Abstract: A memory device and fabricating method thereof. In the memory device of the present invention, a substrate has a plurality of deep trenches, wherein the deep trenches formed in the adjacent rows are staggered. A deep trench capacitor and a control gate are disposed in each deep trench successively. Word lines are disposed on the control gates respectively, and each word line is electrically coupled to the control gate thereunder. Diffusion regions are disposed in the substrate and surrounding the deep trenches respectively to serve as sources of vertical transistors. Each diffusion region is electrically connected to the surrounding deep trench capacitor. Active areas are disposed on the rows of the control gates respectively along a second direction. The regions where each active area overlaps the control gates have at least one indentation.

Abstract: Method for detecting whether the alignment of bit line contacts and active areas in DRAM devices is normal, and a test device thereof. In the present invention a plurality of memory cells are formed in the memory area and at least one test device is formed in the scribe line region simultaneously. A first resistance and a second resistance are detected by the test device. Normal alignment of the bit line and the bar-type active area of the test device is determined according to the first resistance and the second resistance. Finally, whether the alignment of the bit line contacts and the active areas in memory areas is normal is determined according to whether the alignment of the bit line contact and bar-type active area of the test device is normal.

Abstract: Method for detecting whether the alignment of bit line contacts and active areas in DRAM devices is normal, and a test device thereof. In the present invention a plurality of memory cells are formed in the memory area and at least one test device is formed in the scribe line region simultaneously. A first resistance and a second resistance are detected by the test device. Normal alignment of the bit line and the bar-type active area of the test device is determined according to the first resistance and the second resistance. Finally, whether the alignment of the bit line contacts and the active areas in memory areas is normal is determined according to whether the alignment of the bit line contact and bar-type active area of the test device is normal.

Abstract: A test structure and a test method for determining misalignment occurring in integrated circuit manufacturing processes are provided. The test structure includes a first conductive layer having a first testing structure and a second testing structure, a dielectric layer thereon, and a second conductive layer on the dielectric layer. The second conductive layer includes a third testing structure and a fourth testing structure, which respectively overlap a portion of the first testing structure and the second testing structure in a first direction and a second direction. The first direction is opposite to the second direction. The method includes a step of measuring the electrical characteristic between the first and the second conductive layers to calculate an offset amount caused by the misalignment.

Abstract: A memory device and fabricating method thereof. In the memory device of the present invention, a substrate has a plurality of deep trenches, wherein the deep trenches formed in the adjacent rows are staggered. A deep trench capacitor and a control gate are disposed in each deep trench successively. Word lines are disposed on the control gates respectively, and each word line is electrically coupled to the control gate thereunder. Diffusion regions are disposed in the substrate and surrounding the deep trenches respectively to serve as sources of vertical transistors. Each diffusion region is electrically connected to the surrounding deep trench capacitor. Active areas are disposed on the rows of the control gates respectively along a second direction. The regions where each active area overlaps the control gates have at least one indentation.

Abstract: A test device and method for detecting alignment of active areas and memory cell structures in DRAM devices with vertical transistors. In the test device, parallel first and second memory cell structures disposed in the scribe line region, each has a deep trench capacitor and a transistor structure. An active area is disposed between the first and second memory cell structures. The active area overlaps the first and second memory cell structures by a predetermined width. First and second conductive pads are disposed on both ends of the first memory cell structures respectively, and third and fourth conductive pads are disposed on both ends of the first memory cell structures respectively.

Abstract: A test device and method for detecting alignment of word lines and deep trench capacitors in DRAM devices with vertical transistors. In the test device, an active area is disposed in the scribe line region. An H-type deep trench capacitor is disposed in the active area, and has parallel first and second portions and a third portion. Each of the first and second portions has a center and two ends. The third portion is disposed between the centers of the first and second portions. First to fourth conductive pads are disposed on the two ends of the first and second portions respectively. A bar-type conductive pad is disposed between the first and second portions, having a center aligned with a center of the third portion.

Abstract: Method for detecting whether the alignment of bit line contacts and active areas in DRAM devices is normal, and a test device thereof. In the present invention a plurality of memory cells are formed in the memory area and at least one test device is formed in the scribe line region simultaneously. A first resistance and a second resistance are detected by the test device. Normal alignment of the bit line and the bar-type active area of the test device is determined according to the first resistance and the second resistance. Finally, whether the alignment of the bit line contacts and the active areas in memory areas is normal is determined according to whether the alignment of the bit line contact and bar-type active area of the test device is normal.