A method for producing a MEMS device comprises fabricating a first semiconductor layer and selectively depositing a second semiconductor layer over the first semiconductor layer, wherein the second semiconductor layer comprises a first part composed of monocrystalline semiconductor material and a second part composed of polycrystalline semiconductor material. The method furthermore comprises structuring at least one of the semiconductor layers, wherein the monocrystalline semiconductor material of the first part and underlying material of the first semiconductor layer form a spring element of the MEMS device and the polycrystalline semiconductor material of the second part and underlying material of the first semiconductor layer form at least one part of a comb drive of the MEMS device.

A mirror device manufacturing method includes a forming step of forming a structure by forming a base portion, a movable portion, and a coupling portion coupling the base portion and the movable portion to each other such that the movable portion is able to swing with respect to the base portion through processing of a wafer, and forming a mirror layer in the movable portion; and a collecting step of performing collection of foreign substances from the structure using a collection member after the forming step. A mirror unit manufacturing method includes a sealing step of sealing the mirror device after the collecting step.

Embodiments of the disclosure provide methods for microfabricating an omni-view peripheral scanning system. One exemplary method may include separately fabricating a reflector and a scanning MEMS mirror, and then bonding the microfabricated reflector with the scanning MEMS mirror to form the omni-view peripheral scanning system. The microfabricated reflector may include a cone-shaped bottom portion, and a via hole across the cone-shaped bottom portion. The microfabricated scanning MEMS mirror may include a MEMS actuation platform and a scanning mirror supported by the MEMS actuation platform. The scanning MEMS mirror may face the cone-shaped bottom portion of the reflector when forming the omni-view peripheral scanning system.

A micromechanical sensor that is produced surface-micromechanically includes at least one mass element formed in a third functional layer that is non-perforated at least in certain portions. The sensor has a gap underneath the mass element that is formed by removal of a second functional layer and at least one oxide layer. The removal of the at least one oxide layer takes place by introducing a gaseous etching medium into a defined number of etching channels arranged substantially parallel to one another. The etching channels are configured to be connected to a vertical access channel in the third functional layer.

A method for producing a MEMS device comprises fabricating a first semiconductor layer and selectively depositing a second semiconductor layer over the first semiconductor layer, wherein the second semiconductor layer comprises a first part composed of monocrystalline semiconductor material and a second part composed of polycrystalline semiconductor material. The method furthermore comprises structuring at least one of the semiconductor layers, wherein the monocrystalline semiconductor material of the first part and underlying material of the first semiconductor layer form a spring element of the MEMS device and the polycrystalline semiconductor material of the second part and underlying material of the first semiconductor layer form at least one part of a comb drive of the MEMS device.

A overhanging device cavity structure comprises a substrate and a cavity disposed in or on the substrate. The cavity comprises a first cavity side wall and a second cavity side wall opposing the first cavity side wall on an opposite side of the cavity from the first cavity side wall. A support extends from the first cavity side wall to the second cavity side wall and at least partially divides the cavity. A device is disposed on, for example in direct contact with, the support and extends from the support into the cavity.

A overhanging device cavity structure comprises a substrate and a cavity disposed in or on the substrate. The cavity comprises a first cavity side wall and a second cavity side wall opposing the first cavity side wall on an opposite side of the cavity from the first cavity side wall. A support extends from the first cavity side wall to the second cavity side wall and at least partially divides the cavity. A device is disposed on, for example in direct contact with, the support and extends from the support into the cavity.

A overhanging device cavity structure comprises a substrate and a cavity disposed in or on the substrate. The cavity comprises a first cavity side wall and a second cavity side wall opposing the first cavity side wall on an opposite side of the cavity from the first cavity side wall. A support extends from the first cavity side wall to the second cavity side wall and at least partially divides the cavity. A device is disposed on, for example in direct contact with, the support and extends from the support into the cavity.

Embodiments of the disclosure provide methods for microfabricating an omni-view peripheral scanning system. One exemplary method may include separately fabricating a reflector and a scanning MEMS mirror, and then bonding the microfabricated reflector with the scanning MEMS mirror to form the omni-view peripheral scanning system. The microfabricated reflector may include a cone-shaped bottom portion, and a via hole across the cone-shaped bottom portion. The microfabricated scanning MEMS mirror may include a MEMS actuation platform and a scanning mirror supported by the MEMS actuation platform. The scanning MEMS mirror may face the cone-shaped bottom portion of the reflector when forming the omni-view peripheral scanning system.

A micromechanical sensor that is produced surface-micromechanically includes at least one mass element formed in a third functional layer that is non-perforated at least in certain portions. The sensor has a gap underneath the mass element that is formed by removal of a second functional layer and at least one oxide layer. The removal of the at least one oxide layer takes place by introducing a gaseous etching medium into a defined number of etching channels arranged substantially parallel to one another. The etching channels are configured to be connected to a vertical access channel in the third functional layer.