This application claims the priority of European Patent Application No. 15000074.3, filed Jan. 14, 2015, the disclosure of which is incorporated herein by reference in its entirety.
An increasing number of sensors are integrated into semiconductor chips. Such a sensor chip may be placed on a carrier such as a die pad, and possibly be encapsulated.
In some applications, the sensor chip is thinned from a back side of the sensor chip for building a thin membrane that is thermally isolated versus the rest of the sensor chip. This may serve the operation of a sensitive element on or in the membrane, for example, in particular when the sensitive element is provided for sensing a temperature or otherwise is sensitive to temperature, or, for example, when a heating operation is required during measuring or manufacturing which heat is not desired to migrate elsewhere to the chip but is desired to remain locally confined, e.g. in the membrane.
When such a sensor chip is mounted to a die pad with its back side facing the die pad, a cavity is generated between the sensor chip and the die pad in view of the recess in the sensor chip. In such arrangement, the membrane of the sensor chip lowers the total mechanical resistance of the sensor package, and the underlying cavity may promote an accumulation of moisture, for example, during manufacturing, shipment or handling. In particular, moisture may be absorbed by an encapsulation of the sensor chip containing organic material, e.g. plastics, if applicable, which moisture may be released into the cavity in response to elevated temperatures. During assembly, for example, a solder reflow process may induce elevated temperatures to the entire sensor package including the encapsulation if any. However, elevated temperatures may also be induced from external, or from internal, wherein during operation, for example, a heater may induce elevated temperatures if applicable. Irrespective of the source of heating, such elevated temperature may result in a vapor pressure increase inside the cavity, and in a plastic encapsulation of the sensor chip if applicable. Such moisture uptake may finally lead to delamination of material interfaces and/or to cracks in the sensor package which is also referred to as “popcorn” phenomenon.
For moisture/reflow sensitive components such as plastic-encapsulated surface mounted devices and other packages made with moisture-permeable materials, a moisture sensitivity level is determined by tests and a resulting classification determines storage conditions, packing, handling and timing specifications for the product at the manufacturer and the customer. In case the sensitivity of a sensor package to moisture can be reduced and less stringent moisture sensitivity levels can be achieved, packing requirements may be reduced and the handling of the sensor package may be facilitated. However, drilling a hole in the die pad underneath the cavity does not seem to solve the problem given that such hole provides access to the cavity and the membrane in the following which may allow dust, flux, PCB coating material, assembly chemicals, etc. enter the cavity e.g. during assembly of the sensor package itself, e.g. during dicing, handling, testing, etc., during shipment, during assembly on a PCB at costumer side, and during whole operating lifetime.
Hence, it is desired to provide a sensor package that is less prone to a vapor pressure increase in the cavity.
According to a first aspect of the invention, a sensor package is provided comprising a sensor chip with a front side and a back side, and with a recess in the back side. The sensor chip is attached to a carrier by means of an attachment layer with the back side facing the carrier thereby defining a first area of the carrier the sensor chip rests on and a second area of the carrier facing the recess. A through hole is provided in the carrier and is arranged in its first area. The through hole preferably is covered by the attachment layer and preferably serves as venting hole.
The carrier is meant to carry the sensor chip, which sensor chip is attached to the carrier. In this context, it is preferred that the carrier is a flat plate-like support. Preferably, the carrier is a die pad. However, all embodiments relating to the die pad in the following may also be applied to a different kind of carrier. In a preferred embodiment, the die pad is made from metal, and specifically is part of a lead frame structure.
At first glance, there is no direct channel between a cavity defined by the recess and the carrier on the one hand and the through hole on the other hand since the through hole is arranged offset from the recess. Instead, the attachment layer seals in between the sensor chip and the carrier. The attachment layer in one embodiment comprises an adhesive, such as epoxy material. At high temperatures, however, the attachment layer softens and allows a highly compressed gas caused by vapor pressure in the cavity to leak out from the cavity between the attachment layer and the sensor chip, or between the attachment layer and the carrier, and/or through the attachment layer to the venting hole. After pressure relief such channel through the attachment layer may close again. Without such a pressure relief, the membrane may risk to break at a certain loading. Hence, the attachment layer serves as a temperature and/or pressure dependent venting medium for releasing the cavity from excess pressure. On the other hand, the lack of a direct channel between the cavity and the through hole prevents solder, gas or water from intruding into the cavity, which otherwise may happen, for example, during manufacturing including assembly. At the same time, the cavity is protected from contamination, induced by flux during a solder reflow process at the customer, for example.
Hence, the present idea allows pressure balancing and removal of moisture from the cavity and thereby may achieve a lowered moisture sensitivity level (e.g. MSL-1 instead of MSL-3). This is achieved by adding the venting hole in the carrier next to the cavity or next to a groove, preferably in form of a half etched channel in the carrier, which connects to the cavity and leads next to the venting hole in the carrier. The carrier preferably is part of a lead frame structure made from an electrically and thermally conducting material, such as metal. Preferably, the sensor package is a QFN package (Quad Flat No-leads).
The sensor chip, also referred to as die, may contain a semiconductor substrate, such as a silicon substrate, into which semiconductor substrate a processing circuit preferably is integrated. Layers, such as CMOS layers may be provided for building the integrated processing circuit. The sensor chip has a front side and a back side, wherein a sensitive layer preferably is arranged at the front side. The sensitive layer may be arranged on top of or integrated in the semiconductor substrate or on top of or integrated in a layer, such as one of the CMOS layers, and preferably on or in a membrane of the sensor chip that spans the cavity. In case an integrated processing circuit is provided in the sensor chip, the sensitive layer may be connected thereto for pre-processing signals from the sensitive layer in the integrated processing circuit.
Specifically, the sensitive layer may contain a metal oxide material, and in particular a semiconducting metal oxide material. A metal oxide material generally may include one or more of tin oxide, zinc oxide, titanium oxide, tungsten oxide, indium oxide and gallium oxide. Such metal oxides may be used for the detection of analytes such as VOCs, carbon monoxide, nitrogen dioxide, methane, ammonia or hydrogen sulphide. Metal oxide sensors are based on the concept that gaseous analytes interact with the metal oxide layer at elevated temperatures of the sensitive layer in the range of more than 100° Celsius, and specifically between 250° C. and 350° Celsius. As a result of the catalytic reaction, the conductivity of the sensitive layer may change which change can be measured. The sensor therefore may be a gas sensor.
In another embodiment, the sensitive layer may comprise a polymer that in one embodiment may be sensitive to H2O such that the sensor may be a humidity sensor. A capacity or a resistance of such polymer layer may be measured for deriving information as to the gas that may interact with the sensitive layer.
In another embodiment, the sensitive layer may comprise temperature sensing means for detecting a flow of a fluid, such as the flow of a gas or the flow of a liquid.
In addition, a heater can be provided, and preferably is arranged on or in the membrane, for supporting a measurement by the sensitive layer and/or for supporting a manufacturing of the sensor package. In one embodiment, the heater is required for heating the sensitive layer prior to and/or during a gas measurement. This may be the case, for example, when the sensitive layer contains metal oxide material. In another embodiment, the heater may alternatively or additionally be used for annealing the sensitive layer after having applied a sensitive material to the sensor chip for building the sensitive layer from. This may be the case when the sensitive layer comprises a polymer, and/or when the sensitive layer is made from a material comprising metal oxide. In a third embodiment, the heater may be used for heating the fluid passing the sensitive layer for generating a gradient in temperature upstream and a downstream of the heater which can be measured by the temperature means.
The membrane may be provided to achieve thermal insulation. In a preferred embodiment, the membrane is manufactured by etching, such as dry-etching or wet-etching, or otherwise removing material from the back side of the sensor chip, such as bulk substrate material, thereby generating a recess in the back side of the sensor chip. The remaining material of the sensor chip above the recess forms the membrane which may consist of CMOS layers and/or parts of the bulk substrate material.
The carrier may have a footprint approximately equal to a footprint of the sensor chip. The through hole in the carrier may be fabricated subject to the material of the carrier and/or the carrier in general, e.g. by etching, piercing, laser drilling, mechanical drilling, etc. Preferably, contact pads are provided for electrically contacting the sensor chip. The contact pads are preferably made from the same material as the carrier in case of being separate from the carrier and in case of being made from metal, and are preferably arranged in the same plane as the carrier. In a different embodiment, the carrier may comprise the contact pads. The contact pads are exposed to the environment as pins for electrical contact. In one embodiment, the contact pads and the carrier represent a lead frame structure. The contact pads may be represented by electrically conducting platforms or leads electrically isolated from each other.
A molding compound may be applied to a lead frame structure/sensor chip combination. The molding compound preferably comprises plastics and preferably is an epoxy with filler particles which filler particles e.g. may be glass. The molding compound at least partially encloses and/or encapsulates the sensor chip. Preferably, an opening is provided in the molding compound for allowing a gas a variable of which is to be measured to access the sensitive layer of the sensor chip. The molding compound encapsulates and as such covers the sensor chip essentially except for the sensitive layer such that any outgassing from the sensor chip itself, from adhesives between the sensor chip and the carrier, or from the carrier itself etc. does not have any impact on the measurement.
In an alternate embodiment, a printed circuit board (PCB) may act as carrier Here, the sensor chip is attached to a front side of the printed circuit board, while the contact pads may be formed by metallizations on a back side of the printed circuit board which additionally requires vias through the printed circuit board for connecting to the contact pads. Instead of a printed circuit board, another carrier such as a ceramic substrate or a glass substrate may be used.
According to a further aspect of the present invention, a method is provided for manufacturing a sensor package. A sensor chip is manufactured with a front side, a back side and a recess in the back side. A through hole is manufactured in a carrier which carrier later on carries the sensor chip. The sensor chip is attached to the carrier with its back side facing the carrier by means of an attachment layer such that the through hole is located in a first area of the carrier the sensor chip rests on. The through hole preferably is covered by the attachment layer. This may in particular be the case if the carrier is attached to the sensor chip by a die attach film as attachment layer. Here, a second area of the carrier which is defined as area facing the recess may also be covered by the attachment layer. In a different embodiment, and preferably if the carrier is attached to the sensor chip by a wafer backside coating as attachment layer, the attachment layer may be structured and therefore only cover the first area excluding the through hole and excluding the second area. Hence, in this embodiment the attachment layer may be understood as having cut-outs for the second area and for the through hole.
Other advantageous embodiments of the gas sensor package are listed in the dependent claims as well as in the description below and shall be considered as embodiments to both the arrangement and the method.
Embodiments of the present invention, aspects and advantages will become apparent from the following detailed description thereof. Such description makes reference to the annexed drawings, wherein the figures show:
In the drawings, same elements are referred to by the same reference signs.
In between two rows of contact pads 12, a carrier in form of a die pad 11 is provided which serves as a support for a sensor chip 2 indicated in dashed lines. The die pad 11 is of rectangular shape and may in a different embodiment have one flattened corner at least on its bottom side, e.g. manufactured by etching half the thickness of the die pad 11, which may serve as an optical and/or mechanical encoding for an orientation of the sensor package. The contact pads 12 and the die pad 11 are mechanically linked by a molding compound 3.
The sensor chip 2 has a recess in its back side referred to by 21 and illustrated by a dashed circle. Given that the sensor chip 2 rests with its back side on the die pad 11, a first area A1 of the die pad 11 is defined as the area the sensor chip 2 actually rests on, i.e. is in contact with the die pad 11 via an attachment layer to be introduced later on. A second area A2 instead is defined as area of the die pad that faces the recess 21 of the sensor chip 2.
A through hole 111 is provided in the die pad 11 which extends through an entire thickness of the die pad 11. The through hole 111 is arranged in the first area A1 of the die pad 11, i.e. where the sensor chip 2 rests on the die pad 11. Its area is referred to by A3 which area A3 resides within the first area A1.
The sensor chip 2 is attached to the die pad 11 by means of an attachment layer. Preferably, the attachment layer is an adhesive film that permanently sticks the sensor chip 2 to the die pad 11. Hence, the attachment layer is arranged between the die pad 11 and the back side of the sensor chip 2. The attachment layer is not explicitly shown in
A distance D1 between the through hole 111 and the recess 21 preferably is less than 250 μm. During operation, a cavity defined by the recess 21 in the sensor chip 2 and the die pad 11 may suffer from elevated pressure, contaminated gas etc. Hence the through hole 111 offers an exit for gas in the cavity. However, the only way to get from the cavity to the through hole 111 is by overcoming the attachment layer between the recess 21 and the through hole 111. The material of the attachment layer and its dimension may be chosen or designed to make this venting channel become more or less resistive to a gas flow.
In the
The shape of a resulting sensor package preferably is defined by the shape of the molding compound which is indicated by a dashed rectangle in
The sensor chip 2 is arranged on the front side FS of the die pad 11, with its back side bs and the recess 21 facing the die pad 11, and is attached thereto by an attachment layer 4. As a result, a cavity 5 is formed inside the sensor package. The through hole 111 connects the cavity 5 via the attachment layer 4 to the outside world. One or more of heat, pressure, contaminants may be transferred in the form of gas from the cavity 5 via the attachment layer 4 to the through hole 111 and escape from there.
The mold compound 3 encapsulates the sensor chip 2 except for an opening 31 towards the sensitive layer 23. In this embodiment, the opening 31 has a circular footprint which narrows towards the sensitive layer 23.
In a different process of manufacturing a sensor package, the step illustrated in diagram 5a) is replaced by a step illustrated in
While above there are shown and described embodiments of the invention, it is to be understood that the invention is not limited thereto but may otherwise be embodied and practiced within the scope of the following claims. In particular, it is emphasized that the method described in the various embodiments may include additional steps added or intermingled with the process steps described without leaving the scope of the method claims.
Number | Date | Country | Kind |
---|---|---|---|
15000074.3 | Jan 2015 | EP | regional |