Shamik Das scite author profile

A nanoprocessor constructed from intrinsically nanometre-scale building blocks is an essential component for controlling memory, nanosensors and other functions proposed for nanosystems assembled from the bottom up. Important steps towards this goal over the past fifteen years include the realization of simple logic gates with individually assembled semiconductor nanowires and carbon nanotubes, but with only 16 devices or fewer and a single function for each circuit. Recently, logic circuits also have been demonstrated that use two or three elements of a one-dimensional memristor array, although such passive devices without gain are difficult to cascade. These circuits fall short of the requirements for a scalable, multifunctional nanoprocessor owing to challenges in materials, assembly and architecture on the nanoscale. Here we describe the design, fabrication and use of programmable and scalable logic tiles for nanoprocessors that surmount these hurdles. The tiles were built from programmable, non-volatile nanowire transistor arrays. Ge/Si core/shell nanowires coupled to designed dielectric shells yielded single-nanowire, non-volatile field-effect transistors (FETs) with uniform, programmable threshold voltages and the capability to drive cascaded elements. We developed an architecture to integrate the programmable nanowire FETs and define a logic tile consisting of two interconnected arrays with 496 functional configurable FET nodes in an area of ∼960 μm(2). The logic tile was programmed and operated first as a full adder with a maximal voltage gain of ten and input-output voltage matching. Then we showed that the same logic tile can be reprogrammed and used to demonstrate full-subtractor, multiplexer, demultiplexer and clocked D-latch functions. These results represent a significant advance in the complexity and functionality of nanoelectronic circuits built from the bottom up with a tiled architecture that could be cascaded to realize fully integrated nanoprocessors with computing, memory and addressing capabilities.

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Nanowire nanocomputer as a finite-state machine

Yao¹,

Yan²,

Das

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Implementation of complex computer circuits assembled from the bottom up and integrated on the nanometer scale has long been a goal of electronics research. It requires a design and fabrication strategy that can address individual nanometer-scale electronic devices, while enabling large-scale assembly of those devices into highly organized, integrated computational circuits. We describe how such a strategy has led to the design, construction, and demonstration of a nanoelectronic finite-state machine. The system was fabricated using a design-oriented approach enabled by a deterministic, bottom-up assembly process that does not require individual nanowire registration. This methodology allowed construction of the nanoelectronic finite-state machine through modular design using a multitile architecture. Each tile/module consists of two interconnected crossbar nanowire arrays, with each crosspoint consisting of a programmable nanowire transistor node. The nanoelectronic finite-state machine integrates 180 programmable nanowire transistor nodes in three tiles or six total crossbar arrays, and incorporates both sequential and arithmetic logic, with extensive intertile and intratile communication that exhibits rigorous input/output matching. Our system realizes the complete 2-bit logic flow and clocked control over state registration that are required for a finite-state machine or computer. The programmable multitile circuit was also reprogrammed to a functionally distinct 2-bit full adder with 32-set matched and complete logic output. These steps forward and the ability of our unique design-oriented deterministic methodology to yield more extensive multitile systems suggest that proposed general-purpose nanocomputers can be realized in the near future.nanocomputing | nanoprocessor | logic circuits | memory I t is widely agreed (1, 2) that because of fundamental physical limits, the microelectronics industry is approaching the end of its present Roadmap (1) for the miniaturization of computer circuits based upon lithographically fabricated bulk-silicon (Si) transistors. Therefore, much effort has been invested in the nanoelectronics field for the development of novel, alternative, nanometer-scale electronic device and fabrication technologies that could serve as potential routes for ever-denser and more capable systems to enable continued technological and economic advancement (3-17). These efforts have yielded simple nanoelectronic circuits (3)(4)(5)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17) and more complex circuit systems (6, 7) that use novel nanomaterials but are not integrated on the nanometer scale. In this regard, building a nanocomputer that transcends the ultimate scaling limitations of conventional semiconductor electronics has been a central goal of the nanoscience field and a long-term objective of the computing industry.A finite-state machine (FSM) is a representation for a nanocomputer in that it is a fundamental model for clocked, programmable logic circuits (18, 19) and integrates key arithmetic and memor...

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Designs for Ultra-Tiny, Special-Purpose Nanoelectronic Circuits

Das

Gates

Abdu

et al. 2007

IEEE Trans. Circuits Syst. I

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Architectures and Simulations for Nanoprocessor Systems Integrated on the Molecular Scale

Das

Rose

Ziegler

et al.

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SPICE-compatible compact model for graphene field-effect transistors

Henry

Das

2012

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Shamik Das

Programmable nanowire circuits for nanoprocessors

Nanowire nanocomputer as a finite-state machine

Designs for Ultra-Tiny, Special-Purpose Nanoelectronic Circuits

Architectures and Simulations for Nanoprocessor Systems Integrated on the Molecular Scale

SPICE-compatible compact model for graphene field-effect transistors

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