Your search keyword '"Lu, Yanghua"' showing total 9 results

1. Mechanical motion tuned carrier transport characteristic of dynamic diode

Author

Yang, Zunshan, Zhong, Huikai, Wang, Can, Lu, Yanghua, Feng, Lixuan, Yu, Xutao, Liu, Chang, and Lin, Shisheng

Subjects

Physics - Applied Physics

Abstract

Since the invention of dynamic diode, its physical properties and potential applications have attracted wide attentions. A lot of attempts have been made to harvest the rebounding current and voltage of dynamic diode. However, the underlying physical mechanism of its carrier transport characteristic was rarely explored carefully. Here, the electrical transport properties of the dynamic diode are systematically investigated with a mechanical motion tuned method, where the dynamic current-voltage curve shows a gentler growth trend compared to the static curve. The rebounding current increases with motion velocity and contact force, resulting in a reduced current with the same bias voltage and an oscillation current with a changing velocity and force. Besides, we propose a circuit model with an accurate mathematical formula expression to describe the oscillation current, where an imaginary parameter n0 is creatively added to the exponential growth term. This work shows a physical picture of adjust microscopic carrier motion with macroscopic mechanical motion, which provides strong theoretical support for designing dynamic diode devices with better performance in the future.

Published

2023

2. Self-driven photo-polarized water molecule triggered graphene-based photodetector

Author

Lin, Shisheng, Liu, Chang, Chen, Xin, Zhang, Yi, Yu, Xutao, Bo, Yujiao, and Lu, Yanghua

Subjects

Physics - Applied Physics

Abstract

Flowing water can be used as an energy source for generators, providing a major part of the energy for daily life. However, water is rarely used for information or electronic devices. Herein, we present the feasibility of a polarized liquid-triggered photodetector in which polarized water is sandwiched between graphene and semiconductor. Due to the polarization and depolarization processes of water molecular under the driven of photogenerated carriers, a photo-sensitive current can be repeatably produced, resulting in a high-performance photodetector. The response wavelength of the photodetector can be finely tuned as a result of the free choice of semiconductors as there is no requirement of lattice match between graphene and the semiconductors. Under zero voltage bias, the responsivity and specific detectivity of Gr/NaCl (0.5 M)/N-GaN reaches values of 130.7 mA/W and 2.8*10^12 Jones under 350 nm illumination. Meanwhile, using a polar liquid photodetector can successfully read the photoplethysmography signals to produce accurate oxygen blood saturation and heart rate. Compared with the commercial pulse oximetry sensor, the average errors of oxygen saturation and heart rate in the designed photoplethysmography sensor are~1.9% and ~2.1%, respectively. This study transfers the message that water can be used as high-performance photodetector in informative industries., Comment: The experimental data needs to be further updated

Published

2022

3. Self-driven water or polarized liquid based ultraviolet photodetector

Author

Liu, Chang, Lu, Yanghua, Yu, Xutao, Wang, Can, Shen, Runjiang, and Lin, Shisheng

Subjects

Physics - Applied Physics, Physics - Optics

Abstract

Traditionally, photodetector is based on solid materials constructed PN junction, which needs many delicate growth technologies. Herein, we demonstrate the feasibility of polarized liquid triggered photodetector where the liquid is sandwiched between P-type or N-type semiconductor which can be chosen freely according to the requirement of the specific response wavelength. Under the multiple cycles of optical switching, transient photo-polarized current, steady state photo-polarized current and depolarized current are repeatably observed in semiconductor/polar liquids/semiconductor structure. The responsivity and specific detectivity of transient photo-polarized current in N-GaN/water/P-GaN reach values of 104.2 mA/W and 4.4*10^12 Jones at 365 nm, and 52.8 mA/W and 1.9*10^12 Jones at 254 nm illumination under zero voltage bias. We anticipate that our research will have a profound impact on integrating self-powered photodetector with freely selectable wavelength bands.

Published

2022

4. Infrared Radiation of Graphene Electrothermal Film Triggered Alpha and Theta Brainwaves

Author

Lu, Yanghua, Yang, Renyu, Dai, Yue, Yuan, Deyi, Yu, Xutao, Liu, Chang, Feng, Lixuan, Shen, Runjiang, Wang, Can, Dai, Shenyi, and Lin, Shisheng

Subjects

Physics - Applied Physics

Abstract

The alpha and theta frequency brainwave activity in Electroencephalogram (EEG) signal has been correlated with attention, inhibitory processes, memory, perceptual abilities, and sleep. The enhanced alpha and theta brainwave activity may bring positive behavioral modifications such as promoting creativity and a quick sleep. Herein, we discover that infrared radiation from multilayer graphene electrothermal film can obviously promote the appearance of alpha and theta brainwave in human mind. In particular, the occurrence frequency of the alpha and theta waves in EEG can be effectively enhanced up to 2.3 and 3.0 times, respectively. And the duration time of the alpha and theta waves in EEG can also be effectively extended. The mechanism may be attributed to the efficient infrared radiation caused by graphene mainly focused on the range from 7 to 14 micron, coinciding with the radiation wavelength of natural human body, which can be effectively absorbed by the human skin and speed up the blood microcirculation and metabolism. The comparative effect of different working temperature and heating materials such as water, Cu and even monolayer graphene are systematically investigated, indicating the infrared radiation from the multilayer graphene electrothermal film at 50 degrees has the largest enhancement effect of alpha and theta brainwaves. The multilayer graphene film electrical heater represents a convenient and surprising way for triggering the alpha and theta brainwaves, which has many potential applications in the area of enlarged health cerements.

Published

2022

5. Wind Driven Semiconductor Electricity Generator With High Direct Current Output Based On a Dynamic Schottky Junction

Author

Yu, Xutao, Zheng, Haonan, Lu, Yanghua, Si, Jiaqi, Shen, Runjiang, Yan, Yanfei, Hao, Zhenzhen, and Lin, Shisheng

Subjects

Physics - Applied Physics

Abstract

As the fast development of internet of things (IoTs), distributed sensors have been frequently used and the small and portable power sources are highly demanded. However, the present portable power source such as lithium battery has low capacity and need to be replaced or recharged frequently. A portable power source which can continuously generate electrical power in situ will be an idea solution. Herein, we demonstrate a wind driven semiconductor electricity generator based on a dynamic Schottky junction, which can output a continuous direct current with an average value of 4.4 mA (the maximum value of 8.4 mA) over 360 seconds. Compared with the previous metal/semiconductor generator, the output current is one thousand times higher. Furthermore, this wind driven generator has been explored to function as a turn counter due to its stable output and also to drive a graphene ultraviolet photodetector, which shows a responsivity of 35.8 A/W under the 365 nm ultraviolet light. Our research provides a feasible method to achieve wind power generation and power supply for distributed sensors in the future.

Published

2020

6. Direct-Current Generator Based on Dynamic Water-Semiconductor Junction with Polarized Water as Moving Dielectric Medium

Author

Lu, Yanghua, Yan, Yanfei, Yu, Xutao, Zhou, Xu, Feng, Sirui, Xu, Chi, Zheng, Haonan, Yang, Zunshan, Li, Linjun, Liu, Kaihui, and Lin, Shisheng

Subjects

Physics - Applied Physics

Abstract

There is a rising prospective in harvesting energy from water droplets, as microscale energy is required for the distributed sensors in the interconnected human society. However, achieving a sustainable direct-current generating device from water flow is rarely reported, and the quantum polarization principle of the water molecular remains uncovered. Herein, we propose a dynamic water-semiconductor junction with moving water sandwiched between two semiconductors as a moving dielectric medium, which outputs a sustainable direct-current voltage of 0.3 V and current of 0.64 uA with low internal resistance of 390 kilohm. The sustainable direct-current electricity is originating from the dynamic water polarization process in water-semiconductor junction, in which water molecules are continuously polarized and depolarized driven by the mechanical force and Fermi level difference, during the movement of the water on silicon. We further demonstrated an encapsulated portable power-generating device with simple structure and continuous direct-current voltage, which exhibits its promising potential application in the field of wearable electronic generators.

Published

2020

7. DC electricity generation from dynamic polarized water-semiconductor interface

Author

Yan, Yanfei, Zhou, Xu, Feng, Sirui, Lu, Yanghua, Qian, Jianhao, Zhang, Panpan, Yu, Xutao, Zheng, Yujie, Wang, Fengchao, Liu, Kaihui, and Lin, Shisheng

Subjects

Physics - Applied Physics

Abstract

Liquid electricity generator and hydrovoltaic technology have received numerous attentions, which can be divided into horizontal movement generator and vertical movement generator. The horizontal movement generator is limited for powering the integrated and miniaturized energy chip as the current output direction is depending on the moving direction of the water droplet, which means a sustainable and continuous direct-current (DC) electricity output can be hardly achieved because of the film of limited length. On the other hand, the existing vertical movement generators include triboelectricity or humidity gradient-based liquid electricity generator, where the liquid or water resource must be sustainably supplied to ensure continuous current output. Herein, we have designed an integratable vertical generator by sandwiching water droplets with semiconductor and metal, such as graphene or aluminum. This generator, named as polarized liquid molecular generator (PLMG), directly converts the lateral kinetic energy of water droplet into vertical DC electricity with an output voltage of up to ~1.0 V from the dynamic water-semiconductor interface. The fundamental discovery of PLMG is related to the non-symmetric structure of liquid molecules, such as water and alcohols, which can be polarized under the guidance of built-in field caused by the Fermi level difference between metal and semiconductor, while the symmetric liquid molecules cannot produce any electricity on the opposite. Integratable PLMG with a large output power of ~90 nW and voltage of ~2.7 V has been demonstrated, meanwhile its small internal resistance of ~250 kilohm takes a huge advantage in resistance matching with the impedance of electron components. The PLMG shows potential application value in the Internet of Things (IoTs) after proper miniaturization and integration.

Published

2020

8. High Performance Direct-Current Generator Based on Dynamic PN Junctions

Author

Lu, Yanghua, Feng, Sirui, Hao, Zhenzhen, Shen, Runjiang, and Lin, Shisheng

Subjects

Physics - Applied Physics

Abstract

After the electromagnetic generator, searching for novel electric generators without strong magnetic field is highly demanded. The generator without strong magnetic field calls for a physical picture distinct from the traditional generators. As the counterpart of the static PN junction has been widely used in the integrated circuits, we develop an electric generator named dynamic PN generator with a high current density and voltage output, which converts mechanical energy into electricity by sliding two semiconductors with different Fermi level. A dynamic N-GaAs/SiO2/P-Si generator with the open-circuit voltage of 3.1 V and short-circuit density of 1.0 A/m2 have been achieved. The physical mechanism of the dynamic PN generator is proposed based on the built-in electric field bounding back diffusing carriers in dynamic PN junctions, which breaks the equilibrium between drift and diffusion current in the PN junction. Moreover, the dynamic MoS2/AlN/Si generator with the open-circuit voltage of 5.1 V and short-circuit density of 112 A/m2 (11.2 mA/cm2) have also been achieved, which can effectively output a direct-current and light up a blue light-emitting diode directly. This dynamic MoS2/AlN/Si generator can continuously work for hours without obvious degradation, demonstrating its unique mechanism and potential applications in many fields where the mechanical energy is available.

Published

2019

9. Direct-Current Generator Based on Moving Van der Waals Schottky Diode

Author

Lin, Shisheng, Lu, Yanghua, Feng, Sirui, Hao, Zhenzhen, and Yan, Yanfei

Subjects

Physics - Applied Physics

Abstract

Traditionally, Schottky diodes are used statically in the electronic information industry but dynamic state Schottky diodes based applications have been rarely explored. Herein, a novel Schottky diode named moving Schottky diode generator has been designed, which can convert mechanical energy into electrical energy with voltage output as high as 0.6V, by means of lateral movement between graphene/metal film and semiconductor, where the semiconductor can be non-piezoelectric materials. The mechanism is based on the built-in electric field separation of drifting electrons in moving van der Waals Schottky diode. The power output can be further increased in future through optimizing the Schottky diode. The graphene film/silicon moving van der Waals Schottky diode based generator behaves better stability. This direct-current generator has the potential of converting mechanical efficiently and vibrational energy into electricity and enables many promising applications.

Published

2018