Publications

9 Results

Search results

Jump to search filters

An electro-optical Mott neuron based on niobium dioxide

Nature Electronics

Islam, Mahnaz; Bohaichuk, Stephanie M.; Brown, Timothy D.; Oh, Sangheon; Perez, Christopher; Zhang, Chengyang; Park, Tae J.; Park, Minseong; Talin, Albert A.; Ramanathan, Shriram; Kumar, Suhas; Pop, Eric

Various applications—including brain-like computing and on-chip artificial vision—increasingly demand a combination of electronic and photonic techniques. However, integrating both approaches on a single chip is challenging, and solutions typically rely on disparate components with power-hungry signal conversions. Here we report electro-optical Mott neurons that combine visible light emission with electrical threshold switching, as well as neuron-like oscillations. The devices are based on thin films of sputtered niobium dioxide (NbO2), a Mott insulator–metal transition material, operating at room temperature and emitting light that peaks around 810 nm. Operando measurements reveal an electronic origin to the light emission: charge carrier relaxation initiated by high-field transport in the NbO2. Our devices combine electrical and optical functions within a single material, thereby expanding the options available for future artificial intelligence hardware.

More Details

Effect of Gamma Radiation on TaOₓ ECRAM

IEEE Transactions on Nuclear Science

Faruque, Hossain M.R.; Bennett, Christopher H.; Oh, Sangheon; Zutter, Brian T.; Siath, Max; Neuendank, Jereme; Spear, Matthew; Xiao, T.P.; Hughart, David R.; Agarwal, Sapan; Barnaby, Hugh J.; Li, Yiyang; Talin, Albert A.; Marinella, Matthew J.

Electrochemical random access memory (ECRAM) is an emerging three-terminal nonvolatile memory (NVM) with highly controllable channel conductance which is promising for use as an analog memory (or synapse) in analog in-memory computing (IMC) systems. Energy-efficient analog IMC computing is particularly desirable for power-constrained, high-radiation environments such as satellites. However, little is known about the suitability of ECRAM for use in a total ionizing dose (TID) environment. This work investigates the effect of Co-60 gamma radiation on the channel conductance and noise—two properties critical for analog IMC systems—of a TaOx-based ECRAM up to 17.3 Mrad(SiO2) for both low- and high-channel-conductance state devices. A transient increase in conductance is observed in response to radiation which consists of two elements: an immediate increase in conductivity due to photocurrent and a secondary increase in conductivity, which has a slower rise and saturation and can persist for hours after exposure. This secondary, persistent photoconductivity is attributed to charging caused by hole trapping. These transient effects would not likely occur in a space environment due to the low dose rate compared with this experiment. No permanent change is found in the low conductance state (LCS) following exposure and the minor shift in the high conductance change would be less significant than the regular retention decay in this state. A permanent increase in the random telegraph noise is observed, possibly due to increased traps created in the channel. This work demonstrates that TaOx-based ECRAM is suitable for use in spaceborne analog IMC systems that are subject to significant TID.

More Details

Tuning the Spin Transition and Carrier Type in Rare-Earth Cobaltates via Compositional Complexity

Advanced Materials

Oh, Sangheon; Brown, Timothy D.; Spataru, Dan C.; Sugar, Joshua D.; Witman, Matthew D.; Kumar, Suhas; Talin, Albert A.; Fuller, Elliot J.

There is growing interest in material candidates with properties that can be engineered beyond traditional design limits. Compositionally complex oxides (CCO), often called high entropy oxides, are excellent candidates, wherein a lattice site shares more than four cations, forming single-phase solid solutions with unique properties. However, the nature of compositional complexity in dictating properties remains unclear, with characteristics that are difficult to calculate from first principles. Here, compositional complexity is demonstrated as a tunable parameter in a spin-transition oxide semiconductor La1− x(Nd, Sm, Gd, Y)x/4CoO3, by varying the population x of rare earth cations over 0.00≤ x≤ 0.80. Across the series, increasing complexity is revealed to systematically improve crystallinity, increase the amount of electron versus hole carriers, and tune the spin transition temperature and on-off ratio. At high a population (x = 0.8), Seebeck measurements indicate a crossover from hole-majority to electron-majority conduction without the introduction of conventional electron donors, and tunable complexity is proposed as new method to dope semiconductors. First principles calculations combined with angle resolved photoemission reveal an unconventional doping mechanism of lattice distortions leading to asymmetric hole localization over electrons. Thus, tunable complexity is demonstrated as a facile knob to improve crystallinity, tune electronic transitions, and to dope semiconductors beyond traditional means.

More Details

Low Power, Radiation Resilient Synchronous Edge Processing for Remote Monitoring

Xiao, T.P.; Wahby, William; Bennett, Christopher H.; Hughart, David R.; Oh, Sangheon; Fuller, Elliot J.; Talin, Albert A.; Li, Yiyang; Agarwal, Sapan; Hays, Park E.; Siath, Maximilian; Wilson, Donald; Dempsey, Ryan C.; Marinella, Matthew

Next-generation space remote sensing systems may be equipped with imaging arrays that sense data at a rate that outstrips the processing capability of any computing hardware that can operate within a satellite’s power budget. This project developed novel convolutional and recurrent neural networks to detect and estimate point-like events amid clutter, and investigated their efficient and accurate implementation on analog in-memory computing systems that are 10-1000× more energy-efficient than digital processors. This project leveraged two memory devices at different levels of technological maturity: a large-scale analog computing prototype using commercial SONOS charge-trap memory, and electrochemical memory (ECRAM) with intrinsic radiation hardness. We experimentally demonstrated end-to-end analog processing of our neural networks on SONOS and characterized the radiation response of both SONOS and ECRAM. We advanced the state-of-the-art in ECRAM precision and reliability, and developed co-design methods to enable accurate long-term operation of SONOS analog accelerators in space radiation environments.

More Details
9 Results
9 Results
Top