Etch stop control for MEMS device formation

A microelectromechanical device is formed in a silicon semiconductor substrate. A metalization layer is formed on a glass wafer. A metal cap layer is then formed on the metalization layer, such that combined layers have a small surface work function that is less than approximately 5.17 eV. The semiconductor substrate is anodically bonded to the glass wafer, and then etched to remove silicon from the structures without significant excess etching of the microelectromechanical device, thus maintaining good control over critical dimensions of the microelectromechanical device.

FIELD OF THE INVENTION

The present invention relates to micro mechanical device formation, and in particular to etch stop control to enhance formation of micro mechanical devices.

BACKGROUND OF THE INVENTION

In the formation of micro mechanical devices, commonly referred to as MEMS devices, silicon or other semiconductor materials are used to form small structures. Semiconductor fabrication techniques are used to form the structures. One such technique is the use of wet chemical etching of the silicon to remove silicon in a controlled manner. Precise control of the etching is required to form critical dimensions required for some of the structures. An “etch stop” is used to achieve this control. One type of etch stop is accomplished by heavily doping a desired portion of the semiconductor with boron, and etching in an anisotropic etchant such as EDP or KOH. When the etchant reaches the heavily doped layer, the etch rate slows down by several orders of magnitude, effectively stopping the etching.

Metal layers are added to MEMS devices prior to etching to provide electrical contact with the silicon. The metal layers provide a good electrical contact but are not attacked by the etchant.

SUMMARY OF THE INVENTION

Electrochemical effects, due to the interaction of the silicon, the metal, and the wet etchant, can result in excess etching the silicon. This excess etching reduces dimensional control. Excess etching of semiconductor material such as silicon in MEMS devices is minimized by using a metalization of the semiconductor material having a small work function. In addition, the metalization is substantially inert to attack from the etchant, such as KOH or EDP.

In one embodiment, the work function of the metalization is smaller than approximately 5.17 eV. Some metals which provide both a small work function and are also resistant to selected etchants include chromium, rhodium, or tungsten. In a further embodiment, the thickness of the metal layer is between approximately 1000-3000 Angstroms.

In further embodiments, the metal layer comprises a layer of a metal having a high work function, capped with a metal having a lower work function. In some embodiments, that work function of the cap is substantially less than 5.17 eV.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1is a cross section of a portion110of a microelectromechanical (MEMS) device, such as an angular rate sensor (i.e., a gyro). In this embodiment, a silicon sensor mechanism115is a rotating or moving part of the sensor. The thickness of the mechanism can be a critical dimension to the proper performance of the sensor. In one embodiment, a less than 1% variation in thickness is a desired tolerance.

In one embodiment, the silicon mechanism is formed in a heavily-boron-doped layer117deposited on or diffused in to a lightly doped substrate, also indicated at115. The silicon mechanism plus substrate115is bonded to a glass substrate120, such as Pyrex, for support. A low work function metal layer125formed on the glass substrate120provides a means for electrical contact with the MEMS device. The silicon substrate115is anodically bonded to the glass substrate120. Once bonded, the lightly doped silicon substrate is etched away using common etchants, such as aqueous solutions of strong bases including KOH or EDP. Etching stops when the lightly doped substrate has etched away and the heavily-boron-doped material is exposed to the etchant. Since the etching stops, the timing of the etching may not be critical. When done properly, the only silicon remaining is the silicon mechanism.

Control of the dimensions of the silicon mechanism115requires a combination of etchant and boron concentration that has a high selectivity (i.e., the ratio of the etch rate in the undoped substrated to the etch rate in the heavily doped layer is very high). Selectivites >103are achieved using EDP as the etchant and a boron concentration >1×1020cm−3.

The metal layer is selected to be resistant to attack by the etchant. Gold and Platinum are examples of metals with excellent resistance to EDP14, however, an electrochemical effect has been discovered that appears to be created by the interaction of the silicon, metal and wet etchant. The electrochemical effect results in excess etching of the silicon as seen in prior artFIG. 2at150and155. Dissimilar materials, such as gold127and silicon115, cause the silicon to etch beyond the etch stop. This etching results in the loss of accurate control of critical dimensions during the dissolved wafer process. Excess silicon is removed from all exposed surfaces of the silicon mechanism.

The numbering inFIG. 2is consistent withFIG. 1for like parts. InFIG. 2, the excess etched silicon is indicated by broken lines at150and155, while the silicon mechanism is still represented as115. The metalization layer is represented at127because it is different than metalization layer125in FIG.1. Metalization127is prior art metalization having a high work function. Unless the etch is stopped at precisely the correct time, excess etching occurs.

To solve the excess, etching problem, the metalization layer125has a work function that is smaller than approximately 5.17 eV. The metalization is still resistant to the etchant. This maximum allowed work function is selected by computing the sum of the silicon bandgap (1.12 eV) and the electron affinity for silicon (4.05 eV). Several metals meet this criterion, such as Rhodium, Chromium, and Tungsten. Further metals, such as Ni and Pd are borderline, having work functions of approximately 5.17 eV. The selected metal, in addition to being resistant to the etchant should also provide a low resistance electrical contact with the silicon mechanism.

In one embodiment, the metal layer is between approximately 1000 to 3000 Angstroms thick. In a further embodiment, the silicon mechanism is etched to serve as a beam, supporting a moving part of the mechanism, such as an oscillating plate, or other sensing mechanism. The thickness control may need to be as small as plus or minus 0.1 microns. The MEMS device, of which the silicon mechanism is a part, may be a gyro, pressure sensor or accelerometer in one embodiment.

In a further embodiment, metal layer125is formed of gold, or some other metal having a work function greater than 5.17 eV, and includes a cap126of a metal layer on top of the gold. The cap126is formed by deposition, and has a work function less than 5.17 eV. Since the cap is in contact with the silicon, the excess etching is eliminated. The cap can be removed in selected areas to provide for better wire bonding. The cap, in one embodiment has a work function below approximately 5.0 eV, is resistant to the etchant, and is a barrier between the gold and silicon during wafer bonding. Cr meets the first two criteria, but may not be a good barrier if subjected to temperatures at or above approximately 250 degrees Celsius. Rhodium meets all criteria. Ti, W, or Mo are also candidates. In addition to gold, high work function metals such as Pt, Pd or Ni are used in conjunction with the lower work function metals being used as a cap. Such combinations of metals should have a surface work function below 5.17 eV. It is understood that while Rhodium, Chromium and Tungsten are preferred candidates; other metals meeting the requirements are also possible.