Abstract: A MEMS IR sensor, with a cavity in a substrate underlapping an overlying layer and a temperature sensing component disposed in the overlying layer over the cavity, may be formed by forming an IR-absorbing sealing layer on the overlying layer so as to cover access holes to the cavity. The sealing layer is may include a photosensitive material, and the sealing layer may be patterned using a photolithographic process to form an IR-absorbing seal. Alternately, the sealing layer may be patterned using a mask and etch process to form the IR-absorbing seal.

Abstract: A method of etching a metal containing layer including a metal including material includes providing a substrate including a top semiconductor surface having the metal containing layer thereon. A photoresist pattern is formed from a photoresist layer on the metal containing layer including forming sloped edge regions of the photoresist layer, wherein the sloped edge regions have an average angle over a full length of the sloped edge regions of from ten (10) to fifty (50) degrees. The metal containing layer is dry etched using the photoresist pattern, wherein the sloped edge regions of the photoresist layer reduce deposition and growth of an etch byproduct including the metal including material into sidewalls of the photoresist layer (metal/polymer sidewall defect) as compared to a conventional vertical (or near-vertical) edge of the photoresist layer.

Abstract: A MEMS device having a device cavity in a substrate has a cavity etch monitor proximate to the device cavity. An overlying layer including dielectric material is formed over the substrate. A monitor scale is formed in or on the overlying layer. Access holes are etched through the overlying layer and a cavity etch process forms the device cavity and a monitor cavity. The monitor scale is located over a lateral edge of the monitor cavity. The cavity etch monitor includes the monitor scale and monitor cavity, which allows visual measurement of a lateral width of the monitor cavity; the lateral dimensions of the monitor cavity being related to lateral dimensions of the device cavity.

Abstract: A process of forming a MEMS device with a device cavity underlapping an overlying dielectric layer stack having an etchable sublayer over an etch-resistant lower portion, including: etching through at least the etchable sublayer of the overlying dielectric layer stack in an access hole to expose a lateral face of the etchable sublayer, covering exposed surfaces of the etchable sublayer by protective material, and subsequently performing a cavity etch. A cavity etch mask may cover the exposed surfaces of the etchable sublayer. Alternatively, protective sidewalls may be formed by an etchback process to cover the exposed surfaces of the etchable sublayer. Alternatively, the exposed lateral face of the etchable sublayer may be recessed by an isotropic etch, than isolated by a reflow operation which causes edges of an access hole etch mask to drop and cover the exposed lateral face of the etchable sublayer.

Abstract: A MEMS IR sensor, with a cavity in a substrate underlapping an overlying layer and a temperature sensing component disposed in the overlying layer over the cavity, may be formed by forming an IR-absorbing sealing layer on the overlying layer so as to cover access holes to the cavity. The sealing layer is may include a photosensitive material, and the sealing layer may be patterned using a photolithographic process to form an IR-absorbing seal. Alternately, the sealing layer may be patterned using a mask and etch process to form the IR-absorbing seal.

Abstract: A MEMS device having a device cavity in a substrate has a cavity etch monitor proximate to the device cavity. An overlying layer including dielectric material is formed over the substrate. A monitor scale is formed in or on the overlying layer. Access holes are etched through the overlying layer and a cavity etch process forms the device cavity and a monitor cavity. The monitor scale is located over a lateral edge of the monitor cavity. The cavity etch monitor includes the monitor scale and monitor cavity, which allows visual measurement of a lateral width of the monitor cavity; the lateral dimensions of the monitor cavity being related to lateral dimensions of the device cavity.

Abstract: A process of forming a MEMS device with a device cavity underlapping an overlying dielectric layer stack having an etchable sublayer over an etch-resistant lower portion, including: etching through at least the etchable sublayer of the overlying dielectric layer stack in an access hole to expose a lateral face of the etchable sublayer, covering exposed surfaces of the etchable sublayer by protective material, and subsequently performing a cavity etch. A cavity etch mask may cover the exposed surfaces of the etchable sublayer. Alternatively, protective sidewalls may be formed by an etchback process to cover the exposed surfaces of the etchable sublayer. Alternatively, the exposed lateral face of the etchable sublayer may be recessed by an isotropic etch, than isolated by a reflow operation which causes edges of an access hole etch mask to drop and cover the exposed lateral face of the etchable sublayer.