Package structures, modules containing such packages and methods of manufacture. are described. In an embodiment, a package includes a plurality of terminal pads, a plurality of passive components bonded to top sides of the plurality of terminal pads, a die bonded to top sides of the plurality of passive components and a molding compound encapsulating at least the plurality of passive components and the die.

A semiconductor apparatus with fake functionality includes a logic device and at least one fake device. The logic device is formed on a substrate and turned on by a bias voltage. The fake device is also formed on the substrate. The fake device cannot be turned on by the same bias voltage applied on the logic device.

A memory device includes a semiconductor layer with an in-plane polarization component switchable between a first direction and a second direction. A writing electrode is employed to apply a writing voltage to the semiconductor layer to change the in-plane polarization component between the first direction and the second direction. A reading electrode is employed to apply a reading voltage to the semiconductor layer to measure a tunneling current substantially perpendicular to the polarization direction of the in-plane polarization component. The directions of the reading voltage and the writing voltage are substantially perpendicular to each other. Therefore, the reading process is non-destructive. Thin films (e.g., one unit cell thick) of ferroelectric material can be used in the memory device to increase the miniaturization of the device.

A method of forming a non-volatile memory cell on a substrate having memory cell and logic circuit regions by forming a pair of conductive floating gates in the memory cell region, forming a first source region in the substrate between the pair of floating gates, forming a polysilicon layer in both regions, forming an oxide layer over the polysilicon layer in the logic circuit region, performing a chemical-mechanical polish of the polysilicon layer in the memory cell area leaving a first block of the polysilicon layer between the floating gates that is separated from remaining portions of the polysilicon layer, and selectively etching portions of the polysilicon layer to result in: second and third blocks of the polysilicon layer disposed in outer regions of the memory cell area, and a fourth block of the polysilicon layer in the logic circuit region.

An erasable programmable non-volatile memory includes a first transistor, a second transistor, an erase gate region and a metal layer. The first transistor includes a select gate, a first doped region and a second doped region. The select gate is connected with a word line. The first doped region is connected with a source line. The second transistor includes the second doped region, a third doped region and a floating gate. The third doped region is connected with a bit line. The erase gate region is connected with an erase line. The floating gate is extended over the erase gate region and located near the erase gate region. The metal layer is disposed over the floating gate and connected with the bit line.

A random number generator device has at least at least a memory unit, a voltage generator, and a control circuit. Each memory unit has two memory cells, one of the two memory cells is coupled to a bias line and a first bit line, and another of the two memory cells is coupled to the bias line and a second bit line. The voltage generator provides the two memory cells a bias voltage, a first bit line voltage and a second bit line voltage via the bias line, the first bit line and the second bit line respectively. The control circuit shorts the first bit line and the second bit line to program the two memory cells simultaneously during a programming period and generates a random number bit according the statuses of the two memory cells during a reading period.

An antifuse cell includes an antifuse capacitor that is activatable with a breakdown voltage to provide an electrically conductive path through the capacitor. A pull-up transistor is coupled to the antifuse capacitor. A current path of the pull-up transistor is arranged in parallel with the antifuse capacitor. A shooting transistor is coupled to the pull-up transistor with the current paths of the pull-up transistor and a current path of the shooting transistor cascaded to each other.

A semiconductor structure and a manufacturing method of the same are provided. The semiconductor structure includes a stack structure, an etching stop layer, and a conductive structure. The stack structure includes a plurality of conductive layers and a plurality of insulating layers stacked interlacedly. The etching stop layer is formed on a sidewall of the stack structure. An energy gap of the etching stop layer is larger than 6 eV. The conductive structure is electrically connected to at least one of the conductive layers.

A semiconductor structure is provided. The semiconductor structure includes a substrate, a plurality of first stacked structures and two second stacked structures disposed on the substrate. Each of the first stacked structures includes alternately stacked metal layers and oxide layers. Each of the second stacked structures includes alternately stacked silicon nitride layers and oxide layers. The first stacked structures are disposed between the two second stacked structures.

Various embodiments provide a self-merged profile (SMP) method for fabricating a semiconductor device and a device fabricated using an SMP method. In an example embodiment, a semiconductor device is provided. The example semiconductor device comprises (a) a plurality of conductive lines; (b) a plurality of conductive pads; (c) a plurality of dummy tails; and (d) a plurality of closed loops. Each of the plurality of conductive pads is associated with one of the plurality of conductive lines, one of the plurality of dummy tails, and one of the plurality of closed loops. In example embodiments, the plurality of dummy tails and the plurality of closed loops are formed as residuals of the process used to create the plurality of conductive lines and the plurality of conductive pads.