Tae Hyung Park scite author profile

Issues in the circuitry, integration, and material properties of the two-dimensional (2D) and three-dimensional (3D) crossbar array (CBA)-type resistance switching memories are described. Two important quantitative guidelines for the memory integration are provided with respect to the required numbers of signal wires and sneak current paths. The advantage of 3D CBAs over 2D CBAs (i.e., the decrease in effect memory cell size) can be exploited only under certain limited conditions due to the increased area and layout complexity of the periphery circuits. The sneak current problem can be mitigated by the adoption of different voltage application schemes and various selection devices. These have critical correlations, however, and depend on the involved types of resistance switching memory. The problem is quantitatively dealt with using the generalized equation for the overall resistance of the parasitic current paths. Atomic layer deposition is discussed in detail as the most feasible fabrication process of 3D CBAs because it can provide the device with the necessary conformality and atomic-level accuracy in thickness control. Other subsidiary issues related to the line resistance, maximum available current, and fabrication technologies are also reviewed. Finally, a summary and outlook on various other applications of 3D CBAs are provided.

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Highly Uniform, Electroforming‐Free, and Self‐Rectifying Resistive Memory in the Pt/Ta₂O₅/HfO_2‐x/TiN Structure

Yoon

Song

Yoo

et al. 2014

Adv Funct Materials

222

152

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The development of a resistance switching (RS) memory cell that contains rectifi cation functionality in itself, highly reproducible RS performance, and electroforming-free characteristics is an impending task for the development of resistance switching random access memory. In this work, a two-layered dielectric structure consisting of HfO 2 and Ta 2 O 5 layers, which are in contact with the TiN and Pt electrode, is presented for achieving these tasks simultaneously in one sample confi guration. The HfO 2 layer works as the resistance switching layer by trapping or detrapping of electronic carriers, whereas the Ta 2 O 5 layer remains intact during the whole switching cycle, which provides the rectifi cation. With the optimized structure and operation conditions for the given materials, excellent RS uniformity, electroforming-free, and selfrectifying functionality could be simultaneously achieved from the Pt/Ta 2 O 5 / HfO 2 /TiN structure.

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Nociceptive Memristor

et al. 2018

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The biomimetic characteristics of the memristor as an electronic synapse and neuron have inspired the advent of new information technology in the neuromorphic computing. The application of the memristors can be extended to the artificial nerves on condition of the presence of electronic receptors which can transfer the external stimuli to the internal nerve system. In this work, nociceptor behaviors are demonstrated from the Pt/HfO /TiN memristor for the electronic receptors. The device shows four specific nociceptive behaviors; threshold, relaxation, allodynia, and hyperalgesia, according to the strength, duration, and repetition rate of the external stimuli. Such nociceptive behaviors are attributed to the electron trapping/detrapping to/from the traps in the HfO layer, where the depth of trap energy level is ≈0.7 eV. Also, the built-in potential by the work function mismatch between the Pt and TiN electrodes induces time-dependent relaxation of trapped electrons, providing the appropriate relaxation behavior. The relaxation time can take from several milliseconds to tens of seconds, which corresponds to the time span of the decay of biosignal. The material-wise evaluation of the electronic nociceptor in comparison with other material, which did not show the desired functionality, Pt/Ti/HfO /TiN, reveals the importance of careful material design and fabrication.

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Pt/Ta₂O₅/HfO₂₋_x/Ti Resistive Switching Memory Competing with Multilevel NAND Flash

et al. 2015

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Pt/Ta2 O5 /HfO2- x /Ti resistive switching memory with a new circuit design is presented as a feasible candidate to succeed multilevel-cell (MLC) NAND flash memory. This device has the following characteristics: 3 bit MLC, electroforming-free, self-rectifying, much higher cell resistance than interconnection wire resistance, low voltage operation, low power consumption, long-term reliability, and only an electronic switching mechanism, without an ionic-motion-related mechanism.

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Thickness effect of ultra-thin Ta2O5 resistance switching layer in 28 nm-diameter memory cell

Park

Song

Kim

et al. 2015

Sci Rep

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Resistance switching (RS) devices with ultra-thin Ta2O5 switching layer (0.5–2.0 nm) with a cell diameter of 28 nm were fabricated. The performance of the devices was tested by voltage-driven current—voltage (I-V) sweep and closed-loop pulse switching (CLPS) tests. A Ta layer was placed beneath the Ta2O5 switching layer to act as an oxygen vacancy reservoir. The device with the smallest Ta2O5 thickness (0.5 nm) showed normal switching properties with gradual change in resistance in I-V sweep or CLPS and high reliability. By contrast, other devices with higher Ta2O5 thickness (1.0–2.0 nm) showed abrupt switching with several abnormal behaviours, degraded resistance distribution, especially in high resistance state, and much lower reliability performance. A single conical or hour-glass shaped double conical conducting filament shape was conceived to explain these behavioural differences that depended on the Ta2O5 switching layer thickness. Loss of oxygen via lateral diffusion to the encapsulating Si3N4/SiO2 layer was suggested as the main degradation mechanism for reliability, and a method to improve reliability was also proposed.

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Tae Hyung Park

A Review of Three‐Dimensional Resistive Switching Cross‐Bar Array Memories from the Integration and Materials Property Points of View

Highly Uniform, Electroforming‐Free, and Self‐Rectifying Resistive Memory in the Pt/Ta₂O₅/HfO_2‐x/TiN Structure

Nociceptive Memristor

Pt/Ta₂O₅/HfO₂₋_x/Ti Resistive Switching Memory Competing with Multilevel NAND Flash

Thickness effect of ultra-thin Ta2O5 resistance switching layer in 28 nm-diameter memory cell

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Tae Hyung Park

A Review of Three‐Dimensional Resistive Switching Cross‐Bar Array Memories from the Integration and Materials Property Points of View

Highly Uniform, Electroforming‐Free, and Self‐Rectifying Resistive Memory in the Pt/Ta2O5/HfO2‐x/TiN Structure

Nociceptive Memristor

Pt/Ta2O5/HfO2−x/Ti Resistive Switching Memory Competing with Multilevel NAND Flash

Thickness effect of ultra-thin Ta2O5 resistance switching layer in 28 nm-diameter memory cell

Contact Info

Product

Resources

About

Highly Uniform, Electroforming‐Free, and Self‐Rectifying Resistive Memory in the Pt/Ta₂O₅/HfO_2‐x/TiN Structure

Pt/Ta₂O₅/HfO₂₋_x/Ti Resistive Switching Memory Competing with Multilevel NAND Flash