A method for locally removing/modifying a polymer material on a surface of a wafer. The method includes: a) aligning a mask with respect to the surface; b) locally exposing the surface through the mask using a VUV light source while simultaneously supplying a gas mixture containing at least oxygen; c) purging the surface with a gas mixture containing at least nitrogen and oxygen, the VUV light source being switched off; and d) repeating at least steps b) and c) until the removal/modification is complete. A device is described for locally removing/modifying a polymer material on a surface of a wafer, including a mask. The device includes an adjustable wafer table for holding the wafer, and is configured to set an exposure gap between the wafer and the mask in a first operating state, and to set a purge gap between the wafer and the mask in a second operating state.

Provided are a method for preparing a silicon wafer with a rough surface and a silicon wafer, for solving the problem that a viscous force is likely to be generated when a smooth surface of the silicon wafer approaches another film layer. The method includes: depositing a porous oxide film layer on a surface of the first silicon planar layer that has been subjected to planar planarization, and then etching the porous oxide film layer by XeF.sub.2 vapor etching, during which XeF.sub.2 gas passes through the porous oxide film layer to etch the first silicon planar layer in an irregular way. Therefore, the first silicon planar layer has a greater surface roughness. When the silicon wafer approaches to another film layer, the viscous force generated therebetween is reduced, improving the sensitivity of the MEMS device and reducing the probability of out-of-work MEMS devices.

Provided are a method for preparing a silicon wafer with a rough surface and a silicon wafer, which solves the problem in the prior art that viscous force is likely to be generated. The method includes: depositing a first film layer having a large surface roughness on a surface of a silicon wafer that has been subjected to planar planarization, and then blanket etching the first film layer to remove the first film layer. Then, the surface of the first silicon layer facing away from the substrate is further etched to form grooves and protrusions, which provide roughness, thereby forming a silicon wafer with a rough surface. When the silicon wafer approaches to another film layer, the viscous force generated therebetween is reduced, and thus the sensitivity of the MEMS device is improved and the probability of out-of-work MEMS device is reduced.

Provided are a method for preparing a silicon wafer with a rough surface and a silicon wafer, which solves the problem in the prior art that viscous force is likely to be generated. The method includes: depositing a first film layer having a large surface roughness on a surface of a silicon wafer that has been subjected to planar planarization, and then blanket etching the first film layer to remove the first film layer. Then, the surface of the first silicon layer facing away from the substrate is further etched to form grooves and protrusions, which provide roughness, thereby forming a silicon wafer with a rough surface. When the silicon wafer approaches to another film layer, the viscous force generated therebetween is reduced, and thus the sensitivity of the MEMS device is improved and the probability of out-of-work MEMS device is reduced.

Capped microelectromechanical systems (MEMS) devices are described. In at least some situations, the MEMS device includes one or more masses which move. The cap may include a stopper which damps motion of the one or more movable masses. In at least some situations, the stopper damps motion of one of the masses but not another mass.

Capped microelectromechanical systems (MEMS) devices are described. In at least some situations, the MEMS device includes one or more masses which move. The cap may include a stopper which damps motion of the one or more movable masses. In at least some situations, the stopper damps motion of one of the masses but not another mass.

Capped microelectromechanical systems (MEMS) devices are described. In at least some situations, the MEMS device includes one or more masses which move. The cap may include a stopper which damps motion of the one or more movable masses. In at least some situations, the stopper damps motion of one of the masses but not another mass.

Capped microelectromechanical systems (MEMS) devices are described. In at least some situations, the MEMS device includes one or more masses which move. The cap may include a stopper which damps motion of the one or more movable masses. In at least some situations, the stopper damps motion of one of the masses but not another mass.