Mustafa M. Aziz scite author profile

Phase‐change materials offer a promising route for the practical realisation of new forms of general‐purpose and ‘brain‐like’ computers. An experimental proof‐of‐principle of such remakable capabilities is presented that includes (i) the reliable execution by a phase‐change ‘processor’ of the four basic arithmetic functions of addition, subtraction, multiplication and division, (ii) the demonstration of an ‘integrate and fire’ hardware neuron using a single phase‐change cell and (iii) the expostion of synaptic‐like functionality via the ‘memflector’, an optical analogue of the memristor.

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Terabit-per-square-inch data storage using phase-change media and scanning electrical nanoprobes

Wright

Armand

Aziz

2006

IEEE Trans. Nanotechnology

116

110

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Abstract-A theoretical study of the write, read, and erase processes in electrical scanning probe storage on phase-change media is presented. Electrical, thermal, and phase-transformation mechanisms are considered to produce a physically realistic description of this new approach to ultrahigh-density data storage. Models developed are applied to the design of a suitable storage layer stack with the necessary electrical, thermal, and tribological properties to support recorded bits of nanometric scale. The detailed structure of nanoscale crystalline and amorphous bits is also predicted. For an optimized trilayer stack comprising Ge 2 Sb 2 Te 5 sandwiched by amorphous or diamond-like carbon layers, crystalline bits were roughly trapezoidal in shape while amorphous bits were semi-ellipsoidal. In both cases, the energy required to write individual bits was very low (of the order of a few hundred picoJoules). Amorphous marks could be directly overwritten (erased), but crystalline bits could not. Readout performance was investigated by calculating the readout current as the tip scanned over isolated bits and bit patterns of increasing density. The highest readout contrast was generated by isolated crystalline bits in an amorphous matrix, but the narrowest readout pulses arose from isolated amorphous marks in a crystalline background. To assess the ultimate density capability of electrical probe recording the role of write-induced intersymbol interference and the thermodynamic stability of nanoscale marks were also studied.

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The Design of Rewritable Ultrahigh Density Scanning-Probe Phase-Change Memories

Wright

Wang

Shah

et al. 2011

IEEE Trans. Nanotechnology

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Abstract-A systematic design of practicable media suitable for re-writeable, ultra-high density (> 1Tbit/sq.in.), high data rate (> 1Mbit/s/tip) scanning probe phase-change memories is presented. The basic design requirements were met by a Si/TiN/GST/DLC structure, with properly tailored electrical and thermal conductivities. Various alternatives for providing re-writeability were investigated. In the first case amorphous marks were written into a crystalline starting phase and subsequently erased by re-crystallization, as in other already-established phasechange memory technologies. Results imply that this approach is also appropriate for probe-based memories. However, experimentally the successful writing of amorphous bits using scanning electrical probes has not been widely reported. In light of this a second approach has been studied, that of writing crystalline bits in an amorphous starting matrix, with subsequent erasure by re-amorphization. With conventional phase-change materials, such as continuous films of Ge 2 Sb 2 Te 5 , this approach invariably leads to the formation of a crystalline 'halo' surrounding the erased (re-amorphized) region, with severe adverse consequences on the achievable density. Suppression of the 'halo' was achieved using patterned media or slow-growth phase-change media, with the latter seemingly more viable.

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Switching times and transition widths in digital recording theory

Middleton

Miles²,

Aziz³

2001

IEEE Trans. Magn.

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Crystallization of Ge2Sb2Te5 films by amplified femtosecond optical pulses

Liu

Aziz

Shalini

et al. 2012

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The phase transition between the amorphous and crystalline states of Ge 2 Sb 2 Te 5 has been studied by exposure of thin films to series of 60 femtosecond (fs) amplified laser pulses. The analysis of microscope images of marks of tens of microns in size provide an opportunity to examine the effect of a continuous range of optical fluence. For a fixed number of pulses, the dependence of the area of the crystalline mark upon the fluence is well described by simple algebraic results that provide strong evidence that thermal transport within the sample is one-dimensional (vertical). The crystalline mark area was thus defined by the incident fs laser beam profile rather than by lateral heat diffusion, with a sharp transition between the crystalline and amorphous materials as confirmed from line scans of the microscope images. A simplified, one-dimensional model that accounts for optical absorption, thermal transport and thermally activated crystallization provides values of the optical reflectivity and mark area that are in very good quantitative agreement with the experimental data, further justifying the one-dimensional heat flow assumption. Typically, for fluences below the damage threshold, the crystalline mark has annular shape, with the fluence at the centre of the irradiated mark being sufficient to induce melting. The fluence at the centre of the mark was correlated with the melt depth from the thermal model to correctly predict the observed melt fluence thresholds and to explain the closure and persistence of the annular crystalline marks as functions of laser fluence and pulse number. A solid elliptical mark may be obtained for smaller fluences. The analysis of marks made by amplified fs pulses present a new and effective means of observing the crystallization dynamics of phase-change material at elevated temperatures near the melting point, which provided estimates of the growth velocity in the range 7-9 m/s. Furthermore, finer control over the crystallization process in phase-change media can be obtained by controlling the number of pulses which, along with the laser fluence, can be tailored to any medium stack with relaxed restrictions on the thermal properties of the layers in the stack. V C 2012 American Institute of Physics. [http://dx

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Write strategies for multiterabit per square inch scanned-probe phase-change memories

Wright

Shah

Wang

et al. 2010

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A mark-length write strategy for multiterabit per square inch scanned-probe memories is described that promises to increase the achievable user density by at least 50%, and potentially up to 100% or more, over conventional approaches. The viability of the write strategy has been demonstrated by experimental scanning probe write/read measurements on phase-change (GeSbTe) media. The advantages offered by adopting mark-length recording are likely to be equally applicable to other forms of scanned probe storage.

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Dependence of non-reciprocity in spin wave excitation on antenna configuration

Shibata

Kasahara

Nakayama

et al. 2018

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The dependence of nonreciprocity of excitation of magnetostatic surface waves (MSSW) on antenna width was investigated experimentally and theoretically. The nonreciprocity was successfully modified by changing the excitation antenna width. The nonreciprocity ratio, which was defined as the spin wave intensity under negative bias field divided by that under positive bias field, was found to decrease with increasing antenna width. Micromagnetic simulations revealed that this decrease in the nonreciprocity ratio originates from the rapid decrease in the in-plane excitation field compared to the perpendicular excitation field with reducing the antenna width.

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Phase‐change processors, memristors and memflectors

Wright¹,

Wang²,

Aziz³

et al. 2012

Physica Status Solidi (b)

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Phase‐change materials exhibit some remarkable properties. They can be crystallized in picoseconds and amorphized in femtoseconds, but remain stable against spontaneous crystallization for many years. They exhibit huge differences in optical and electrical properties between the amorphous and crystalline phases. Such properties have led, over the last four decades, to the successful development of both optical and electrical non‐volatile phase‐change memories. However, such binary memories only ‘scratch the surface’ in terms the remarkable potential applications of phase‐change materials and devices, which extend to arithmetic, logical and bio‐inspired (or neuromorphic) processing. In this paper we introduce and explain some of this remarkable functionality inherent to phase‐change systems. Phase‐change device operating in accumulation mode. This provides the basic mechanism for providing arithmetic, logic and neuronal type processing.magnified image

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Mustafa M. Aziz

Arithmetic and Biologically‐Inspired Computing Using Phase‐Change Materials

Terabit-per-square-inch data storage using phase-change media and scanning electrical nanoprobes

The Design of Rewritable Ultrahigh Density Scanning-Probe Phase-Change Memories

Switching times and transition widths in digital recording theory

Crystallization of Ge2Sb2Te5 films by amplified femtosecond optical pulses

Write strategies for multiterabit per square inch scanned-probe phase-change memories

Dependence of non-reciprocity in spin wave excitation on antenna configuration

Phase‐change processors, memristors and memflectors

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