Quantum dot cellular automata: A new paradigm for digital design

Bilal, Bisma; Ahmed, Suhaib; Kakkar, Vipan

doi:10.56053/3.1.33

Cited by 10 publications

(12 citation statements)

References 32 publications

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“…They used these nanobelts as photoconductors. Fu et al also used Au as catalyst to grow CdS nanowires by using a thermal evaporation method [6]. Figure 3 shows the CdS nanowires that were grown by the VLS process by this group.…”

Section: Resultsmentioning

confidence: 99%

Structural properties of chalcogenides nanostructures

Arumugam

Chaudhry

2023

Theo. NANOTECHNOLOGY

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In Metal chalcogenide hierarchical nanostructures as energy conversion devices were studied in this chapter. Cd-chalcogenide nanostructures were chosen as sample study due to their unique properties as energy converter. In the first step, different methods were introduced to grow this type of nanostructures. It was discussed three low cost-effective methods to grow the Cd-chalcogenide nanostructures such as thermal evaporation (chemical and physical vapor depositions), chemical bath deposition, and electrochemical methods. However, it was observed that samples were grown by a pulsed laser deposition method as a complex method. In addition, effects of growth conditions on morphology and optical properties of the nanostructures were investigated. In the second step, the fundamentals of solar energy conversion were described. Furthermore, quantum physics of semi- conductor solar cells was studied. Finally, the Cd-chalcogenide nanostructures were introduced as solar energy conversion and important factors that can affect the efficiency of this type of solar cells were introduced.

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Section: Resultsmentioning

confidence: 99%

Structural properties of chalcogenides nanostructures

Arumugam

Chaudhry

2023

Theo. NANOTECHNOLOGY

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“…A cell's polarity is determined by its adjacent cells. QCA has four clock zones for proper routing of information: zones 0-3 having a phase difference of 90°as shown in Figure 1(b) [36][37][38]. The binary wires are needed to have crossovers during the design of complicated circuits to reduce the complexity of the circuits.…”

Section: Qca Basicsmentioning

confidence: 99%

Design of efficient N‐bit shift register using optimized D flip flop in quantum dot cellular automata technology

Yaqoob

Ahmed

Naz

et al. 2021

IET Quantum Communication

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There is a need for secure and powerful nano communication systems with ultra-low power consumption in the new digital age. Quantum-dot cellular automata (QCA) is a technology which can be used for designing these systems. In the nano regime, relative to complementary metal oxide semiconductor technology, QCA is able to work with greater speed and lower power dissipation along with high density. This study examines the applicability and viability of using QCA to construct the sequential circuits. An optimized D flip flop is designed in QCA. The fault tolerance for single cell omission and single cell addition defects of the proposed flip flop is also presented. This flip flop is then used to design 2-, 3-, 4-and 8-bit shift registers which can be efficiently scaled up to N-bits. The operations of all proposed designs are validated using QCADesigner tool and the energy dissipation analysis is done using QCAPro tool. The performance comparison shows that the proposed QCA designs are cost efficient and they can be utilized efficiently in designing digital communication systems which require small area along with high speed and ultra-low power consumption.This is an open access article under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.

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“…And its synthesis, assembly and the particles morphology control have received great attention all the time. A number of methods have been developed to synthesize the CdS nanomaterials such as hydrothermal-solvethermal methods [2,4], SBA-15 templates [5], sol-gel methods [6], singlesource molecular precursors methods [7], polymethylmethacrylate matrix methods [8], porous alumina template [9], etc. However, so far there has been no report on the synthesis of CdS nanomaterials through living bio-membrane bi-template.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of CdS nanotubes and nanospheres by living bio-membrane bi-template

Sunagai¹,

Hiro²

2020

ETN

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Semiconductor CdS nanotubes with a small ratio of length to diameter and nanospheres were simultaneously synthesized in the light of bio- mineralization process through living bio-membrane bi-template of mungbean sprouts at room temperature. The outside diameter of the nanotube is 220－ 240 nm and the inner diameter is 200－220 nm, the length is up to 600－700 nm and the ratio of length to diameter is 2:1. The nanoshpheres are 25 nm in diameter and well distributed. The XRD pattern indicates that these nanocrystals were crystallized in the cubic structure with lattice a = 5.818 Å. The optical properties of the products are illustrated, and their possible forming mechanism is explored.

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Quantum dot cellular automata: A new paradigm for digital design

Cited by 10 publications

References 32 publications

Structural properties of chalcogenides nanostructures

Structural properties of chalcogenides nanostructures

Design of efficient N‐bit shift register using optimized D flip flop in quantum dot cellular automata technology

Synthesis of CdS nanotubes and nanospheres by living bio-membrane bi-template

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