9 research outputs found
InkjetâPrinted Tungsten Oxide Memristor Displaying NonâVolatile Memory and Neuromorphic Properties
Printed electronics including large-area sensing, wearables, and bioelectronic systems are often limited to simple circuits and hence it remains a major challenge to efficiently store data and perform computational tasks. Memristors can be considered as ideal candidates for both purposes. Herein, an inkjet-printed memristor is demonstrated, which can serve as a digital information storage device, or as an artificial synapse for neuromorphic circuits. This is achieved by suitable manipulation of the ion species in the active layer of the device. For digital-type memristor operation resistive switching is dominated by cation movement after an initial electroforming step. It allows the device to be utilized as non-volatile digital memristor, which offers high endurance over 12 672 switching cycles and high uniformity at low operating voltages. To use the device as an electroforming-free, interface-based, analog-type memristor, anion migration is exploited which leads to volatile resistive switching. An important figure of merits such as short-term plasticity with close to biological synapse timescales is demonstrated, for facilitation (10â177 ms), augmentation (10s), and potentiation (35 s). Furthermore, the device is thoroughly studied regarding its metaplasticity for memory formation. Last but not least, the inkjet-printed artificial synapse shows non-linear signal integration and low-frequency filtering capabilities, which renders it a good candidate for neuromorphic computing architectures, such as reservoir computing
Mitigation of OpenâCircuit Voltage Losses in Perovskite Solar Cells Processed over MicrometerâSizedâTextured Si Substrates
The recent development of solution-processed perovskite thin films over micrometer-sized textured silicon bottom solar cells enables tandem solar cells with power conversion efficiencies > 30%. Next to improved light harvesting, textured silicon wafers are the industrial standard. To achieve high performance, the open-circuit voltage losses that occur when fabricating perovskite solar cells over such textures need to be mitigated. This study provides a practical guideline to discriminate and address the voltage losses at the interfaces as well as in the bulk of solution-processed double cation perovskite thin films using photoluminescence quantum yield measurements. Furthermore, the origin of these losses is investigated via morphological, microstructural, and compositional analysis and present possible mitigation strategies. The guideline will be beneficial for scientists working on randomly textured surfaces and provides a deeper understanding on this timely research topic
Temperature Variation-Induced Performance Decline of Perovskite Solar Cells
This
paper reports on the impact of outdoor temperature variations on the
performance of organo metal halide perovskite solar cells (PSCs).
It shows that the open-circuit voltage (<i>V</i><sub>OC</sub>) of a PSC decreases linearly with increasing temperature. Interestingly,
in contrast to these expected trends, the current density (<i>J</i><sub>SC</sub>) of PSCs is found to decline strongly below
20% of the initial value upon cycling the temperatures from 10 to
60 °C and back. This decline in the current density is driven
by an increasing series resistance and is caused by the fast temperature
variations as it is not apparent for solar cells exposed to constant
temperatures of the same range. The effect is fully reversible when
the devices are kept illuminated at an open circuit for several hours.
Given these observations, an explanation that ascribes the temperature
variation-induced performance decline to ion accumulation at the contacts
of the solar cell because of temperature variation-induced changes
of the built-in field of the PSC is proposed. The effect might be
a major obstacle for perovskite photovoltaics because the devices
exposed to real outdoor temperature profiles over 4 h showed a performance
decline of >15% when operated at a maximum power point