神经形态工程学
量子计算机
钒
数码产品
量子位元
纳米技术
材料科学
计算机科学
半导体
横杆开关
认知计算
记忆电阻器
电阻随机存取存储器
量子
计算机体系结构
光电子学
电子工程
物理
电气工程
电压
工程类
人工神经网络
量子力学
认知
神经科学
人工智能
电信
冶金
生物
出处
期刊:Materials horizons
[The Royal Society of Chemistry]
日期:2024-01-01
被引量:1
摘要
Vanadium is a critical raw material. In the nearby future, it may, however, become one of the key elements of computer devices based on two-dimensional arrays of spin qubits for quantum information processing or charge- and resistance-based data memory cells for non-volatile in-memory and neuromorphic computing. The research and development (R&D) of vanadium-containing electronic materials and methods for their responsible fabrication underpins the transition to innovative hybrid semiconductors for energy- and resource-efficient memory and information processing technologies. The combination of standard and emerging solid-state semiconductors with stimuli-responsive oxo complexes of vanadium(IV,V) is envisioned to result in electronics with a new room-temperature device nanophysics, and the ability to modulate and control it at the sub-nanometer level. The development of exponential (Boolean) logics based on the oxovanadium-comprising circuitry and crossbar arrays of individual memristive cells for in-memory computing, the implementation of basic synaptic functions via dynamic electrical pulses for neuromorphic computing, and the readout and control of spin networks and interfaces for quantum computing are strategically important future areas of molecular chemistry and applied physics of vanadium.
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