The present disclosure generally relates to a MEMS DVC utilizing one or more MIM capacitors located in the anchor of the DVC and an Ohmic contact located on the RF-electrode. The MIM capacitor in combination with the ohmic MEMS device ensures that a stable capacitance for the MEMS DVC is achieved with applied RF power.

An electrical contact system includes a first contact, a first diffusion layer disposed on the first contact, a first liquid metal layer disposed on the first diffusion layer, a second contact, a second diffusion layer disposed on the second contact, and a second liquid metal layer disposed on the second diffusion layer.

Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are provided. The method of forming a MEMS structure includes forming fixed actuator electrodes and a contact point on a substrate. The method further includes forming a MEMS beam over the fixed actuator electrodes and the contact point. The method further includes forming an array of actuator electrodes in alignment with portions of the fixed actuator electrodes, which are sized and dimensioned to prevent the MEMS beam from collapsing on the fixed actuator electrodes after repeating cycling. The array of actuator electrodes are formed in direct contact with at least one of an underside of the MEMS beam and a surface of the fixed actuator electrodes.

The present application discloses a method for forming electrical contacts on a semiconductor substrate. The method includes forming a first metal layer over the substrate, and forming a layer of a second metal oxide by sputter deposition of a second metal in an oxygen environment.

The present disclosure generally relates to a MEMS DVC utilizing one or more MIM capacitors located in the anchor of the DVC and an Ohmic contact located on the RF-electrode. The MIM capacitor in combination with the ohmic MEMS device ensures that a stable capacitance for the MEMS DVC is achieved with applied RF power.

In order, for example, to improve the ohmic contact between two metal pieces located at a metallization level, these two metal pieces are equipped with two offset vias located at the metallization level and at least partially at the via level immediately above. Each offset via comprises, for example, a nonoxidizable or substantially nonoxidizable compound, such as a barrier layer of Ti/TiN.

In order, for example, to improve the ohmic contact between two metal pieces located at a metallization level, these two metal pieces are equipped with two offset vias located at the metallization level and at least partially at the via level immediately above. Each offset via comprises, for example, a nonoxidizable or substantially nonoxidizable compound, such as a barrier layer of Ti/TiN.

A MEMS switch that includes a substrate with a first insulating layer and a silicon layer thereabove, a fixed portion and a movable switching portion being formed in the silicon layer. A first metal layer is situated in recesses in the silicon layer at a side of the silicon layer facing away from the substrate, the first metal layer forming at least one switchable electrical contact between the fixed portion and the switching portion. A method for manufacturing a MEMS switch including at least one embedded metal contact is also described.

In order, for example, to improve the ohmic contact between two metal pieces located at a metallization level, these two metal pieces are equipped with two offset vias located at the metallization level and at least partially at the via level immediately above. Each offset via comprises, for example, a nonoxidizable or substantially nonoxidizable compound, such as a barrier layer of Ti/TiN.

Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are provided. The method of forming a MEMS structure includes forming fixed actuator electrodes and a contact point on a substrate. The method further includes forming a MEMS beam over the fixed actuator electrodes and the contact point. The method further includes forming an array of actuator electrodes in alignment with portions of the fixed actuator electrodes, which are sized and dimensioned to prevent the MEMS beam from collapsing on the fixed actuator electrodes after repeating cycling. The array of actuator electrodes are formed in direct contact with at least one of an underside of the MEMS beam and a surface of the fixed actuator electrodes.