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1. Light induced photovoltaic and pyroelectric effects in ferroelectric BaTiO3 film based Schottky interface for self‐powered and flexible multi‐modal logic gates

Author

Huiyu Dan, Hongyu Li, Lan Xu, Chong Guo, Chris R. Bowen, and Ya Yang

Subjects
BaTiO3, flexible, optoelectronic logic gates, self‐powered, Materials of engineering and construction. Mechanics of materials, TA401-492, Information technology, T58.5-58.64
Abstract

Abstract Optoelectronic logic gates have emerged as one of the key candidates for the creation of next generation logic devices. However, current optoelectronic logic gates can provide only one or two logic gates, severely limiting their applications. Here we report a self‐powered and mechanically flexible device based on a BaTiO3 ferroelectric film to produce multi‐modal logic gates. By exploiting the photo‐induced photovoltaic and pyroelectric effects of a Schottky junction which is created between BaTiO3 and LaNiO3, the device is able to provide five different optoelectronic logic gates, which can be operated using input lasers of different wavelength (405 or 785 nm). The mode of operation of the logic gate can be switched by controlling the wavelength and intensity of the input laser, where the switching process is both lossless and reversible. A logic gate array was designed to conduct the five logic operations, with 100% accuracy, thereby providing application potential for the Internet of Things, big data, and secure solutions for data processing and transmission.

Published
2024
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2. Intelligent Recognition Using Ultralight Multifunctional Nano-Layered Carbon Aerogel Sensors with Human-Like Tactile Perception

Author

Huiqi Zhao, Yizheng Zhang, Lei Han, Weiqi Qian, Jiabin Wang, Heting Wu, Jingchen Li, Yuan Dai, Zhengyou Zhang, Chris R. Bowen, and Ya Yang

Subjects
Multifunctional sensor, Tactile perception, Multimodal machine learning algorithms, Universal tactile system, Intelligent object recognition, Technology
Abstract

Highlights The tactile performance of ultralight multifunctional sensors can reach the level of human tactile perception. An individual sensor can provide multiple tactile sensations: pressure, temperature, materials recognition, and 3D location. Therefore, it is no longer necessary to integrate multiple sensing modules with different functions, which greatly simplifies system complexity and reduces energy loss. The tactile system with multimodal learning algorithms has universality and can accommodate object recognition tasks in various application scenarios (e.g., Mars and Kitchen).

Published
2023
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3. Coupling Enhancement of a Flexible BiFeO3 Film-Based Nanogenerator for Simultaneously Scavenging Light and Vibration Energies

Author

Xiao Han, Yun Ji, Li Wu, Yanlong Xia, Chris R. Bowen, and Ya Yang

Subjects
Ferroelectric film, Coupled nanogenerators, Photovoltaic effect, Flexoelectric effect, Energy collection, Technology
Abstract

Abstract Coupled nanogenerators have been a research hotspot due to their ability to harvest a variety of forms of energy such as light, mechanical and thermal energy and achieve a stable direct current output. Ferroelectric films are frequently investigated for photovoltaic applications due to their unique photovoltaic properties and bandgap-independent photovoltage, while the flexoelectric effect is an electromechanical property commonly found in solid dielectrics. Here, we effectively construct a new form of coupled nanogenerator based on a flexible BiFeO3 ferroelectric film that combines both flexoelectric and photovoltaic effects to successfully harvest both light and vibration energies. This device converts an alternating current into a direct current and achieves a 6.2% charge enhancement and a 19.3% energy enhancement to achieve a multi-dimensional "1 + 1 > 2" coupling enhancement in terms of current, charge and energy. This work proposes a new approach to the coupling of multiple energy harvesting mechanisms in ferroelectric nanogenerators and provides a new strategy to enhance the transduction efficiency of flexible functional devices.

Published
2022
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4. Air‐condition process for scalable fabrication of CdS/ZnS 1D/2D heterojunctions toward efficient and stable photocatalytic hydrogen production

Author

Dongdong Zhang, Jie Teng, Hongli Yang, Zhi Fang, Kai Song, Lin Wang, Huilin Hou, Xianlu Lu, Chris R. Bowen, and Weiyou Yang

Subjects
air condition, CdS, heterojunctions, photocatalytic hydrogen production, ZnS, Production of electric energy or power. Powerplants. Central stations, TK1001-1841
Abstract

Abstract We report the scalable fabrication of CdS/ZnS 1D/2D heterojunctions under ambient air conditions (i.e., room temperature and atmospheric pressure) in which ZnS nanoparticles are anchored on the surface of CdS nanosheets. The as‐formed heterojunctions exhibit a significantly enhanced photocatalytic H2 evolution rate of 14.02 mmol h−1 g−1 when irradiated with visible light, which is ~10 and 85 times higher than those of pristine CdS nanosheets and CdS nanoparticles, respectively, and superior to most of the CdS‐based photocatalysts reported to date. Furthermore, they provide robust photocatalytic performance with demonstratable stability over 58 h, indicating their potential for practical applications. The formation of 1D/2D heterojunctions not only provides improved exposed active sites that respond to illumination but also provides a rapid pathway to generate photogenerated carriers for efficient separation and transfer through the matrix of single‐crystalline CdS nanosheets. In addition, first‐principles simulations demonstrate that the existence of rich Zn vacancies increases the energy level of the ZnS valence band maximum to construct type‐II and Z‐scheme mixed heterojunctions, which plays a critical role in suppressing the recombination of carriers with limited photocorrosion of CdS to enhance photocatalytic behavior.

Published
2023
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5. A multifunctional optical‐thermal logic gate sensor array based on ferroelectric BiFeO3 thin films

Author

Li Wu, Yun Ji, Huiyu Dan, Chris R. Bowen, and Ya Yang

Subjects
BiFeO3, logic gate, optical‐thermal, photocurrent, photovoltage, Materials of engineering and construction. Mechanics of materials, TA401-492, Information technology, T58.5-58.64
Abstract

Abstract The growing need to process a diverse range of data has ignited effort in developing new multifunctional logic gate devices. In this article, we report a new form of all‐in‐one logic gate system that exploits the photoresponsivity of a self‐powered multifunctional BiFeO3 (BFO) sensor material. The BFO sensor can not only detect both light intensity and temperature, but it can also execute three common logic gates of “AND”, “OR”, and “NOT” by converting optical and thermal inputs into electrical output. The diverse functionality of the BFO logic gate sensor array utilizes the unique light‐and temperature‐controlled energy band structure and carrier behavior of the BFO material. To demonstrate the potential, a 3 × 3 logic gate sensor matrix is developed, which successfully detected light and temperature distributions, and accurately produced the three basic logic gate operations. This work provides a new route to construct highly integrated multifunctional electronic devices for the advancement of large sensing, communication, and computing operations.

Published
2023
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6. Differences and Similarities of Photocatalysis and Electrocatalysis in Two-Dimensional Nanomaterials: Strategies, Traps, Applications and Challenges

Author

Weiqi Qian, Suwen Xu, Xiaoming Zhang, Chuanbo Li, Weiyou Yang, Chris R. Bowen, and Ya Yang

Subjects
2D nanomaterials, Photocatalysis, Electrocatalysis, Electrochemistry, Photoelectrochemistry, Technology
Abstract

Abstract Photocatalysis and electrocatalysis have been essential parts of electrochemical processes for over half a century. Recent progress in the controllable synthesis of 2D nanomaterials has exhibited enhanced catalytic performance compared to bulk materials. This has led to significant interest in the exploitation of 2D nanomaterials for catalysis. There have been a variety of excellent reviews on 2D nanomaterials for catalysis, but related issues of differences and similarities between photocatalysis and electrocatalysis in 2D nanomaterials are still vacant. Here, we provide a comprehensive overview on the differences and similarities of photocatalysis and electrocatalysis in the latest 2D nanomaterials. Strategies and traps for performance enhancement of 2D nanocatalysts are highlighted, which point out the differences and similarities of series issues for photocatalysis and electrocatalysis. In addition, 2D nanocatalysts and their catalytic applications are discussed. Finally, opportunities, challenges and development directions for 2D nanocatalysts are described. The intention of this review is to inspire and direct interest in this research realm for the creation of future 2D nanomaterials for photocatalysis and electrocatalysis.

Published
2021
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7. 2D Nanomaterials for Effective Energy Scavenging

Author

Md Al Mahadi Hasan, Yuanhao Wang, Chris R. Bowen, and Ya Yang

Subjects
2D nanomaterials, Solar energy, Tribo-/piezo-/thermo-/pyro-electricity, Osmotic power generation, Self-powered sensor, Technology
Abstract

Abstract The development of a nation is deeply related to its energy consumption. 2D nanomaterials have become a spotlight for energy harvesting applications from the small-scale of low-power electronics to a large-scale for industry-level applications, such as self-powered sensor devices, environmental monitoring, and large-scale power generation. Scientists from around the world are working to utilize their engrossing properties to overcome the challenges in material selection and fabrication technologies for compact energy scavenging devices to replace batteries and traditional power sources. In this review, the variety of techniques for scavenging energies from sustainable sources such as solar, air, waste heat, and surrounding mechanical forces are discussed that exploit the fascinating properties of 2D nanomaterials. In addition, practical applications of these fabricated power generating devices and their performance as an alternative to conventional power supplies are discussed with the future pertinence to solve the energy problems in various fields and applications.

Published
2021
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8. Piezoelectric Materials for Controlling Electro-Chemical Processes

Author

Weiqi Qian, Weiyou Yang, Yan Zhang, Chris R. Bowen, and Ya Yang

Subjects
Piezoelectric materials, Piezoelectric effect, Electro-chemistry, Piezo-electro-chemistry, Technology
Abstract

Abstract Piezoelectric materials have been analyzed for over 100 years, due to their ability to convert mechanical vibrations into electric charge or electric fields into a mechanical strain for sensor, energy harvesting, and actuator applications. A more recent development is the coupling of piezoelectricity and electro-chemistry, termed piezo-electro-chemistry, whereby the piezoelectrically induced electric charge or voltage under a mechanical stress can influence electro-chemical reactions. There is growing interest in such coupled systems, with a corresponding growth in the number of associated publications and patents. This review focuses on recent development of the piezo-electro-chemical coupling multiple systems based on various piezoelectric materials. It provides an overview of the basic characteristics of piezoelectric materials and comparison of operating conditions and their overall electro-chemical performance. The reported piezo-electro-chemical mechanisms are examined in detail. Comparisons are made between the ranges of material morphologies employed, and typical operating conditions are discussed. In addition, potential future directions and applications for the development of piezo-electro-chemical hybrid systems are described. This review provides a comprehensive overview of recent studies on how piezoelectric materials and devices have been applied to control electro-chemical processes, with an aim to inspire and direct future efforts in this emerging research field.

Published
2020
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9. Flexible ferroelectric wearable devices for medical applications

Author

Zois Michail Tsikriteas, James I. Roscow, Chris R. Bowen, and Hamideh Khanbareh

Subjects
Medical Device, Biodevice, Energy Resources, Electronic Materials, Energy Materials, Science
Abstract

Summary: Wearable electronics are becoming increasingly important for medical applications as they have revolutionized the way physiological parameters are monitored. Ferroelectric materials show spontaneous polarization below the Curie temperature, which changes with electric field, temperature, and mechanical deformation. Therefore, they have been widely used in sensor and actuator applications. In addition, these materials can be used for conversion of human-body energy into electricity for powering wearable electronics. In this paper, we review the recent advances in flexible ferroelectric materials for wearable human energy harvesting and sensing. To meet the performance requirements for medical applications, the most suitable materials and manufacturing techniques are reviewed. The approaches used to enhance performance and achieve long-term sustainability and multi-functionality by integrating other active sensing mechanisms (e.g. triboelectric and piezoresistive effects) are discussed. Data processing and transmission as well as the contribution of wearable piezoelectric devices in early disease detection and monitoring vital signs are reviewed.

Published
2021
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10. Recent Progress in Hybridized Nanogenerators for Energy Scavenging

Author

Tongtong Zhang, Tao Yang, Mei Zhang, Chris R. Bowen, and Ya Yang

Subjects
Electromagnetic Field, Energy Systems, Nanostructure, Science
Abstract

Summary: As the world's demand for alternative energy increases, the development of green energy harvesters becomes ever more important. As a result, the creation of triboelectric (TENG), piezoelectric (PENG), and pyroelectric nanogenerators, electromagnetic generators (EMG), solar cells, and electrochemical cells is attracting interest in an effort to convert mechanical, thermal, magnetic, solar, and chemical energy into electricity. In order to take advantage of the ambient energies from our surrounding environment, the design of hybridized generator units that can simultaneously scavenge energy in a variety of forms continues to develop. These systems are being considered to satisfy the energy needs of a range of electronic devices and adapt to a variety of working environments. This review demonstrates the latest progress in hybridized nanogenerators in accordance with their structure, operating principle, and applications. These studies demonstrate new approaches to developing hybrid techniques and novel assemblies for efficiently harvesting environmental energy from a number of sources.

Published
2020
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11. Anti-Ferroelectric Ceramics for High Energy Density Capacitors

Author

Aditya Chauhan, Satyanarayan Patel, Rahul Vaish, and Chris R. Bowen

Subjects
anti-ferroelectric, energy storage, capacitor, bulk ceramics, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

With an ever increasing dependence on electrical energy for powering modern equipment and electronics, research is focused on the development of efficient methods for the generation, storage and distribution of electrical power. In this regard, the development of suitable dielectric based solid-state capacitors will play a key role in revolutionizing modern day electronic and electrical devices. Among the popular dielectric materials, anti-ferroelectrics (AFE) display evidence of being a strong contender for future ceramic capacitors. AFE materials possess low dielectric loss, low coercive field, low remnant polarization, high energy density, high material efficiency, and fast discharge rates; all of these characteristics makes AFE materials a lucrative research direction. However, despite the evident advantages, there have only been limited attempts to develop this area. This article attempts to provide a focus to this area by presenting a timely review on the topic, on the relevant scientific advancements that have been made with respect to utilization and development of anti-ferroelectric materials for electric energy storage applications. The article begins with a general introduction discussing the need for high energy density capacitors, the present solutions being used to address this problem, and a brief discussion of various advantages of anti-ferroelectric materials for high energy storage applications. This is followed by a general description of anti-ferroelectricity and important anti-ferroelectric materials. The remainder of the paper is divided into two subsections, the first of which presents various physical routes for enhancing the energy storage density while the latter section describes chemical routes for enhanced storage density. This is followed by conclusions and future prospects and challenges which need to be addressed in this particular field.

Published
2015
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12. Solid-Gas Phase Photo-Catalytic Behaviour of Rutile and TiOn (1 < n < 2) Sub-Oxide Phases for Self-Cleaning Applications

Author

Manuel Nuño, Vaia Adamaki, David M. Tobaldi, Maria J. Hortigüela Gallo, Gonzalo Otero-Irurueta, Chris R. Bowen, and Richard J. Ball

Subjects
photocatalysis, TiO2, sub-oxide, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85
Abstract

The solid-gas phase photo-catalytic activities of rutile TiO2 and TiOn (1 < n < 2) sub-oxide phases have been evaluated. Varying concentrations of Ti3+ defects were introduced into the rutile polymorph of titanium dioxide through carbo-thermal reduction at temperatures ranging from 350 °C to 1300 °C. The resulting sub-oxides formed were characterized by X-ray diffraction, X-ray photoelectron spectroscopy, scanning electron microscopy, impedance spectroscopy and UV-visible diffuse reflectance spectroscopy. The presence of Ti3+ in rutile exposed to high reduction temperatures was confirmed by X-ray diffraction. In addition, a Ti3+-Ti4+ system was demonstrated to enhance the photo-catalytic properties of rutile for the degradation of the air pollutants NO2 and CO2 under UV irradiation of wavelengths (λ) 376–387 nm and 381–392 nm. The optimum reduction temperature for photo-catalytic activity was within the range 350–400 °C and attributed to improved charge-separation. The materials that were subject to carbo-thermal reduction at temperatures of 350 °C and 400 °C exhibited electrical conductivities over one hundred times higher compared to the non-reduced rutile. The results highlight that sub-oxide phases form an important alternative approach to doping with other elements to improve the photo-catalytic performance of TiO2. Such materials are important for applications such as self-cleaning where particles can be incorporated into surface coatings.

Published
2019
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13. Commercialisation of CMOS Integrated Circuit Technology in Multi-Electrode Arrays for Neuroscience and Cell-Based Biosensors

Author

Chris R. Bowen, John Taylor, Anthony H. D. Graham, and Jon Robbins

Subjects
IC, CMOS, biosensor, biocompatibility, Chemical technology, TP1-1185
Abstract

The adaptation of standard integrated circuit (IC) technology as a transducer in cell-based biosensors in drug discovery pharmacology, neural interface systems and electrophysiology requires electrodes that are electrochemically stable, biocompatible and affordable. Unfortunately, the ubiquitous Complementary Metal Oxide Semiconductor (CMOS) IC technology does not meet the first of these requirements. For devices intended only for research, modification of CMOS by post-processing using cleanroom facilities has been achieved. However, to enable adoption of CMOS as a basis for commercial biosensors, the economies of scale of CMOS fabrication must be maintained by using only low-cost post-processing techniques. This review highlights the methodologies employed in cell-based biosensor design where CMOS-based integrated circuits (ICs) form an integral part of the transducer system. Particular emphasis will be placed on the application of multi-electrode arrays for in vitro neuroscience applications. Identifying suitable IC packaging methods presents further significant challenges when considering specific applications. The various challenges and difficulties are reviewed and some potential solutions are presented.

Published
2011
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15. A high-performance UV photodetector with superior responsivity enabled by a synergistic photo/thermal enhancement of localized surface plasmon resonance

Author

Luxia Zheng, Yang Yang, Chris R. Bowen, Lan Jiang, Zhan Shu, Yun He, Hongli Yang, Zongzhuo Xie, Taixu Lu, Feng Hu, and Weiyou Yang

Subjects
Materials Chemistry, General Chemistry
Abstract

We report the development of a high-performance UV photodetector based on W18O49/TiO2 nanofibers enabled by plasmon-induced synergistic photo/thermal enhancement; the responsivity of this device significantly exceeds those of TiO2-based photodetectors reported to date.

Published
2023

17. Soft gallstone-crushing robots

Author

Lin Xu, Heting Wu, Weiqi Qian, Yang Wang, Chris R. Bowen, Zhong Lin Wang, and Ya Yang

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science, Condensed Matter Physics
Published
2022

19. A multifunctional optical‐thermal logic gate sensor array based on ferroelectric <scp> BiFeO 3 </scp> thin films

Author

Li Wu, Yun Ji, Huiyu Dan, Chris R. Bowen, and Ya Yang

Subjects
BiFeO, Materials Science (miscellaneous), optical-thermal, photocurrent, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, photovoltage, Materials Chemistry, logic gate
Abstract

The growing need to process a diverse range of data has ignited effort in developing new multifunctional logic gate devices. In this article, we report a new form of all-in-one logic gate system that exploits the photoresponsivity of a self-powered multifunctional BiFeO3 (BFO) sensor material. The BFO sensor can not only detect both light intensity and temperature, but it can also execute three common logic gates of “AND”, “OR”, and “NOT” by converting optical and thermal inputs into electrical output. The diverse functionality of the BFO logic gate sensor array utilizes the unique light-and temperature-controlled energy band structure and carrier behavior of the BFO material. To demonstrate the potential, a 3 × 3 logic gate sensor matrix is developed, which successfully detected light and temperature distributions, and accurately produced the three basic logic gate operations. This work provides a new route to construct highly integrated multifunctional electronic devices for the advancement of large sensing, communication, and computing operations. (Figure presented.).

Published
2023

21. Freeze casting of porous monolithic composites for hydrogen storage

Author

George M. Neville, Rajan Jagpal, Joseph Paul-Taylor, Mi Tian, Andrew D. Burrows, Chris R. Bowen, and Timothy J. Mays

Subjects
Chemistry (miscellaneous), SDG 13 - Climate Action, General Materials Science, SDG 7 - Affordable and Clean Energy
Abstract

Hydrogen storage by adsorption offers operational benefits over energy intensive compression techniques. Incorporating physisorption materials in compression stores could improve hydrogen capacities, reducing the volume or pressure needed for storage vessels. However, such materials are often presented as fine powders and development efforts to date have predominantly focused on improving hydrogen uptake alone. Without due attention to industry-relevant attributes, such as handling, processability, and mechanical properties it is unlikely that these materials will find commercial application. In the paper, the desirable mechanical properties of hydrogen-adsorbent PIM-1 are exploited to yield a series of composite monoliths doped with a high surface area activated carbon, intended to act as pressure vessel inserts. Freeze casting techniques were successfully adapted for use with chloroform, facilitating the production of coherent and controlled three-dimensional geometries. This included the use of an innovative elastomeric mould made by additive manufacture to allow facile adoption, with the ability to vary multiple forming factors in the future. The composite monolith formed exhibited a stiffness of 0.26 GPa, a compressive strength of 6.7 MPa, and an increased BET surface area of 847 m2 g−1 compared to PIM-1 powders, signifying the first steps towards producing hydrogen adsorbents in truly useful monolithic forms.

Published
2022

23. Energy Harvesting from Ultra-low-Frequency Vibrations Through a Quasi-zero Stiffness Electromagnetic Energy Harvester

Author

Wei Wang, Ying Zhang, Chris R. Bowen, Zon-Han Wei, and Junyi Cao

Subjects
Acoustics and Ultrasonics, Energy harvesting, Mechanical Engineering, Rolling magnet, Electromagnetic, Quasi-zero stiffness, Ultra-low frequency
Abstract

Purpose: To scavenge vibrational energy from ultra-low frequency vibrations with low excitation levels, this paper presents a novel quasi-zero stiffness electromagnetic energy harvester (QZS-EMEH) by exploiting a rolling magnet system. Methods: By calculating the nonlinear restoring force exerted on the moving magnet, the parameter region that results in conditions of quasi-zero stiffness is determined, and a theoretical model of the QZS-EMEH is established. Based on the method of harmonic balance, the analytical solution of the QZS-EMEH is derived, and the influence of system parameters on the response characteristics and energy harvesting performance is discussed. Results: Numerical and theoretical results indicate that the QZS-EMEH can efficiently harness energy in a wide frequency range under low-level excitations. Furthermore, the nonlinear dynamics of the QZS-EMEH are investigated based on the bifurcation diagram, phase orbit, Poincaré map, and basin of attraction, demonstrating that appropriate initial conditions can lead to the high-energy orbit oscillation. Conclusions: Finally, realistic ambient vibration accelerations from a bus and a human body are applied to excite the QZS-EMEH, and the results illustrate that the QZS-EMEH can generate considerable electrical output power and has excellent application prospects.

Published
2022

25. Bistable energy harvesting backpack:Design, modeling, and experiments

Author

Zehao Hou, Wenyu Zha, Hongbo Wang, Wei-Hsin Liao, Chris R. Bowen, and Junyi Cao

Subjects
Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Bistable harvester, Nonlinear design, Fuel Technology, Nuclear Energy and Engineering, Nonlinear dynamics, SDG 7 - Affordable and Clean Energy, Energy harvesting backpack, Biomechanical energy harvesting
Abstract

Inspired by the dynamics of the noninertial systems, a novel bistable energy harvesting backpack is proposed that improves biomechanical energy harvesting performance. In contrast to traditional bistable energy harvesters that use an oblique compressed spring, a new bistable backpack is developed that uses the change of a spring torque direction located on a pinion. A detailed nondimensionalized model of the novel bistable energy harvesting backpack is developed and analyzed. Based on the dynamic bistable model, the influence of the carried backpack mass on the symmetry and the bifurcation frequency and amplitude of oscillation is examined to determine the ideal design parameters of the bistable backpack for experimental analysis and prototype manufacture. A comparison is made between the new bistable backpack and a traditional linear backpack under both harmonic and human walking excitation. The new bistable backpack design exhibits an improved frequency bandwidth from 1 Hz to 1.65 Hz at the base harmonic excitation of 2 m/s2 and the harvesting performance is enhanced from 2.34 W to 3.32 W when the walking speed is 5.6 km/h. The bench and treadmill tests verify the theoretical analysis and demonstrate the ability of the bistable energy harvesting backpack for broadband and performance enhancement.

Published
2022

26. HfO2-based ferroelectrics:From enhancing performance, material design, to applications

Author

Haiyan Chen, Xuefan Zhou, Lin Tang, Yonghong Chen, Hang Luo, Xi Yuan, Chris R. Bowen, and Dou Zhang

Subjects
Hardware_GENERAL, General Physics and Astronomy, SDG 7 - Affordable and Clean Energy, Physics and Astronomy(all)
Abstract

Nonvolatile memories are in strong demand due to the desire for miniaturization, high-speed storage, and low energy consumption to fulfill the rapid developments of big data, the Internet of Things, and artificial intelligence. Hafnia (HfO2)-based materials have attracted significant interest due to the advantages of complementary-metal-oxide-semiconductor (CMOS) compatibility, large coercive voltage, and superior ferroelectricity at an ultra-thin thickness. The comparable ferroelectricity to that of traditional perovskite materials and size advantage of HfO2 result in fascinating storage performance, which can be readily applicable to the fields of integrated non-volatile memories. This Review provides a comprehensive overview of recent developments in HfO2-based ferroelectrics with attention to the origin of ferroelectricity, performance modulation, and recent achievements in the material. Moreover, potential solutions to existing challenges associated with the materials are discussed in detail, including the wake-up effect, long-term fatigue behavior, and imprint challenges, which pave the way for obtaining HfO2-based ferroelectric materials and devices with long service life and high stability. Finally, the range of potential applications for these fascinating new materials is presented and summarized, which include non-volatile memories and neuromorphic systems. This Review intends to present the state-of-the-art HfO2-based ferroelectrics and to highlight the current challenges, possible applications, and future opportunities and can act as an update for recent developments in these intriguing materials and provide guidance for future researchers in the design and optimization of HfO2-based ferroelectric materials and devices.

Published
2022

28. On the mechanisms of DC conduction in electrospun PLZT/PVDF nanocomposite membranes

Author

James C. Sampson, Ashok Batra, Matthew E. Edwards, Sushma Kotru, Chris R. Bowen, and Ashok Vaseashta

Subjects
Materials Science(all), Mechanics of Materials, Mechanical Engineering, General Materials Science
Abstract

Designing dielectric nanocomposite films with excellent dielectric properties is of strategic importance for a variety of applications requiring pressure sensing, energy harvesting and storing, and biomedical technology. Hence, the present investigation aims at studying the dielectric properties of lead lanthanum zirconate titanate (PLZT)/poly(vinylidene fluoride) (PVDF) nanocomposite based membranes fabricated using traditional electrospinning techniques. The composites were investigated for structural and electrical conductivity properties at varying temperatures. While the Scanning Electron microscope revealed beaded and unannealed micro/nanofibers, the observations of temperature-dependent electrical conductivity imply that the charge carrier transport phenomena involve more than one conduction mechanism. This is an interesting observation and can be explained in terms of the contents and porosity of the composites. As compared to PVDF, PLZT/PVDF nanocomposite films have somewhat better conductivity. The space charge limited current was the dominant mechanism at high voltages, while the Schottky–Richardson conduction mechanism was dominating at high temperature, according to observed J–V characteristics. The DC activation energy was found to be different, as expected, due to the dynamically heterogeneous nature of PLZT aggregates within the polymer matrix; however, the films exhibit the well-known Arrhenius relationship. This indicates that the dominant conduction mechanism is observed to be electronic and thermally activated. Graphical abstract: [Figure not available: see fulltext.]

Published
2022

29. Understanding the Effects of Cross-Linking Density on the Self-Healing Performance of Epoxidized Natural Rubber and Natural Rubber

Author

James Boden, Chris R. Bowen, Antoine Buchard, Matthew G. Davidson, and Chris Norris

Subjects
Chemistry(all), General Chemical Engineering, Chemical Engineering(all), General Chemistry
Abstract

The demand for self-healing elastomers is increasing due to the potential opportunities such materials offer in reducing down-time and cost through extended product lifetimes and reduction of waste. However, further understanding of self-healing mechanisms and processes is required in order to develop a wider range of commercially applicable materials with self-healing properties. Epoxidized natural rubber (ENR) is a derivative of polyisoprene. ENR25 and ENR50 are commercially available materials with 25 and 50 mol % epoxidation, respectively. Recently, reports of the use of ENR in self-healing materials have begun to emerge. However, to date, there has been limited analysis of the self-healing mechanism at the molecular level. The aim of this work is to gain understanding of the relevant self-healing mechanisms through systematic characterization and analysis of the effect of cross-linking on the self-healing performance of ENR and natural rubber (NR). In our study, cross-linking of ENR and NR with dicumyl peroxide and sulfur to provide realistic models of commercial rubber formulations is described, and a cross-linking density of 5 × 10-5 mol cm-3 in sulfur-cured ENR is demonstrated to achieve a healing efficiency of 143% for the tensile strength. This work provides the foundation for further modification of ENR, with the goal of understanding and controlling ENR's self-healing ability for future applications.

Published
2022

30. High Efficiency Water Splitting using Ultrasound Coupled to a BaTiO

Author

Yan, Zhang, Hamideh, Khanbareh, Steve, Dunn, Chris R, Bowen, Hanyu, Gong, Nguyen Phuc Hoang, Duy, and Pham Thi Thuy, Phuong

Abstract

To date, a number of studies have reported the use of vibrations coupled to ferroelectric materials for water splitting. However, producing a stable particle suspension for high efficiency and long-term stability remains a challenge. Here, the first report of the production of a nanofluidic BaTiO

Published
2021

33. Enhanced photocurrent in ferroelectric Bi0.5Na0.5TiO3 materials via ferro-pyro-phototronic effect

Author

Yuan Liu, Yun Ji, Yanlong Xia, Li Wu, Chris R. Bowen, and Ya Yang

Subjects
Pyroelectric effect, Renewable Energy, Sustainability and the Environment, Photovoltaic effect, Ferro-pyro-phototronic effect, Coupling enhancement coefficient, Materials Science(all), Photocurrent, General Materials Science, SDG 7 - Affordable and Clean Energy, BNT, Electrical and Electronic Engineering
Abstract

The photocurrent generated by ferroelectric materials via the photovoltaic effect has latent applications in opto-electronic devices due to the introduction of a polarization-induced charge carrier separation and transport, which is absent in semiconducting p-n junctions. However, the precise mechanism of photocurrent production in photoelectric devices by a range of ferroelectric materials remains a topic of continued interest. Here we report a significant enhancement in the photocurrent of a ferroelectric Bi0.5Na0.5TiO3-based photoelectric device by ferro-pyro-phototronic effect. When compared with the generated photocurrent under illumination alone, the peak and platform photocurrents induced by the simultaneous use of both light and heating can be increased by 131% and 57%, respectively. The increase in photocurrent is found to increase with temperature, where the mechanism of enhancement is associated with the increase in pyroelectric coefficient, photoexcited carrier concentration and carrier mobility at higher operating temperatures. These factors also lead to a rapid response time of 84.2 ms. This work provides guidelines for photocurrent promotion in ferroelectric devices, pushing forward the potential applications of ferroelectric materials for self-powered photodetectors.

Published
2022

35. High Efficiency Water Splitting using Ultrasound Coupled to a BaTiO 3 Nanofluid

Author

Yan Zhang, Hamideh Khanbareh, Steve Dunn, Chris R Bowen, Hanyu Gong, Nguyen Phuc Hoang Duy, and Pham Thi Thuy Phuong

Subjects
General Chemical Engineering, General Engineering, General Physics and Astronomy, Medicine (miscellaneous), General Materials Science, Biochemistry, Genetics and Molecular Biology (miscellaneous)
Published
2022

36. Solid-Gas Phase Photo-Catalytic Behaviour of Rutile and TiO

Author

Manuel, Nuño, Vaia, Adamaki, David M, Tobaldi, Maria J, Hortigüela Gallo, Gonzalo, Otero-Irurueta, Chris R, Bowen, and Richard J, Ball

Subjects
sub-oxide, TiO2, photocatalysis, Article
Abstract

The solid-gas phase photo-catalytic activities of rutile TiO2 and TiOn (1 < n < 2) sub-oxide phases have been evaluated. Varying concentrations of Ti3+ defects were introduced into the rutile polymorph of titanium dioxide through carbo-thermal reduction at temperatures ranging from 350 °C to 1300 °C. The resulting sub-oxides formed were characterized by X-ray diffraction, X-ray photoelectron spectroscopy, scanning electron microscopy, impedance spectroscopy and UV-visible diffuse reflectance spectroscopy. The presence of Ti3+ in rutile exposed to high reduction temperatures was confirmed by X-ray diffraction. In addition, a Ti3+-Ti4+ system was demonstrated to enhance the photo-catalytic properties of rutile for the degradation of the air pollutants NO2 and CO2 under UV irradiation of wavelengths (λ) 376–387 nm and 381–392 nm. The optimum reduction temperature for photo-catalytic activity was within the range 350–400 °C and attributed to improved charge-separation. The materials that were subject to carbo-thermal reduction at temperatures of 350 °C and 400 °C exhibited electrical conductivities over one hundred times higher compared to the non-reduced rutile. The results highlight that sub-oxide phases form an important alternative approach to doping with other elements to improve the photo-catalytic performance of TiO2. Such materials are important for applications such as self-cleaning where particles can be incorporated into surface coatings.

Published
2018

37. Mechanical Structures and Smart Materials

Author

Chris R. Bowen and Chris R. Bowen

Subjects
Smart structures--Congresses, Smart materials--Congresses
Abstract

Selected, peer reviewed papers from the 2013 International Conference on Mechanical Structures and Smart Materials (ICMSSM 2013), November 16-17, 2013, Xiamen, China

Published
2014

38. New materials for micro-scale sensors and actuators

Author

Stephen A. Wilson, Renaud P.J. Jourdain, Qi Zhang, Robert A. Dorey, Chris R. Bowen, Magnus Willander, Qamar Ul Wahab, Safaa M. Al-hilli, Omer Nur, Eckhard Quandt, Christer Johansson, Emmanouel Pagounis, Manfred Kohl, Jovan Matovic, Björn Samel, Wouter van der Wijngaart, Edwin W.H. Jager, Daniel Carlsson, Zoran Djinovic, Michael Wegener, Carmen Moldovan, Rodica Iosub, Estefania Abad, Michael Wendlandt, Cristina Rusu, and Katrin Persson

Subjects
Conductive polymer, Transducer, Materials science, Fabrication, Mechanics of Materials, Mechanical Engineering, Scale (chemistry), Microtechnology, New materials, General Materials Science, Nanotechnology, Actuator, Piezoelectricity
Abstract

This paper provides a detailed overview of developments in transducer materials technology relating to their current and future applications in micro-scale devices. Recent advances in piezoelectric, magnetostrictive and shape-memory alloy systems are discussed and emerging transducer materials such as magnetic nanoparticles, expandable micro-spheres and conductive polymers are introduced. Materials properties, transducer mechanisms and end applications are described and the potential for integration of the materials with ancillary systems components is viewed as an essential consideration. The review concludes with a short discussion of structural polymers that are extending the range of micro-fabrication techniques available to designers and production engineers beyond the limitations of silicon fabrication technology.

Published
2007

40. Study of solid/gas phase photocatalytic reactions by electron ionization mass spectrometry

Author

Manuel, Nuño, Richard J, Ball, and Chris R, Bowen

Abstract

This paper describes a novel methodology for the real-time study of solid-gas phase photocatalytic reactions in situ. A novel reaction chamber has been designed and developed to facilitate the investigation of photoactive materials under different gas compositions. UV irradiation in the wavelength of ranges 376-387 and 381-392 nm was provided using specially designed high efficiency light emitting diode arrays. The experiments used air containing 190 ppm NO2 in a moist environment with a relative humidity of 0.1%. Photocatalytic samples consisting of pressed pellets of rutile and anatase crystalline forms of TiO2 were monitored over a period of 150 min. An ultra-high vacuum right angled bleed valve allowed a controlled flow of gas from the main reaction chamber at atmospheric pressure to a residual gas analyser operating at a vacuum of 10(-5) mbar. The apparatus and methodology have been demonstrated to provide high sensitivity (ppb). The rate of degradation of NO2 attributed to reaction at the TiO2 surface was sensitive to both crystal structures (anatase or rutile) and wavelength of irradiation.

Published
2014

47. Recent Advances in Organic and Organic–Inorganic Hybrid Materials for Piezoelectric Mechanical Energy Harvesting

Author

Thangavel Vijayakanth, David J. Liptrot, Ehud Gazit, Ramamoorthy Boomishankar, and Chris R. Bowen

Subjects
energy harvesting, piezoelectricity, Chemistry(all), organic–inorganic hybrids, Condensed Matter Physics, flexible electronics, ferroelectricity, organic composites, Electronic, Optical and Magnetic Materials, Biomaterials, Materials Science(all), Electrochemistry
Abstract

This article provides a comprehensive overview of piezo- and ferro-electric materials based on organic molecules and organic–inorganic hybrids for mechanical energy harvesting. Molecular (organic and organic–inorganic hybrid) piezo- and ferroelectric materials exhibit significant advantages over traditional materials due to their simple solution-phase synthesis, light-weight nature, thermal stability, mechanical flexibility, high Curie temperature, and attractive piezo- and ferroelectric properties. However, the design and understanding of piezo- and ferroelectricity in organic and organic–inorganic hybrid materials for piezoelectric energy harvesting applications is less well developed. This review describes the fundamental characterization of piezo- and ferroelectricity for a range of recently reported organic and organic–inorganic hybrid materials. The limits of traditional piezoelectric harvesting materials are outlined, followed by an overview of the piezo- and ferroelectric properties of organic and organic–inorganic hybrid materials, and their composites, for mechanical energy harvesting. An extensive description of peptide-based and other biomolecular piezo- and ferroelectric materials as a biofriendly alternative to current materials is also provided. Finally, current limitations and future perspectives in this emerging area of research are highlighted. This perspective aims to guide chemists, materials scientists, and engineers in the design of practically useful organic and organic–inorganic hybrid piezo- and ferroelectric materials and composites for mechanical energy harvesting.

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48. Growth of GaN epitaxial films on polycrystalline diamond by metal-organic vapor phase epitaxy.

Author

Quanzhong Jiang, Duncan W E Allsopp, and Chris R Bowen

Subjects
GALLIUM nitride, METAL organic chemical vapor deposition, SILICON
Abstract

Heat extraction is often essential in ensuring efficient performance of semiconductor devices and requires minimising the thermal resistance between the functional semiconductor layers and any heat sink. This paper reports the epitaxial growth of N-polar GaN films on polycrystalline diamond substrates of high thermal conductivity with metal-organic vapor phase epitaxy, by using a SixC layer formed during deposition of polycrystalline diamond on a silicon substrate. The SixC layer acts to provide the necessary structure ordering information for the formation of a single crystal GaN film at the wafer scale. It is shown that a three-dimensional island (3D) growth process removes hexagonal defects that are induced by the non-single crystal nature of the SixC layer. It is also shown that intensive 3D growth and the introduction of a convex curvature of the substrate can be deployed to reduce tensile stress in the GaN epitaxy to enable the growth of a crack-free layer up to a thickness of 1.1µm. The twist and tilt can be as low as 0.65° and 0.39° respectively, values broadly comparable with GaN grown on Si substrates with a similar structure. [ABSTRACT FROM AUTHOR]

Published
2017
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49. The emergent behavior of three-dimensional and three-phase thermal network model for the heterogeneous materials

Author

Jianhui Tian, Jialiang Wu, Chris R Bowen, Jinjuan Sun, Zaishuang Wang, and Guangchu Hu

Subjects
Mechanical engineering and machinery, TJ1-1570
Abstract

The study of the heat transfer properties of heterogeneous materials has been a world-wide research focus, for example in sectors related to thermal management in aerospace, architecture, and geology. In this paper, the emergent behavior and thermal conduction characteristics of three-dimensional and three-phase heterogeneous materials thermal networks are studied using the finite element method. The results show that the existence of percolation paths of each phase has a strong impact on the effective properties of the network when the contrast in thermal conductivities of each phase is high, and percolation also affects the effective thermal conductivity of the whole thermal network system. However, when the contrast in thermal conductivity between the two phases is low, the thermal networks exhibit a more consistent and “emergent” behavior, and the effective thermal conductivity of thermal networks at the same volume fraction changes to a lower extent from network to network. This paper also demonstrates that a logarithmic mixing rule can predict the effective thermal conductivity in the low contrast emergent region in three-dimensional networks, and the modeling method provides new approaches for the design of multi-phase composites and prediction of their thermal conduction properties.

Published
2023
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50. High Efficiency Water Splitting using Ultrasound Coupled to a BaTiO3 Nanofluid

Author

Yan Zhang, Hamideh Khanbareh, Steve Dunn, Chris R Bowen, Hanyu Gong, Nguyen Phuc Hoang Duy, and Pham Thi Thuy Phuong

Subjects
piezoelectric, ultrasound, piezocatalysis, ferroelectric, sonochemistry, Science
Abstract

Abstract To date, a number of studies have reported the use of vibrations coupled to ferroelectric materials for water splitting. However, producing a stable particle suspension for high efficiency and long‐term stability remains a challenge. Here, the first report of the production of a nanofluidic BaTiO3 suspension containing a mixture of cubic and tetragonal phases that splits water under ultrasound is provided. The BaTiO3 particle size reduces from approximately 400 nm to approximately 150 nm during the application of ultrasound and the fine‐scale nature of the particulates leads to the formation of a stable nanofluid consisting of BaTiO3 particles suspended as a nanofluid. Long‐term testing demonstrates repeatable H2 evolution over 4 days with a continuous 24 h period of stable catalysis. A maximum rate of H2 evolution is found to be 270 mmol h–1 g–1 for a loading of 5 mg l–1 of BaTiO3 in 10% MeOH/H2O. This work indicates the potential of harnessing vibrations for water splitting in functional materials and is the first demonstration of exploiting a ferroelectric nanofluid for stable water splitting, which leads to the highest efficiency of piezoelectrically driven water splitting reported to date.

Published
2022
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