Class / Patent application number | Description | Number of patent applications / Date published |
257050000 | Non-single crystal, or recrystallized, active junction adapted to be electrically shorted (e.g., "anti-fuse" element) | 6 |
20090152549 | MEMORY DEVICE - A memory device is provided, which includes a memory element including a first electrode, a second electrode, and a silicon layer disposed between the first electrode and the second electrode. The memory element is capable of being in a first state, a second state, and a third state. A first data is written to the memory element being in the first state so that a potential of the first electrode is higher than a potential of the second electrode, whereby the memory element being in the second state is obtained. A second data is written to the memory element being in the first state so that a potential of the second electrode is higher than a potential of the first electrode, whereby the memory element being in the third state is obtained. | 06-18-2009 |
20090179201 | Laser Chalcogenide Phase Change Device - A laser activated phase change device for use in an integrated circuit comprises a chalcogenide fuse configured to connect a first patterned metal line and a second patterned metal line and positioned between an inter layer dielectric and an over fuse dielectric. The fuse interconnects active semiconductor elements manufactured on a substrate. A method for activating the laser activated phase change device includes selecting a laser condition of a laser based on characteristics of the fuse and programming a phase-change of the fuse with the laser by direct photon absorption until a threshold transition temperature is met. | 07-16-2009 |
20090321735 | Electrical Antifuse and Method of Programming - An antifuse having a link including a region of unsilicided semiconductor material may be programmed at reduced voltage and current and with reduced generation of heat by electromigration of metal or silicide from a cathode into the region of unsilicided semiconductor material to form an alloy having reduced bulk resistance. The cathode and anode are preferably shaped to control regions from which and to which material is electrically migrated. After programming, additional electromigration of material can return the antifuse to a high resistance state. The process by which the antifuse is fabricated is completely compatible with fabrication of field effect transistors and the antifuse may be advantageously formed on isolation structures. | 12-31-2009 |
20130270559 | ANTIFUSE ELEMENT UTILIZING NON-PLANAR TOPOLOGY - Techniques for providing non-volatile antifuse memory elements and other antifuse links are disclosed herein. In sonic embodiments, the antifuse memory elements are configured with non-planar topology such as FinFET topology. In some such embodiments, the fin topology can be manipulated and used to effectively promote lower breakdown voltage transistors, by creating enhanced-emission sites which are suitable for use in lower voltage non-volatile antifuse memory elements. In one example embodiment, a semiconductor antifuse device is provided that includes a non-planar diffusion area having a fin configured with a tapered portion, a dielectric isolation layer on the fin including the tapered portion, and a gate material on the dielectric isolation layer. The tapered portion of the fin may be formed, for instance, by oxidation, etching, and/or ablation, and in some cases includes a base region and a thinned region, and the thinned region is at least 50% thinner than the base region. | 10-17-2013 |
20160035735 | ANTIFUSE ELEMENT UTILIZING NON-PLANAR TOPOLOGY - Techniques for providing non-volatile antifuse memory elements and other antifuse links are disclosed herein. In some embodiments, the antifuse memory elements are configured with non-planar topology such as FinFET topology. In some such embodiments, the fin topology can be manipulated and used to effectively promote lower breakdown voltage transistors, by creating enhanced-emission sites which are suitable for use in lower voltage non-volatile antifuse memory elements. In one example embodiment, a semiconductor antifuse device is provided that includes a non-planar diffusion area having a fin configured with a tapered portion, a dielectric isolation layer on the fin including the tapered portion, and a gate material on the dielectric isolation layer. The tapered portion of the fin may be formed, for instance, by oxidation, etching, and/or ablation, and in some cases includes a base region and a thinned region, and the thinned region is at least 50% thinner than the base region. | 02-04-2016 |
20160190145 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - A semiconductor device includes an SOI substrate and an anti-fuse element formed on the SOI substrate. The SOI substrate has a p type well region formed on a main surface side of a support substrate and an SOI layer formed on the p type well region via a BOX layer. The anti-fuse element has a gate electrode formed on the SOI layer via agate insulating film. The anti-fuse element constitutes a storage element, and a first potential is applied to the gate electrode and a second potential of the same polarity as the first potential is applied to the p type well region in a write operation of the storage element. | 06-30-2016 |