EP2317533A1 - Capacitive micro-switch comprising a charge drain made up of directed nanotubes on the bottom electrode and method for manufacturing same - Google Patents

Abstract

The micro-switch has an upper metallic membrane (45) and a radio frequency signal line (42) separated by gas or empty thickness. An electrical insulating layer (44) is located on the signal line. A charge drain (43) is constituted of conductor nanotubes e.g. carbon nanotubes, oriented to a surface of the signal line. The drain is surrounded by the electrical insulating layer, where the layer is made of dielectric material. An independent claim is also included for a method for fabricating a micro-switch.

Description

The field of the invention is that of micro-systems components also called MEMS (acronym for Micro Electro Mechanical Systems) and more particularly microswitches radiofrequency or microwave integrating a deformable membrane under the action of an electrostatic field. The main application areas are telecommunications systems and radars.

Micro-system components have been developed for some decades from the technologies implemented for the realization of electronic circuits.

They generally comprise a membrane or a thin metal beam, held suspended by supports above conductive surfaces insulated from each other. A control electrode placed under the conductive surfaces and optionally separated from said conductive surfaces by an insulating layer completes the device.

The membrane-control electrode assembly is subjected to an electrical voltage by means of the control electrode. In the absence of applied voltage, the membrane is suspended above the conductive surfaces and there is no electrical contact therebetween.

In general, one does not use the microswitches MEMS radiofrequency or microwave in simple switch. Indeed, the direct contact between the membrane and the conductive surfaces or the control electrode significantly reduces the service life of the device. A dielectric layer is interposed between the surfaces and the membrane. The simple function is thus transformed into a capacity variation of a capacitor whose armatures consist, on the one hand, of the membrane and, on the other hand, of the control electrode opposite each other. The capacity then varies from a C _up value to a C _down value.

• les techniques de réalisation qui sont dérivées des technologies classiques de fabrication de circuits intégrés électroniques. Elles permettent de simplifier la réalisation et l'intégration et par conséquent, d'obtenir des coûts de fabrication faibles comparés à ceux d'autres technologies, tout en garantissant une fiabilité élevée ;
• les très faibles puissances électriques consommées, quelques microwatts étant nécessaires à l'activation ;
• l'encombrement. On réalise ainsi un micro-commutateur dans une surface de l'ordre du dixième de millimètre carré, permettant d'atteindre une forte capacité d'intégration ;
• les performances hyperfréquence. Ce type de micro-commutateur présente des pertes d'insertion très faibles, de l'ordre du dixième de déciBel, bien inférieures à celles de dispositifs assurant les mêmes fonctions.

The main advantages of this type of device are essentially:

• production techniques that are derived from conventional technologies for manufacturing electronic integrated circuits. They simplify the realization and integration and therefore, to obtain low manufacturing costs compared to other technologies, while ensuring high reliability;
• the very low electric powers consumed, some microwatts being necessary for the activation;
• clutter. A micro-switch is thus produced in a surface of the order of one tenth of a square millimeter, making it possible to achieve a high integration capacity;
• microwave performance. This type of micro-switch has very low insertion losses, of the order of one-tenth of decibel, much lower than those of devices providing the same functions.

In general, the deformable upper membrane is made by depositing one or more layers of materials, at least one of these layers being a conductive material. These materials are those usually used in microelectronics.

A particularly interesting application of these microsystems lies in their use as microwave switches. The operation of this type of switch is particularly illustrated in figure 1, 2 and 3 .

In the initial position, the membrane 11 is at a distance d with respect to an RF line 12, on which a nitride layer 13 is deposited as illustrated in FIG. figure 1 . Assuming that the RF line is also used as an electrode, both ends of the membrane are grounded as illustrated in FIG. figure 2 .

If a potential difference V is applied between the electrode and the membrane, the two parts are brought closer together by drawing the membrane towards the lower electrode (the RF track).

At a value V of the tension, the displacement of the membrane exceeds one third of the initial gap. Thus the membrane collapses on the lower electrode as illustrated in figure 3 . The switch is said to be in the low position and this voltage value is called the activation voltage.

When the membrane is in the up position, illustrated in figure 1 , the RF signal passes into the RF line without being disturbed.

When the membrane is in the low position the signal passes in the RF line and is short-circuited by the membrane which creates a reflection of the EM wave (microwave signal) on the membrane, the signal does not cross the RF MEMS switch.

The actuation used for the RF MEMS switch of the figure 3 is an electrostatic actuation performed by applying a potential between the line (low electrode) and the membrane (high electrode). Other actuations are conceivable such as thermal, piezoelectric, magnetostatic or hybrid actuations (using two or more of the four aforementioned actuations).

The type of contact between the membrane and the line is of the capacitive type on the RF MEMS switch of the figure 3 that is, a dielectric layer was deposited on the low electrode. The line, the dielectric layer, the air gap and the membrane form a variable capacitance making it possible to let the microwave signal pass or block. The second type of possible contact is the ohmic contact (metal-metal) between the membrane and the line.

The center line is covered with a dielectric at the level of the membrane to prevent there being an ohmic contact and therefore a charge circulation when the membrane is in the low state. This gives the advantage of little or no power consumption to keep the membrane low by using the center line as an actuating electrode.

This use is nevertheless not without consequences on the useful life of the dielectric which, as and when the uses and actuations are electrically charged.

Indeed, when the membrane reaches the low state, a conventional capacitive charge effect occurs in the dielectric between the line and the membrane, causing a charge trapping in the dielectric (positive if the electrons are torn off the dielectric, negative if the electrons are trapped in the dielectric).

As the dielectric loads, the performance of the switch is altered. This has the final and irreversible effect of leading to a membrane remaining electrostatically bonded to the dielectric, blocking the RF MEMS Switch to the low state permanently which means the "death" of this RF MEMS switch.

To solve this problem, the present invention proposes a new type of micro-switch comprising a drain of electrical charges inserted at the level of the dielectric layer covering the RF line.

More specifically, the subject of the present invention is a condenser-type electrostatic actuator microswitch composed of two armatures, the first of which is a flexible membrane and the second comprises at least one control electrode, the two armatures being separated by a vacuum thickness. or gas and at least one layer of at least one electrical insulating material located on the control electrode characterized in that it further comprises a charge drain consisting of conducting nanotubes oriented on the surface of said electrode, said drain being covered by said layer of electrical insulating material.

Advantageously, the orientation of the nanotubes is perpendicular to the surface of said electrode.

According to a variant of the invention, the nanotubes are carbon nanotubes.

According to a variant of the invention, the electrical insulating material is a dielectric.

According to a variant of the invention, the dielectric material is of the type Si ₃ N ₄ or Zr0 ₂ or PZT.

According to a variant of the invention, the ratio of the height of the nanotubes to the thickness of the layer of electrical insulating material is close to 0.5.

According to a variant of the invention, the nanotubes are separated from each other by a distance greater than their height, so as to avoid electrical breakdown phenomena.

According to a variant of the invention, the nanotubes are distributed with a pitch of the order of 1 micron, the height of said nanotubes being of the order of 0.1 micron, the thickness of the layer of electrical insulating material being the order of 2 microns.

• la croissance de nanotubes orientés à la surface de l'électrode ;
• le dépôt d'une couche de matériau isolant électrique à la surface de l'électrode recouverte du drain constitué par les nanotubes.

The invention also relates to a method of manufacturing a microswitch according to the invention, characterized in that it comprises

• the growth of nanotubes oriented on the surface of the electrode;
• depositing a layer of electrical insulating material on the surface of the electrode covered with the drain constituted by the nanotubes.

According to a variant of the invention, the growth of nanotubes oriented on the surface of the electrode comprises the growth of nanotubes oriented on the surface of the electrode by growth or catalytic decomposition of hydrocarbons from catalytic particles of the " CVD "for" Chemical Vapor Deposition "or" PECVD "for" Plasma Enhanced Chemical Vapor Deposition ".

• les figures 1, 2 et 3 illustrent le fonctionnement et la structure d'un exemple de MEMS de type micro-commutateur RF selon l'art connu ;
• la figure 4 illustre une vue en coupe détaillée du switch MEMS RF capacitif de type shunt selon l'invention ;
• la figure 5 illustre une vue détaillée du diélectrique sous la membrane du switch MEMS RF comportant un drain de nanotubes de carbone ;
• la figure 6 illustre une étape d'élaboration de drain à partir de la croissance de nanotubes dans un procédé de fabrication d'un micro-commutateur selon l'invention.

The invention will be better understood and other advantages will become apparent on reading my description which will follow given by way of nonlimiting example and thanks to the appended figures among which:

• the Figures 1, 2 and 3 illustrate the operation and structure of an exemplary MEMS RF micro-switch type according to the prior art;
• the figure 4 illustrates a detailed sectional view of the shunt-type capacitive RF MEMS switch according to the invention;
• the figure 5 illustrates a detailed view of the dielectric under the membrane of the RF MEMS switch comprising a carbon nanotube drain;
• the figure 6 illustrates a step of developing a drain from the growth of nanotubes in a method of manufacturing a microswitch according to the invention.

An example of a condenser-type electrostatic actuation microswitch according to the invention is illustrated in FIG. figure 4 .

It comprises, developed on the surface of a substrate 40, an RF signal line 42, on the surface of which is developed the drain based on oriented carbon nanotubes 43 and covered with a layer of dielectric material 44. A metal membrane upper 45 rests on the surface of pillars 41.

Typically, the membrane may be composed of one or two metal layers that may be, for example, a gold layer (Au) or a two-layer aluminum (Al) structure and a titanium-tungsten alloy (TiW) structure. suspended between the two lines of mass.

Typically, the dielectric layer may be a layer of dielectric material, for example ferromagnetic material that can typically be PZT: Pb (Zr _x Ti _1-x ) O ₃ .

While according to the prior art, the signal line is directly covered by the layer of dielectric material, the latter is subjected to electrical discharges when the membrane reaches its low state due to the high voltage required for actuation and the very small distance that results in the end when the membrane touches the dielectric. This causes a loading of the dielectric as it becomes critical when the accumulated charge is sufficient to permanently retain the membrane in the low state.

Thus, the invention proposes a solution consisting in producing capacitive RF MEMS switches whose dielectric layer consists of two elements: a vertical oriented carbon nanotube forest on which the normally used dielectric layer is deposited for the realization capacitive MEMS switch.

This allows a consequent reduction in the loading of the dielectric by creating conduction paths discharging the surplus or filling the electron deficiencies directly resulting in an increase in the lifetime of the capacitive RF MEMS switch, significantly.

Furthermore, the mesh of nanotubes is transparent to the operation of the capacitive RF MEMS switch and therefore does not constitute a disruption to the performance of the latter.

More precisely, the dielectric layer thus separated in two by an intermediate deposition of nano-structured compounds makes it possible to obtain a conductive middle layer allowing the supply or the evacuation of charge carriers inside the dielectric to avoid that the latter does not charge during the operation of the RF MEMS switch.

This has the effect of increasing the cycle life of these RF MEMS switches.

It is known in detail that the charges of the upper part of the dielectric are rapidly trapped but very slowly released unlike that of the lower part of the dielectric in contact with a metal layer.

The figure 5 illustrates in more detail the assembly constituted by the drain of nanotubes and dielectric and schematized by arrows the mobility of the charges along the nanotubes.

The interest of integrating nanotubes into the dielectric and being able to "drain" these charges from the upper part of the dielectric to the lower part in contact with a metal surface. This makes it possible to release the charges thus imprisoned more easily and thus to increase the lifespan of the switches.

The conductivity induced by the presence of these nanotubes remains negligible and does not disturb the operation of RF MEMS switches.

The figure 6 illustrates in more detail, the nanotube growth operation at the surface of the RF line consisting of a metal line. It may advantageously be a conventional operation of growth in an electric field from catalytic elements 43c distributed relative to each other on the surface of the lower electrode 42, and put under a hydrocarbon plasma generate the growth of oriented nanotubes 43.

Claims (9)

Electrostatic actuator microswitch of capacitor type composed of two armatures, the first of which is a flexible membrane (45) and the second comprises at least one control electrode (42), the two armatures being separated by a thickness of vacuum or gas and at least one layer of at least one electrical insulating material (44) located on the control electrode characterized in that it further comprises a charge drain (43) consisting of conducting nanotubes oriented on the surface of said electrode said drain being coated by said layer of electrical insulating material. An electrostatic actuation microswitch according to claim 1, characterized in that the nanotubes are carbon nanotubes. An electrostatic actuation microswitch according to one of claims 1 or 2, characterized in that the electrical insulating material is a dielectric material. An electrostatic actuation microswitch according to claim 3, characterized in that the dielectric material is of the type Si ₃ N ₄ or Zr0 ₂ or PZT. Micro-switch according to one of claims 1 or 2, characterized in that the ratio of the height of the nanotubes on the thickness of the layer of electrical insulating material is close to 0.5. Electrostatic actuation microswitch according to one of claims 1 to 5, characterized in that the nanotubes are separated from each other by a distance greater than their height, so as to avoid electrical breakdown phenomena. Micro-switch according to claim 6, characterized in that the nanotubes are distributed with a pitch of the order of 1 micron, the height of said nanotubes being of the order of 0.1 micron, the thickness of the layer of insulating material being of the order of 2 microns. Method for manufacturing a microswitch according to one of Claims 1 to 7, characterized in that it comprises the growth of nanotubes oriented on the surface of the electrode; depositing a layer of electrical insulating material on the surface of the electrode covered with the drain constituted by the nanotubes. A method of manufacturing a microswitch according to claim 8, characterized in that the growth of nanotubes oriented at the surface of the electrode comprises growth by catalytic decomposition of hydrocarbons from catalytic particles.

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