Sidi Gong scite author profile

Journal of Nanomaterials

Gong

Wen

et al. 2016

Scanning probe phase-change memory (SPPCM) has been widely considered as one of the most promising candidates for next-generation data storage devices due to its fast switching time, low power consumption, and potential for ultra-high density. Development of a comprehensive model able to accurately describe all the physical processes involved in SPPCM operations is therefore vital to provide researchers with an effective route for device optimization. In this paper, we introduce a pseudo-three-dimensional model to simulate the electrothermal and phase-transition phenomena observed during the SPPCM writing process by simultaneously solving Laplace’s equation to model the electrical process, the classical heat transfer equation, and a rate equation to model phase transitions. The crystalline bit region of a typical probe system and the resulting current-voltage curve obtained from simulations of the writing process showed good agreement with experimental results obtained under an equivalent configuration, demonstrating the validity of the proposed model.

Towards low energy consumption data storage era using phase-change probe memory with TiN bottom electrode

Gong

Yang

et al. 2016

Phase-change probe memory has been extensively regarded as one of the most prospective candidates to satisfy the recording density requirement from the incoming age of big data.However, in spite of recent advances, the energy consumption of phase-change probe memory still remains fairly high due to the use of the diamond-like carbon bottom electrode usually having a relatively high electric resistivity. In this case, the possibility of using titanium nitride to replace the diamond-like carbon as the electrode materials is investigated in this paper. The thickness and time dependent resisitivity of titanium nitride film is measured, allowing for a more conductive characteristic and a better stability than diamond-like carbon film at the same condition. Consequently, the writing of crystalline bit using the previously designed phase-change probe memory architecture but with titanium nitride bottom electrode is performed experimentally, and results show that using titanium nitride as bottom electrode would enable an achievement of ultra-high recording density with lower energy consumption than the phase-change stack with diamond-like carbon electrode.

Towards low energy consumption data storage era using phase-change probe memory with TiN bottom electrode

Wang¹,

Gong²,

Yang³

et al. 2017

Electrical resistivity optimization of diamond-like carbon thin film for electrical probe storage application

Gong

Yang

et al. 2016

Translation of the Bible or any other text unavoidably involves a determination about its meaning. There have been different views of meaning from ancient times up to the present, and a particularly Enlightenment and Modernist view is that the meaning of a text amounts to whatever the original author of the text intended it to be. This article analyzes the authorial-intent view of meaning in comparison with other models of literary and legal interpretation. Texts are anchors to interpretation but are subject to individualized interpretations. It is texts that are translated, not intentions. The challenge to the translator is to negotiate the meaning of a text and try to choose the most salient and appropriate interpretation as a basis for bringing the text to a new audience through translation.

The Experimental Demonstration of the Optimized Electrical Probe Memory for Ultra-High Density Recording

Gong²,

Yang³

et al. 2017

NANOTEC

An optimized electrical probe memory structure that includes a DLC capping layer and TiN under layer was previously proposed according to a parametric approach, while the practicality of realizing such a media stack experimentally has not bee investigated. In order to assess its practical feasibility, we first measured the electrical resistivities of DLC and TiN films for different thicknesses. In this case, for the purpose of optimizing the memory system with appropriate, but more physically realistic properties values, we re-designed the architecture using the measured properties, and the modified system is able to provide ultra-high density, large data rate, and low energy consumption.