Provided is a semiconductor device that can detect the cracking progress with high precision. A semiconductor device is formed using a semiconductor substrate, and includes an active region in which a semiconductor element is formed, and an edge termination region outside the active region. A crack detection structure is termed in the edge termination region of the semiconductor substrate. The crack detection structure includes: a trench formed in the semiconductor substrate and extending in a circumferential direction of the edge termination region; an inner-wall insulating film formed on an inner wall of the trench; an embedded electrode formed on the inner-wall insulating film and embedded into the trench; and a monitor electrode formed on the semiconductor substrate and connected to the embedded electrode.

A control unit of a processing apparatus detects a linear region corresponding to a first planned dividing line from an intersection region of the first planned dividing line and a second planned dividing line, obtains an angle between the linear region and an X-axis direction, and positions the linear region corresponding to the first planned dividing line in the X-axis direction. A linear region corresponding to a next first planned dividing line is detected and an interval between the first planned dividing lines is set. A second planned dividing line interval setting section detects two linear regions corresponding to second planned dividing lines, the linear regions being adjacent to each other, and an interval is set between the second planned dividing lines. A device image enclosed by a pair of first planned dividing lines and a pair of second planned dividing lines is generated and stored.

The present disclosure provides a method for preparing a semiconductor device. The semiconductor device includes a substrate, a first region, a second region, a third region, a fourth region, a fifth region and a sixth region. The first type region is disposed on the substrate and has a ring structure. The second type region is disposed on the substrate and disposed in the center of the first type region. A plurality of second well regions are formed in the first region, the second region, the fourth region, the fifth region and the sixth region. A plurality of second well regions in the first region, the second region, the fourth region, the fifth region and the sixth region. The first well region, the second well region, the first type region and the second type region are formed by ion implantation.

An integrated circuit (IC) includes semiconductor substrate with a metal stack including a lower, upper and a top metal layer that includes bond pads and a detection bond pad (DBP). A wirebond damage detector (WDD) includes the DBP over a first and second connected structure. The first and second connected structures both include spaced apart top segments of the upper metal layer coupled to spaced apart bottom segments of the lower metal layer. The DBP is coupled to one end of the first connected structure, and ≥1 metal trace is coupled to another end extending beyond the DBP to a first test pad. The second connected structure includes metal traces coupled to respective ends each extending beyond the DBP to a second test pad and to a third test pad.

A semiconductor structure and a method of manufacturing a semiconductor structure are provided. The method includes forming a conductive layer on a precursor memory structure, in which the precursor memory structure includes a plurality of transistors and a plurality of contact plugs disposed on and connected to the transistors. The conductive layer in a TEG region is then patterned to form a first patterned conductive layer on the precursor memory structure. The first patterned conductive layer is then patterned to form a plurality of first landing pads extending along a first direction, in which the first landing pads are separated from each other in a second direction that is different from the first direction and are electrically connected to each other through the contact plugs and the transistors.

Test line structures are provided. A test line structure includes a semiconductor substrate, a plurality of diagnosis units and a plurality of first micro pad units. The diagnosis units are formed over the semiconductor substrate. Each of the diagnosis units includes a first interconnect structure having a first routing pattern. The first interconnect structures of the diagnosis units are connected in series to form a first test chain through the first micro pad units, and each of the first micro pad units is configured to connect the first interconnect structures of two adjacent diagnosis units in the first test chain. The first routing patterns of the first interconnect structures in the diagnosis units are different.

A semiconductor structure including a semiconductor base and a test element group is provided. The test element group includes a first metal layer, a second metal layer, and a through-silicon via. The first metal layer is located on the semiconductor base. Reserved space running through the first metal layer is formed on the first metal layer. The second metal layer is located above the first metal layer and is spaced away from the first metal layer. The through-silicon via is located inside the semiconductor base and runs through the reserved space, and the through-silicon via is connected to the second metal layer. The cross-sectional area of the through-silicon via is less than the cross-sectional area of the reserved space, so that the through-silicon via is spaced away from the first metal layer.

Thermal monitors comprising a substrate with at least one camera position on a bottom surface thereof, a wireless communication controller and a battery. The camera has a field of view sufficient to produce an image of at least a portion of a wafer support, the image representative of the temperature within the field of view. Methods of using the thermal monitors are also described.

A semiconductor test device for measuring a contact resistance includes: first fin structures, upper portions of the first fin structures protruding from an isolation insulating layer; epitaxial layers formed on the upper portions of the first fin structures, respectively; first conductive layers formed on the epitaxial layers, respectively; a first contact layer disposed on the first conductive layers at a first point; a second contact layer disposed on the first conductive layers at a second point apart from the first point; a first pad coupled to the first contact layer via a first wiring; and a second pad coupled to the second contact layer via a second wiring. The semiconductor test device is configured to measure the contact resistance between the first contact layer and the first fin structures by applying a current between the first pad and the second pad.

Semiconductor structures and methods of testing the same are provided. A semiconductor structure according to the present disclosure includes a substrate, a semiconductor device over the substrate, wherein the semiconductor device includes an interconnect structure, and the interconnect structure includes a plurality of metallization layers disposed in a dielectric layer; and a delamination sensor. The delamination sensor includes a connecting structure and a plurality of contact vias in at least one of the plurality of metallization layers. The connecting structure bonds the semiconductor device to the substrate and does not functionally couple the semiconductor device to the substrate. The plurality of contact vias fall within a first region of a vertical projection area of the connecting structure but do not overlap a second region of the vertical projection area.