casting compound <NUM>, therefore, is usually not able to protect the components and electrical connections from corrosive gases.

The casting compound <NUM> may form a first protective layer with a first thickness d1 in a vertical direction y. The vertical direction y is a direction that is essentially perpendicular to a top surface of the semiconductor substrate <NUM>. The top surface of the semiconductor substrate <NUM> is a surface on which semiconductor bodies <NUM> are or may be mounted. The first protective layer <NUM> at least partly covers any components that are arranged on the top surface of the semiconductor substrate <NUM> as well as any exposed surfaces of the semiconductor substrate <NUM>. The first thickness d1 may be between <NUM> and <NUM>, for example.

Referring to <FIG>, to additionally protect the components inside the housing <NUM> against corrosive gases, the power semiconductor module arrangement <NUM> further includes a second protective layer <NUM>. The second protective layer <NUM> is arranged on a top surface of the first protective layer <NUM>. The top surface of the first protective layer <NUM> is a surface opposite to its lower surface, wherein the lower surface covers the components and the semiconductor substrate <NUM>. The second protective layer <NUM> is configured to seal at least a part of the inside of the housing <NUM>. For example, the inside of the housing <NUM> may be divided into two areas, namely a first area in which the semiconductor substrate <NUM> and any components and electrical connections mounted on the semiconductor substrate <NUM> are arranged, and a second area which does not include any major components. For example, the first protective layer <NUM> may form an essential part of the first area. The terminal elements <NUM> may pass from the semiconductor substrate <NUM> through the first area (first protective layer <NUM>) and through the second area to the outside of the housing <NUM>. Without a second protective layer <NUM>, corrosive gases may, for example, penetrate the second area and then reach the components of the semiconductor arrangement through the first area. The second protective layer <NUM> is arranged between the first area and the second area, thereby protecting the first area and any components arranged in the first area against the corrosive gases. Corrosive gases, for example, may enter the second area of the inside of the housing <NUM> through the openings that allow the terminal elements <NUM> to pass through the housing <NUM>. The corrosive gases, however, are prevented from entering the first area by the second protective layer <NUM>.

The second protective layer <NUM> may have a second thickness d2 in the vertical direction y. The second thickness d2 may be between <NUM> and <NUM>, for example. The second protective layer <NUM> includes a first material. The first material may be a dielectric material. The second protective layer <NUM> further includes a reactant <NUM>. The reactant <NUM> is configured to chemically react with the corrosive gases, or, in particular, with the sulfur or sulfur-containing compounds of the corrosive gases. If the reactant <NUM> itself is electrically conductive, the concentration of the reactant <NUM> in the first material may be chosen such that the second protective layer <NUM> as a whole is still dielectrically insulating. Corrosive gas may also be trapped, adsorbed or absorbed by the reactant <NUM>. By chemically reacting with the corrosive gas, the reactant <NUM> prevents the harmful substances from reaching the (metal) components inside the housing <NUM> and thereby protects the components against corrosion. The reactant <NUM> may be, for example, a powder of a second material which is (evenly) distributed throughout the first material of the second protective layer <NUM>. The second material may include a metallic material such as, e.g., Ag, Fe, Co, Ni, Cu, Sn, Pb, Mn or may include activated carbon, for example. These are, however, only examples. Any additional or alternative materials which react with the corrosive gases and which may, e.g., form a metal sulfide when exposed to corrosive gases, are also possible. The reactant <NUM> may be essentially evenly distributed throughout the second protective layer <NUM>. The first material may consist of or include a non-reactive polymer such as a silicone gel, acrylate, polyurethane, or silicone rubber, for example. Other casting materials are also possible such as epoxy resin, for example.

If the second material is an electrically conductive material such as a metallic material, for example, the concentration of the second material in the second protective layer <NUM> may be such that the second protective layer <NUM> as a whole is still electrically insulating.

In <FIG>, semiconductor module arrangements without base plate are schematically illustrated. In such semiconductor module arrangements, the semiconductor substrate <NUM> may form a bottom of the housing <NUM>. The housing <NUM> itself may only comprise sidewalls and a cover, for example. The sidewalls of the housing <NUM> may be attached to the semiconductor substrate <NUM> in any suitable way. For example, the sidewalls may be glued, brazed or soldered to the semiconductor substrate <NUM>. Some semiconductor module arrangements are known wherein a fluoropolymer is arranged between the semiconductor substrate <NUM> and the sidewalls of the housing <NUM>. That is, there is some kind of seal arranged between the semiconductor substrate <NUM> and the housing <NUM> which is configured to attach the housing <NUM> to the semiconductor substrate <NUM> and further to prevent gasses from entering the housing <NUM>.

Referring to <FIG>, a semiconductor module arrangement <NUM> comprising a seal <NUM> between the semiconductor substrate <NUM> and the housing <NUM> is schematically illustrated. According to one example, the seal comprises a third material. The third material may consist of or include a non-reactive polymer such as a silicone gel, acrylate, polyurethane, or silicone rubber, for example. Other casting materials are also possible such as epoxy resin, for example. The seal <NUM> may further comprise a fourth material <NUM> which may include a metallic material such as, e.g., Ag, Fe, Co, Ni, Cu, Sn, Pb, Mn or may include activated carbon, for example. The fourth material <NUM> generally has the same function as the second material <NUM> that has been described with respect to the second protective layer <NUM> above. That is, the fourth material <NUM> includes a reactant that is configured to chemically react with corrosive gases, or, in particular, with sulfur or sulfur-containing compounds of corrosive gases. Corrosive gas may also be trapped, adsorbed or absorbed by the reactant. By chemically reacting with the corrosive gas, the reactant prevents the harmful substances from reaching the (metal) components inside the housing <NUM> and thereby protects the components against corrosion. The reactant may be, for example, a powder of the fourth material <NUM> which is (evenly) distributed throughout the third material of the seal <NUM>.

The second protective layer <NUM> in the example illustrated in <FIG> is arranged on top of the first protective layer <NUM>. That is, the first protective layer <NUM> is arranged between the second protective layer <NUM> and the semiconductor substrate <NUM>. The second protective layer <NUM>, therefore, cannot prevent gasses, e.g., corrosive gasses, entering the housing through the joint between the semiconductor substrate <NUM> and the housing <NUM> from reaching the elements mounted on the semiconductor substrate <NUM>. Any gasses entering the housing <NUM> in this way only need to penetrate the first protective layer <NUM>. The additional seal <NUM> comprising the third material and the fourth material <NUM>, therefore, provides a further barrier for corrosive gasses. The semiconductor module arrangement <NUM>, therefore, is better protected against corrosive gasses than semiconductor module arrangements not comprising the seal <NUM>.

In the example illustrated in <FIG>, the second protective layer <NUM> only covers the first protective layer <NUM> in the vertical direction y. This, however, is only an example. Now referring to <FIG>, in accordance with the present invention, second protective layer <NUM>, in addition to a top surface of the first protective layer <NUM>, further extends along the side surfaces of the first protective layer <NUM>. The top surface of the first protective layer <NUM> is a surface facing away from the semiconductor substrate <NUM>. The side surfaces of the first protective layer <NUM> are surfaces perpendicular to the top surface and facing the sidewalls of the housing <NUM>. That is, the second protective layer <NUM> is arranged between the first protective layer <NUM> and the sidewalls of the housing <NUM>. The second protective layer <NUM> may extend along the side surfaces of the first protective layer <NUM> all the way down towards the semiconductor substrate <NUM>. That is, the second protective layer <NUM> is also arranged between the elements arranged on the semiconductor substrate <NUM> and the joint between the semiconductor substrate <NUM> and the housing <NUM>. In this way, the second protective layer <NUM> also prevents corrosive gases entering through the joint from reaching the components arranged on the semiconductor substrate <NUM>. The barrier for corrosive gasses, therefore, is even increased as compared to the arrangement of <FIG>.

The second protective layer <NUM> has a horizontal section covering the first protective layer <NUM> in the vertical direction y, and vertical sections which cover the side surfaces of the first protective layer <NUM>. The horizontal section may have a second thickness d2 in the vertical direction y, as has already been described above. The second thickness d2 may be between <NUM> and <NUM>, for example. The vertical sections may each have a third thickness d3 in the horizontal direction x. The third thickness d3 may be between <NUM> and <NUM>, for example. The third thickness d3 may equal the second thickness d2, for example.

Ideally, there are no gaps or spaces between the second protective layer <NUM> and the sidewalls of the housing <NUM>, between the second protective layer <NUM> and the semiconductor substrate <NUM> (<FIG>), as well as between the second protective layer <NUM> and any other components (e.g., terminal elements <NUM>) which extend through the second protective layer <NUM>.

As the reactant <NUM> of the second protective layer <NUM> may include a metal, for example, the first protective layer <NUM> that is arranged between the second protective layer <NUM> and the components arranged on the semiconductor substrate <NUM> prevents the reactant from reacting with the metal including components mounted on the semiconductor substrate <NUM>.

In the examples illustrated in <FIG>, the semiconductor module arrangement does not comprise a base plate and the housing <NUM> does not comprise a bottom. This, however, is only one embodiment of the present invention. <FIG> schematically illustrates a semiconductor arrangement similar to the arrangement of <FIG>, the only difference being that the semiconductor arrangement <NUM> of <FIG> comprises a bottom or a base plate <NUM>. That is, the housing <NUM> is not attached to the semiconductor substrate <NUM> but to the bottom or base plate <NUM> instead. The semiconductor substrate <NUM> is arranged on the bottom or base plate <NUM> and inside the housing <NUM>. All that has been described with respect to <FIG> above also simultaneously applies for the arrangement of <FIG>. The second protective layer <NUM> of the arrangement in <FIG> corresponds to the second protective layer <NUM> of the arrangement of <FIG>, the first protective layer <NUM> of the arrangement in <FIG> corresponds to the first protective layer <NUM> of the arrangement of <FIG>, and so on. The seal <NUM> that is arranged between the housing <NUM> and the bottom or base plate <NUM> in the arrangement of <FIG> corresponds to the seal <NUM> that has been described with respect to <FIG> above.

The same applies for the arrangement that is schematically illustrated in <FIG> and the arrangement that has been described with respect to <FIG> above. According to the present invention, the arrangement of <FIG> comprises a bottom or base plate <NUM> which is not present in the arrangement of <FIG>. Otherwise the arrangements of <FIG> and <FIG> correspond to each other.

According to one example, the second protective layer <NUM> may be produced as a flexible mat. The flexible mat may be produced separately and may then be placed on the top surface of the first protective layer <NUM>. It is, however, generally also possible that the second protective layer <NUM> is produced as a rigid plate instead of a flexible mat. A second protective layer <NUM> may have a hardness that is not very sticking and, therefore, rather easy to handle. Another hardness, however, is also possible.

The second protective layer <NUM> may be produced by any suitable process such as casting or molding, for example. The materials forming the second protective layer <NUM>, in particular the first material, may originally be in a liquid or viscous form. A mixture may be produced by mixing the first material and the second material. The mixture may then be filled into a casting mold, for example. After filling the mixture into the casting mold, the mixture may be developed (processed) into a solid or semi-solid mat or plate with the second material evenly distributed therein. The casting mold may have a simple rectangular or quadratic form, for example. The resulting mat or plate, therefore, may also have a rectangular or quadratic form. Recesses for the terminal elements may be cut out in a further step to adapt the form of the mat or plate to the geometry of the power semiconductor module arrangement <NUM>. For example, an extrusion method may be used to shape the mat or plate. Extrusion methods are generally used to create objects of a fixed cross-sectional profile. A material (e.g., the solid or semi-solid mat or plate) is pushed through a die or press mold of the desired cross-section. In this way, very complex cross-sections of the mat or plate may be created. It is, however, also possible that the casting mold includes respective recesses such that the mat or plate is casted or molded in the desired shape without the need for a further cutting step.

The mat or plate may subsequently be removed from the casting mold. For example, the mat or plate may be produced by a supplier. The manufacturer of the power semiconductor module arrangement <NUM> may buy the finished mat or plate and may insert the mat or plate into a power semiconductor module arrangement during the mounting process. The manufacturer, however, does not need to perform a molding step and/or a curing or hardening process when assembling the power semiconductor module arrangement <NUM>. By simply arranging the prefabricated mat or plate in the power semiconductor module arrangement <NUM>, the mat or plate does not have a substance-to-substance bond with any of the other components of the power semiconductor module arrangement <NUM>. In other words, it would be generally possible to remove the mat or plate from the power semiconductor module arrangement <NUM>, without destroying any of the other components. For example, the mat or plate does not have a substance-to-substance bond with the sidewalls of the housing. The mat or plate may have a certain adhesive strength and may adhere to the sidewalls to a certain degree. However, this is not a permanent bond. The same applies to the bond between the mat or plate and the first protective layer <NUM>.

Prefabricating the second protective layer <NUM>, however, is only an example. It is also possible to first arrange the first protective layer <NUM> in the housing <NUM> and then fill the still liquid first material with the second material <NUM> distributed therein into the housing <NUM>. The material in this case then needs to be hardened, e.g., by removing some or all of the liquid from the second protective layer <NUM>. For example, a heating or drying step may be performed in order to remove the liquid.

With respect to the arrangements illustrated in <FIG> and <FIG>, the material of the first protective layer <NUM> may filled into the housing <NUM>, followed by a hardening step (removing liquid from the first protective layer <NUM>). The second protective layer <NUM> may then be easily formed on the top surface of the first protective layer <NUM>.

With respect to the arrangements illustrated in <FIG> and <FIG>, a spacer may be inserted into the housing <NUM> before forming the first protective layer <NUM>. The spacer may fill any spaces adjacent to the sidewalls of the housing <NUM> during formation of the first protective layer <NUM> which will later be needed for the second protective layer <NUM>. Once the first protective layer <NUM> has been formed and hardened, the spacer may be removed. Afterwards, the materials of the second protective layer <NUM> is filled into the spaces between the first protective layer <NUM> and the sidewalls of the housing <NUM> and also on the top surface of the first protective layer <NUM>.

Claim 1:
A power semiconductor module arrangement (<NUM>) comprising:
a dielectric substrate (<NUM>), a housing (<NUM>) comprising sidewalls;
at least one semiconductor body (<NUM>) arranged on a top surface of the dielectric substrate (<NUM>);
a first protective layer (<NUM>) arranged on the top surface of the dielectric substrate (<NUM>), thereby covering the at least one semiconductor body (<NUM>);
a second protective layer (<NUM>) for protecting the power semiconductor module arrangement (<NUM>); and
a seal (<NUM>), wherein the second protective layer (<NUM>) comprises a first material and a second material (<NUM>),
wherein the second material (<NUM>) is distributed within the first material and
comprises a reactant, wherein the reactant is configured to chemically react with, trap, adsorb, or absorb corrosive gases;
the second protective layer (<NUM>) covers at least a top surface of the first protective layer (<NUM>), wherein a top surface of the first protective layer (<NUM>) is a surface facing away from the dielectric substrate (<NUM>),
the second protective layer (<NUM>) further comprises vertical sections covering side surfaces of the first protective layer (<NUM>) and arranged between the first protective layer (<NUM>) and the sidewalls of the housing (<NUM>), and
the seal (<NUM>) is arranged between the sidewalls of the housing (<NUM>) and the dielectric substrate (<NUM>), thereby attaching the housing (<NUM>) to the dielectric substrate (<NUM>), wherein the dielectric substrate forms a bottom of the housing, and the seal comprises a third material and a fourth material (<NUM>), wherein the fourth material (<NUM>) is distributed within the third material and comprises a reactant, wherein the reactant is configured to chemically react with, trap, adsorb, or absorb corrosive gases.