Your search keyword '"MECHANICAL energy"' showing total 14,903 results

1. Electron transfer in a crystalline cytochrome with four hemes.

Author

Parson, William W., Huang, Jingcheng, Kulke, Martin, Vermaas, Josh V., and Kramer, David M.

Subjects

*CHARGE exchange, *BAND gaps, *ELECTRON diffusion, *SHEWANELLA oneidensis, *MECHANICAL energy, *PROTON transfer reactions, *SEMICLASSICAL limits

Abstract

Diffusion of electrons over distances on the order of 100 μm has been observed in crystals of a small tetraheme cytochrome (STC) from Shewanella oneidensis [J. Huang et al. J. Am. Chem. Soc. 142, 10459–10467 (2020)]. Electron transfer between hemes in adjacent subunits of the crystal is slower and more strongly dependent on temperature than had been expected based on semiclassical electron-transfer theory. We here explore explanations for these findings by molecular-dynamics simulations of crystalline and monomeric STC. New procedures are developed for including time-dependent quantum mechanical energy differences in the gap between the energies of the reactant and product states and for evaluating fluctuations of the electronic-interaction matrix element that couples the two hemes. Rate constants for electron transfer are calculated from the time- and temperature-dependent energy gaps, coupling factors, and Franck–Condon-weighted densities of states using an expression with no freely adjustable parameters. Back reactions are considered, as are the effects of various protonation states of the carboxyl groups on the heme side chains. Interactions with water are found to dominate the fluctuations of the energy gap between the reactant and product states. The calculated rate constant for electron transfer from heme IV to heme Ib in a neighboring subunit at 300 K agrees well with the measured value. However, the calculated activation energy of the reaction in the crystal is considerably smaller than observed. We suggest two possible explanations for this discrepancy. The calculated rate constant for transfer from heme I to II within the same subunit of the crystal is about one-third that for monomeric STC in solution. [ABSTRACT FROM AUTHOR]

Published

2024

2. A new flexible electrostatic generator using dielectric fluid.

Author

Yang, Ruisen, Yang, Meng, Fan, Peng, Lu, Tongqing, and Wang, Tiejun

Subjects

*LIQUID dielectrics, *ELECTROSTATIC accelerators, *MECHANICAL energy, *ELECTRICAL energy, *DIELECTRIC films, *ENERGY harvesting

Abstract

A new design of a flexible and compact electrostatic generator with dielectric fluid is presented in this work. The generator utilizes the flow of dielectric fluid between two dielectric films to change the capacitance and converts mechanical energy into electrical energy. We fabricate a dielectric fluid generator (DFG) and build up an experimental setup to investigate the performance of energy harvesting. We use an optimal triangular electromechanical cycle and achieve a maximum energy harvesting power of 1.83 mW with a device that the length of the longest side is 15 cm. The power density is 35.2 μW g−1, and the conversion efficiency is 17.8%. The parameters of the DFG, including the initial voltage, the applied force, and the mechanical loading time, are studied. As a demonstration, we use the DFG to harvest electrical energy from hand tapping to power LEDs. The DFG is flexible and compact, which is promising for harvesting energy from human movements. [ABSTRACT FROM AUTHOR]

Published

2023

3. Dual nanoparticles effect on the frictional and vibrational dissipation behaviors of polymer‐based water‐lubricated bearing materials.

Author

Li, Shifan, Dong, Conglin, Yuan, Chengqing, and Bai, Xiuqin

Subjects

MECHANICAL energy, DIESEL motors, TITANIUM dioxide, NANOPARTICLES, NANOCRYSTALS

Abstract

Marine water‐lubricated bearings have the advantages of environmental friendliness and long replacement cycle. However, when under the complex lubrication circumstance, the frictional and vibrational behaviors of water‐lubricated bearing always dissipate the mechanical energy output from the ship's diesel engine. Aiming at this problem and combining with previous research findings, in this paper, ceramic balls with similar mechanical properties to ship's main shaft were selected as the friction counterpart to simulate the operating conditions of marine water‐lubricated bearing. Meanwhile, dual nanoparticles of tungsten disulfide (WS2) and titanium dioxide (TiO2) were used to modify ultra‐high molecular weight polyethylene (UHMWPE) bearing material. The tribological and vibrational properties of the prepared composites were carefully investigated. The results showed that compared to pure UHMWPE, with the synergistic effect of 0.75 wt% WS2 and 0.9 wt% TiO2, the frictional and vibrational behaviors of the composites were reduced by 43.3% and 42.7%. Mechanical testing and microscopic characterization revealed the enhancement mechanism of these nanoparticles on UHMWPE. This study proposed a design strategy on marine water‐lubricated bearings for engineering application. [ABSTRACT FROM AUTHOR]

Published

2024

4. Reprogramming multi-stable snapping and energy dissipation in origami metamaterials through panel confinement.

Author

Almessabi, Abdulrahman, Li, Xuwen, Jamalimehr, Amin, and Pasini, Damiano

Subjects

*ENERGY dissipation, *MECHANICAL energy, *CYCLIC loads, *SAFETY appliances, *METAMATERIALS

Abstract

With a focus on a class of origami-inspired metamaterials, this work explores the role of panel confinement in their mechanical response under cyclic loading. The goal is twofold: (i) quantify the magnitude change in snapping force and energy dissipation attained by varying the severity of confinement of selected panels; and (ii) leverage insights to modulate in situ their mechanical response as dictated by a given application, hence propose panel confinement modulation as a practical design route for response reprogrammability. Through computational modelling, proof-of-concept fabrication and cyclic testing, we first identify and characterize the governing factors enabling either the alteration or the preservation of the snapping force magnitude during repeated cycles of forward and backward loading. Then, we demonstrate how the in situ modulation of the constrained distance between selected panels enables reprogramming their snapping sequence and energy dissipation. The results contribute to expanding the versatility and application of this class of origami metamaterial across sectors, from aerospace to protective equipment, requiring precise control of mechanical damping and energy dissipation. This article is part of the theme issue 'Origami/Kirigami-inspired structures: from fundamentals to applications'. [ABSTRACT FROM AUTHOR]

Published

2024

5. Multifunctional Triboelectric Metamaterials with Unidirectional Charge Transfer Channels for Linear Mechanical Motion Energy Harvesting.

Author

Chen, Haoyu, Shi, Jiahao, Yan, Lifu, and Akbarzadeh, Abdolhamid

Subjects

*MECHANICAL energy, *CLEAN energy, *ENERGY dissipation, *REACTION forces, *ISOTHERMAL efficiency

Abstract

Conventional triboelectric generators (TEGs) have been developed to mainly harvest the energy of linear mechanical motions and convert it usually into oscillating or pulsive, but not sustainable, electrical outputs. In this study, unidirectional charge transfer mechanisms are introduced to develop a triboelectric mechanical metamaterial (TMM) with sustainable electrical outputs. Density functional theory and experimental analyses demonstrate three minimum necessary components of TMMs fabricated by only two triboelectric materials (i.e., copper and PTFE) to generate sustainable electrical outputs. Under a wide range of compression‐tension strain of ±50%, the maximum open‐circuit voltage, short‐circuit current, and volumetric power density are 3860 V, 8 µA, and 365.3 kW m−3, respectively. Different from most conventional cellular solids, the mechanical energy dissipation of the TMMs increases quadratically with the unit cell number. High volumetric electromechanical efficiency is achieved when the unit cell is miniaturized. In addition to energy harvesting and mechanical energy dissipation, TMMs can sense the displacement by counting the number of distinctive peaks in the short‐circuit charge transfer or reaction force versus time curves. The extreme electromechanical functionalities of the TMMs facilitate their applications in intelligent suspension systems, miniaturized green power sources, and self‐sensing energy harvesters. [ABSTRACT FROM AUTHOR]

Published

2024

6. Biowaste‐Derived Triboelectric Nanogenerators for Emerging Bioelectronics.

Author

Bhaduri, Abhisikta and Ha, Tae‐Jun

Subjects

*NANOGENERATORS, *ELECTROSTATIC induction, *ELECTRONIC waste, *MECHANICAL energy, *BIOMEDICAL materials

Abstract

Triboelectric nanogenerators (TENGs) combine contact electrification and electrostatic induction effects to convert waste mechanical energy into electrical energy. As conventional devices contribute to electronic waste, TENGs based on ecofriendly and biocompatible materials have been developed for various energy applications. Owing to the abundance, accessibility, low cost, and biodegradability of biowaste (BW), recycling these materials has gained considerable attention as a green approach for fabricating TENGs. This review provides a detailed overview of BW materials, processing techniques for BW‐based TENGs (BW‐TENGs), and potential applications of BW‐TENGs in emerging bioelectronics. In particular, recent progress in material design, fabrication methods, and biomechanical and environmental energy‐harvesting performance is discussed. This review is aimed at promoting the continued development of BW‐TENGs and their adoption for sustainable energy‐harvesting applications in the field of bioelectronics. [ABSTRACT FROM AUTHOR]

Published

2024

7. Flexible Piezoelectric Energy Harvesters with Mechanoluminescence for Mechanical Energy Harvesting and Stress Visualization Sensing.

Author

Fu, Xueting, Cao, Yongquan, Song, Xinyue, Sun, Renbing, Jiang, Hai, Du, Peng, Peng, Dengfeng, and Luo, Laihui

Subjects

*MECHANICAL energy, *PIEZOELECTRIC detectors, *PIEZOELECTRIC composites, *DYNAMIC pressure, *STRESS concentration, *ENERGY harvesting, *PIEZOELECTRIC thin films

Abstract

Flexible piezoelectric energy harvesters (FPEHs) have wide applications in mechanical energy harvesting, portable device driving, and piezoelectric sensors. However, the poor output performance of piezoelectric energy harvesters and the intrinsic shortcoming of piezoelectric sensors that can only detect dynamic pressure limit their further applications. BaTiO3 (BT) and PVDF are deposited on the glass fiber electronic cloth (GFEC) by impregnation and spin‐coating methods, respectively, to form BT‐GFEC/PVDF piezoelectric composite films. A mixed solution of mechanoluminescence (ML) particles ZnS:Cu and PDMS are used as the encapsulation layer to construct a high‐performance ML‐FPEH with self‐powered electrical and optical dual‐mode response characteristics. Due to the interconnection structure of the piezoelectric films, the prepared ML‐FPEH illustrates a high effective energy harvesting performance (≈58 V, ≈43.56 µW cm−2). It can also effectively harvest mechanical energy from human activities. More importantly, ML‐FPEH can sense stress distribution of hand‐writing via ML to achieve stress visualization, making up for the shortcomings of piezoelectric sensors. This work provides a new strategy for endowing FPEH with dual‐mode sensing and energy harvesting. [ABSTRACT FROM AUTHOR]

Published

2024

8. A multi-objective optimal control approach to motor strategy changes in older people with mild cognitive impairment during obstacle crossing.

Author

Lu, Tung-Wu, Lu, Shiuan-Huei, Yu, Cheng-Hao, Wu, Kuan-Wen, and Kuan, Yi-Chun

Subjects

*MILD cognitive impairment, *TWO-way analysis of variance, *MECHANICAL energy, *OLDER people, *COGNITION, *MOTION capture (Human mechanics)

Abstract

Background: Mild cognitive impairment (MCI) may lead to difficulty maintaining postural stability and balance during locomotion. This heightened susceptibility to falls is particularly evident during tasks such as obstacle negotiation, which demands efficient motor planning and reallocation of attentional resources. This study proposed a multi-objective optimal control (MOOC) technique to assess the changes in motor control strategies during obstacle negotiation in older people affected by amnestic MCI. Methods: Motion data from 12 older adults with MCI and 12 controls when crossing obstacles were measured using a motion capture system, and used to obtain the control strategy of obstacle-crossing as the best compromise between the conflicting objectives of the MOOC problem, i.e., minimising mechanical energy expenditure and maximising foot-obstacle clearance. Comparisons of the weighting sets between groups and obstacle heights were performed using a two-way analysis of variance with a significance level of 0.05. Results: Compared to the controls, the MCI group showed significantly lower best-compromise weightings for mechanical energy expenditure but greater best-compromise weightings for both heel- and toe-obstacle clearances. This altered strategy involved a trade-off, prioritising maximising foot-obstacle clearance at the expense of increased mechanical energy expenditure. The MCI group could successfully navigate obstacles with a normal foot-obstacle clearance but at the cost of higher mechanical energy expenditure. Conclusions: MCI alters the best-compromise strategy between minimising mechanical energy expenditure and maximising foot-obstacle clearances for obstacle-crossing in older people. These findings provide valuable insights into how MCI impacts motor tasks and offer potential strategies for mitigating fall risks in individuals with MCI. Moreover, this approach could serve as an assessment tool for early diagnosis and a more precise evaluation of disease progression. It may also have applications for individuals with impairments in other cognitive domains. [ABSTRACT FROM AUTHOR]

Published

2024

9. Characterizing Rock-Breaking Performance of PDC Cutters via Stability Metrics and Energy consumption in FDEM Simulations.

Author

Wang, Xinrui, Zhang, Hui, Dong, Zhuoxin, Li, Jun, Qin, Cheng, Yang, Boyuan, and Zhou, Yuting

Subjects

*CUTTING force, *MECHANICAL energy, *ROCK music, *ENERGY consumption, *ANGLES

Abstract

As oil production increasingly transitions from shallow to deep formation, the need for efficient PDC cutters to drill through deep hard rock becomes paramount. Currently, there is a lack of effective methods for optimizing cutter shapes and their cutting parameters. This study addresses this gap by developing a rock-breaking mechanism model for PDC cutters and proposing a Stability Index (SI) based on cutting force variations during the cutting process. Using the FDEM method, we simulated the rock-breaking processes of planar, stinger, and machete cutters under various cutting depths and angles. SI and Mechanical Specific Energy (MSE) were employed as evaluation metrics to analyze the rock-breaking characteristics and determine the optimal cutting parameters for each cutter type. The results indicate that at shallow cutting depths, cutting force changes are minimal, predominantly causing plastic damage to the rock, resulting in lower stress and reduced wear on the PDC cutters. Conversely, at greater cutting depths, significant fluctuations in cutting force occur, leading to brittle failure and the generation of large cuttings. This sudden increase in cutting force can accelerate rock breaking but also increases the risk of cutter wear. Our findings suggest that the planar cutter offers stable performance with high cutting force requirements, optimal at a cutting depth of 1.5 mm and an angle of less than 20°. The stinger cutter, requiring lower cutting forces, performs best at a cutting depth of 2 mm and an angle of 20°. The machete cutter exhibits characteristics similar to the stinger cutter at shallow depths and the planar cutter at deeper depths, making it suitable for drilling at a depth of 2 mm and an angle of less than 10°. By balancing SI and MSE, this study provides a comprehensive approach to optimizing PDC cutter performance, enhancing drilling efficiency while minimizing cutter wear. [ABSTRACT FROM AUTHOR]

Published

2024

10. AI‐Enhanced Gait Analysis Insole with Self‐Powered Triboelectric Sensors for Flatfoot Condition Detection.

Author

Issabek, Moldir, Oralkhan, Sabyrzhan, Anash, Adeliya, Nurbergenova, Nuriya, Balapan, Azat, Yeshmukhametov, Azamat, Rakhmanov, Yeltay, and Kalimuldina, Gulnur

Subjects

*NANOGENERATORS, *MACHINE learning, *TACTILE sensors, *FOOT movements, *MECHANICAL energy, *ARCHES

Abstract

Flatfoot is an orthopedic malformation where the inner foot arch flattens during motion, potentially leading to chronic musculoskeletal issues. Monitoring foot conditions is essential, as existing screening methods often need more objectivity and cost‐effectiveness. This research develops an insole‐based screening device using self‐powered triboelectric nanogenerators (TENGs) as tactile sensors and Arduino hardware setup. TENG converts mechanical energy into electrical energy, offering simple fabrication, cost‐effectiveness, longevity, and high‐output power benefits. The device records the electrical output generated by foot movements via Arduino and sends data via Bluetooth to the processing tool. Machine learning algorithms employing the Random Forest Classifier process the data to detect flatfoot conditions accurately after training sessions. For data collection, 100 participants are asked to march and walk for the same duration and distance, ensuring consistent output. Analysis reveals that the insoles' middle sensors produce higher electricity levels in individuals with flatfoot, showing a uniform pressure distribution across the foot and contact in the arch area. In contrast, individuals with normal feet exert more pressure on the toe and heel foot areas. The system achieves an overall accuracy of 82%, demonstrating the insole's potential as a commercial flatfoot detection device. [ABSTRACT FROM AUTHOR]

Published

2024

11. Discrete Element Analysis of the Dynamic Mechanical Characteristics of Ballasted Track on Bridges Under Train Loading.

Author

Qian, Zhongxia, Xiao, Hong, Kong, Chao, Wei, Shaolei, Chi, Yihao, Zhang, Yawen, and Nadakatti, Mahantesh M.

Subjects

*DISCRETE element method, *VIBRATION (Mechanics), *DYNAMIC mechanical analysis, *DYNAMIC loads, *MECHANICAL energy, *BALLAST (Railroads)

Abstract

The operation and service performance of ballasted track on bridges face significant challenges due to high-speed railway train operations. To investigate the mechanical characteristics of ballasted track on bridges, field experiments were conducted. A coupling model of ballasted track on a simply-supported girder bridge was established using the coupling method of discrete element and multi-flexible body dynamics and analyzes the changes in ballast bed settlement deformation, stiffness and energy with increasing load cycles. The findings reveal that dynamic loading alters the original contact state of ballast particles, displaying notable anisotropy vertically and longitudinally and isotropy horizontally. The vibration of ballast particles on bridges is more pronounced than on the subgrade, with vibration acceleration under the sleeper at 150mm depth on the bridge being 2.89 times that on the subgrade foundation. As the system stabilizes, the interlocking effect among granular ballast particles strengthens, reducing mutual sliding and increasing ballast bed stiffness by approximately 7.8–9.5% compared to the initial state, while total energy and dissipated energy gradually decrease. It is recommended to monitor the quality of ballast particles under the sleeper of ballasted tracks on bridges, implement vibration mitigation measures, or periodically replace ballast particles. [ABSTRACT FROM AUTHOR]

Published

2024

12. Free-falling motion of an elastic rigid rod towards a Schwarzschild black hole.

Author

Machado, Luís, Natário, José, and Silva, Jorge Drumond

Subjects

*SCHWARZSCHILD black holes, *PARTIAL differential equations, *BOUNDARY value problems, *MECHANICAL energy, *WAVE equation

Abstract

We study the motion of an elastic rigid rod which is radially free-falling towards a Schwarzschild black hole. This is accomplished by reducing the corresponding free-boundary partial differential equation problem to a sequence of ODEs, which we integrate numerically. Starting with a rod at rest, we show that it is possible to choose its initial compression profile so that its midpoint falls substantially faster, or slower, than a free-falling particle with the same initial conditions. This seems to be a purely kinematic effect, since on average there is no net transfer of elastic energy to mechanical energy. [ABSTRACT FROM AUTHOR]

Published

2024

13. Mechanical power is maximized during contractile ring-like formation in a biomimetic dividing cell model.

Author

Sakamoto, Ryota and Murrell, Michael P.

Subjects

CELL division, CELLULAR mechanics, CELLULAR control mechanisms, MECHANICAL energy, MYOSIN

Abstract

The spatial and temporal dynamics of forces in cells coordinate essential behaviors like division, polarization, and migration. While intracellular signaling initiates contractile ring assembly during cell division, how mechanical forces coordinate division and their energetic costs remain unclear. Here, we develop an in vitro model where myosin-induced stress drives division-like shape changes in giant unilamellar vesicles (GUVs, liposomes). Myosin activity is controlled by light patterns globally or locally at the equator. Global activation causes slow, shallow cleavage furrows due to a tug-of-war between the equatorial and polar forces. By contrast, local activation leads to faster, deeper, and symmetric division as equatorial forces dominate. Dissociating the actin cortex at the poles is crucial for inducing significant furrowing. During furrowing, actomyosin flows align actin filaments parallel to the division plane, forming a contractile ring-like structure. Mechanical power is not greatest during contraction, but is maximized just before furrowing. This study reveals the quantitative relationship between force patterning and mechanical energy during division-like shape changes, providing insights into cell division mechanics. While biochemical regulation initiates cell division, how mechanical forces ensure successful division remains unclear. Here, the authors develop a biomimetic model of dividing cells to characterize the cytoskeleton's mechanical power prior to division. [ABSTRACT FROM AUTHOR]

Published

2024

14. How the acceleration phase influences energy flow and the resulting joint moments of the throwing shoulder in the deceleration phase of the javelin throw.

Author

Köhler, Hans-Peter, Schödlbauer, Maximilian, and Witt, Maren

Subjects

SHOULDER joint, MUSCULOSKELETAL system, KINEMATICS, MECHANICAL energy, PREVENTION of injury

Abstract

Introduction: The throwing motion in the javelin throw applies high loads to the musculoskeletal system of the shoulder, both in the acceleration and deceleration phases. While the loads occurring during the acceleration phase and their relationship to kinematics and energy flow have been relatively well investigated, there is a lack of studies focusing the deceleration phase. Therefore, the aim of this study is to investigate how the throwing arm is brought to rest, which resultant joint torques are placed on the shoulder and how they are influenced by the kinematics of the acceleration phase. Methods: The throwing movement of 10 javelin throwers were recorded using a 12-infrared camera system recording at 300 Hz and 16 markers placed on the body. Joint kinematics, kinetics and energy flow were calculated between the touchdown of the rear leg and the timepoint of maximum internal rotation after release +0.1 s. Elastic net regularization regression was used to predict the joint loads in the deceleration phase using the kinematics and energy flow of the acceleration phase. Results: The results show that a significant amount of energy is transferred back to the proximal segments, while a smaller amount of energy is absorbed. Furthermore, relationships between the kinematics and the energy flow in the acceleration phase and the loads placed on the shoulder joint in the deceleration phase, based on the elastic net regularized regression, could be established. Discussion: The results indicate that the loads of the deceleration phase placed on the shoulder can be influenced by the kinematics of the acceleration phase. For example, an additional upper body forward tilt can help to increase the braking distance of the arm and thus contribute to a reduced joint load. Furthermore, the energy flow of the acceleration phase can be linked to joint stress. However, as previously demonstrated the generation of mechanical energy at the shoulder seems to have a negative effect on shoulder loading while the transfer can help optimize the stress. The results therefore show initial potential for optimizing movement, to reduce strain and improve injury prevention in the deceleration phase. [ABSTRACT FROM AUTHOR]

Published

2024

15. Dynamic mechanical behavior and energy dissipation characteristics of low-temperature saturated granite under cyclic impact loading.

Author

Xu, Huaqiao, Rong, Chuanxin, Wang, Bin, Zhang, Qinghe, Shen, Zhijun, and Jin, Yi

Subjects

*IMPACT loads, *STRESS-strain curves, *MECHANICAL energy, *CYCLIC loads, *ENERGY dissipation

Abstract

To investigate the dynamic mechanical behavior and energy dissipation characteristics of low-temperature rock samples under cyclic impact loading, a temperature-controlled impact system that combines Hopkins bars with a low-temperature compensation device was used. Five temperature gradients were confirmed via a trial impact test, and impact tests were conducted under two kinds of impact air pressures. The macroscopic damage characteristics of rock samples under cyclic impact at different temperatures, dynamic stress-strain curves, changes in peak stress and strain, energy dissipation, and cumulative damage at different temperatures, and the macroscopic and microscopic structural characteristics of low-temperature rock samples after cyclic impact were analyzed in combination with damage. The findings indicated that low-temperature saturated granite primarily experienced tensile damage under cyclic impact loading, with the required number of impacts increasing with decreasing temperature, and rock samples exhibited freeze-induced brittleness and significantly increased fragmentation. The dynamic stress-strain curve generally exhibited rebound characteristics in the post-peak stage. With an increasing number of cycles, an overall decrease in peak stress was observed, whereas the peak strain and cumulative specific dissipated energy exhibited opposite trends. This trend was more pronounced at lower temperatures, with a significant increase in peak strain and specific energy amplitude. In addition, the cumulative damage factor of the rock samples increased at lower temperatures, consistent with macroscopic damage characteristics, and exhibited a negative correlation with peak stress. The degree of crack extension in the macroscopic samples corresponded with the observed fracture changes. Microanalysis (SEM) indicated that decreasing temperature resulted in freeze brittleness of the fracture surfaces, characterized by reduced flatness and an expansion of brittle cracks across the damage surface. The slip separation phenomenon became increasingly pronounced, and these observations were positively correlated with the cumulative damage value. [ABSTRACT FROM AUTHOR]

Published

2024

16. Gradient p‐Polyanion/n‐Polycation Heterojunction Endows Ionic Diodes with Vastly Boosted Output Voltage, Power Density and Sensitivity.

Author

Wang, Hongkun, Du, Mingyu, Jiang, Hao, Zhou, Ruixuan, Wang, Yan, Sui, Kunyan, and Fan, Wenxin

Subjects

*MECHANICAL energy, *HIGH voltages, *POWER density, *DIODES, *POLYANIONS

Abstract

Ionic diode‐based generators show great superiority in harvesting low‐frequency mechanical energy from human motions for various wearable applications. The major challenge is to improve their extremely limited output voltage for the miniaturization/simplicity of ionic diode‐based self‐powered devices as well as further improvement of mechanoelectric conversion performance. Herein, the construction of gradient polycation/polyanion heterojunction is demonstrated to vastly boost the output voltage, energy‐harvesting efficiency, and sensing performance of ionic diode. Besides an inherent potential at the polyanion/polycation heterojunction interface, the additional transmembrane potentials can be generated across gradient polyanion and polycation conductors of ionic diodes due to their gradient charge distribution. Consequently, the gradient ionic diode‐based generators produce much higher output voltage (306.53 mV) than previously reported homogeneous ones (4.1–135 mV). Meanwhile, the high output voltage imparts gradient ionic diode‐based generator with ultrahigh power density (50.16 µW cm−2 or 250.8 µW cm−3) and pressure‐perception sensitivity (43582 mV/MPa), which are dramatically increased by 162.76% and 128.71%, respectively, compare to those of homogeneous one. Impressively, the resulting diode‐based generators can generate ultralarge current density (≈0.52 mA cm−2) with ultralong discharge time (>400 s), thus enabling the continuous power generation under the low‐frequency pressure for various wearable and implantable applications. [ABSTRACT FROM AUTHOR]

Published

2024

17. Phosphor‐Loaded Triboelectric Film‐Based Multipurpose Triboelectric Nanogenerators for Highly‐Efficient Energy Harvesting, Sensing, and Self‐Illumination Applications.

Author

Paranjape, Mandar Vasant, Lee, Jun Kyu, Manchi, Punnarao, Graham, Sontyana Adonijah, Kurakula, Anand, Kavarthapu, Venkata Siva, and Yu, Jae Su

Subjects

*MECHANICAL energy, *NANOGENERATORS, *ENERGY harvesting, *INDIUM tin oxide, *ALUMINUM electrodes

Abstract

A novel approach is proposed for combining phosphor materials with triboelectric nanogenerators (TENGs) for mechanical energy harvesting and illumination applications. For this purpose, strongly reddish‐orange‐emitting Ba0.5Sr0.5Nb2O6:0.25 mol Eu3+ (BSNb:0.25Eu) phosphor materials are synthesized. The photoluminescence properties of the synthesized BSNb:0.25Eu are analyzed. The synthesized BSNb:0.25Eu is utilized as a dielectric filler inside a polydimethylsiloxane polymeric film due to its high dielectric properties to improve the overall dielectric properties of the composite film (CF). TENG devices are fabricated using phosphor‐loaded CFs as the tribonegative layer, transparent polyvinyl alcohol as the tribopositive layer, and aluminum as the conductive electrode. All the TENGs operate in a contact‐separation mode, and the highest electrical output is attained by optimizing the phosphor filler concentration in the CF. The optimized TENG exhibits excellent stability in long‐term operational tests, under varying harsh ambient temperatures. Indium tin oxide sputtered on both triboelectric films as an electrode and combined with a transparent hard substrate to obtain a fully transparent TENG. A self‐illuminating TENG (SI‐TENG) is fabricated by integrating near‐ultraviolet light‐emitting diodes between two identical TENGs. The SI‐TENG can harvest the mechanical energy available in the surrounding environment and illuminate it as a light source. Additionally, the proposed phosphor‐loaded polymer films can be employed for optical thermometry and mechanical energy harvesting via SI‐TENG on a large scale. [ABSTRACT FROM AUTHOR]

Published

2024

18. Superior Charge Density of Triboelectric Nanogenerator via Trap Engineering.

Author

Liu, Xiaoru, Zhao, Zhihao, Zhang, Baofeng, Hu, Yuexiao, Qiao, Wenyan, Gao, Yikui, Wang, Jing, Guo, Ziting, Zhou, Linglin, Wang, Zhong Lin, and Wang, Jie

Subjects

*MECHANICAL energy, *ELECTRICAL energy, *ENERGY density, *BARIUM titanate, *DIELECTRIC loss

Abstract

Triboelectric nanogenerator (TENG) offers a novel approach for converting high‐entropy mechanical energy into electrical energy, yet achieving high charge density remains critical. Optimizations using dielectrics with high specific capacitance have mitigated air breakdown, but charge loss within dielectrics persists as a limiting factor. Here, based on poly(vinylidene fluoride–trifluoroethylene–chlorofluoroethylene) (P(VDF‐TrFE‐CFE)) with high specific capacitance, (P(VDF‐TrFE‐CFE)) composites’ trap density and energy are engineered using high‐polarity interfaces from barium titanate (BTO) nanoparticles and dense chain segment stacking induced by electrostatic interaction with polyetherimide (PEI) to enhance charge retention capability. With modified high interfacial traps, an ultrahigh charge density of 9.23 mC m−2 is achieved in external charge excitation (ECE) TENG using 0.2 vol% PEI/P(VDF‐TrFE‐CFE) film, marking the highest charge density reported for single‐unit TENGs. This work provides novel material strategies for high‐performance TENGs, paving the way for their large‐scale practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

19. Aluminosilicate-based material fabricated from fly ash for energy harvesting application.

Author

Thongthapthai, Wittawat, Harnchana, Viyada, Sintusiri, Jirapan, Payakaniti, Panjasila, Thongbai, Prasit, and Amornkitbamrung, Vittaya

Subjects

*MECHANICAL energy, *ENERGY harvesting, *FLY ash, *DIELECTRIC properties, *PERMITTIVITY, *ELECTROSTATIC induction

Abstract

A triboelectric nanogenerator (TENG) is an emerging energy harvesting technology that utilizes the combination of triboelectrification and electrostatic induction to collect wasted mechanical energy and convert it into electricity. In this work, an aluminosilicate (AS)-based composite, considered as a potential alternative to cement material, has been developed for the fabrication of TENGs. Herein, the AS material is synthesized through the alkali activation of fly ash using a mixture of sodium hydroxide (NaOH) and sodium silicate (Na 2 SiO 3) solutions as activating agents. The electrical output of AS TENGs can be optimized by tuning the liquid-to-solid powder (L/S) ratio during the fabrication of AS composites. The AS composites fabricated at different L/S ratios exhibit the variations in dielectric properties, surface morphology and microstructure. It is found that a high dielectric constant is not the only requirement for achieving optimal TENG output performance. The contribution of dielectric properties and microstructures of the AS composites on TENG performance is discussed. The AS composite with an optimal L/S ratio of 0.5 results in the highest TENG power output density of 2.78 W/m2. Additionally, the versatility of AS TENG to harvest mechanical energy and its application as a power source for portable electronic device are demonstrated. This research has proposed the promising aspect of AS composites as alternative construction materials capable of harvesting mechanical energy, which is essential for the development of green and sustainable power sources. [ABSTRACT FROM AUTHOR]

Published

2024

20. Breaking dielectric dilemma via polymer functionalized perovskite piezocomposite with large current density output.

Author

Khan, Asif Abdullah, Mathur, Avi, Yin, Lu, Almadhoun, Mahmoud, Yin, Jian, Bagheri, Majid Haji, Fattah, Md Fahim Al, Rajabi-Abhari, Araz, Yan, Ning, Zhao, Boxin, Maheshwari, Vivek, and Ban, Dayan

Subjects

NANOGENERATORS, DIELECTRIC strength, ENERGY harvesting, MECHANICAL energy, PERMITTIVITY

Abstract

Organometal halide perovskite (OHP) composites are flexible and easy to synthesize, making them ideal for ambient mechanical energy harvesting. Yet, the output current density from the piezoelectric nanogenerators (PENGs) remains orders of magnitude lower than their ceramic counterparts. In prior composites, high permittivity nanoparticles enhance the dielectric constant (ϵr) but reduce the dielectric strength (Eb). This guides our design: increase the dielectric constant by the high ϵr nanoparticle while enhancing the Eb by optimizing the perovskite structure. Therefore, we chemically functionalize the nanoparticles to suppress their electrically triggered ion migration for an improved piezoelectric response. The polystyrene functionalizes with FAPbBr2I enlarges the grains, homogenizes the halide ions, and maintains their structural integrity inside a polymer. Consequently, the PENG produces a current density of 2.6 µAcm−2N−1. The intercalated electrodes boost the current density to 25 µAcm−2N−1, an order of magnitude enhancement for OHP composites, and higher than ceramic composites. By functionalizing polystyrene with perovskite FAPbBr2I, both the dielectric constant and dielectric strength are controlled, leading to energy-dense composite films for piezoelectric nanogenerators with normalized current density of 25 µA.cm−2 N−1 [ABSTRACT FROM AUTHOR]

Published

2024

21. High-performance photon-driven DC motor system.

Author

Lin, Dingyi, Deng, Fujin, Hua, Wei, Cheng, Ming, Chen, Zhe, and Wang, Zhiming

Subjects

POWER transmission, MECHANICAL energy, ELECTRICAL energy, ELECTROMAGNETIC compatibility, OPEN innovation

Abstract

Direct current (DC) motors are crucial in drones, robotics, and electrical devices. Conventionally, the DC motor is driven by a switching electricity converter, which utilizes electrical energy to drive mechanical motion. However, the rapid on-off switching actions in the switching electricity converter would cause electromagnetic interference (EMI), impairing the functionality of drive systems. Here, we propose a photon-driven DC motor system based on photonic converter, which utilizes optical energy to drive mechanical motion, and therefore avoids EMI derived from electrical switching and immunizes against EMI during electrical energy transmission in conventional switching electricity-driven DC motor system. The operation principle and power modulation-based speed control are also presented for the proposed photon-driven DC motor system. The experiments demonstrate that the motor accurately follows the speed reference and withstands load disturbances. This innovation opens new potential for DC motor applications by improving electromagnetic compatibility. The researchers showcase a photon-driven DC motor system, that utilizes optical energy to drive mechanical motion, avoids EMI derived from electrical switching action and immunizes against EMI in conventional electricity-driven DC motor systems [ABSTRACT FROM AUTHOR]

Published

2024

22. Grid Integration of Offshore Wind Energy: A Review on Fault Ride Through Techniques for MMC-HVDC Systems.

Author

Kumar, Dileep, Shireen, Wajiha, and Ram, Nanik

Subjects

*RENEWABLE energy sources, *WIND power, *OFFSHORE wind power plants, *MECHANICAL energy, *FAULT location (Engineering)

Abstract

Over the past few decades, wind energy has expanded to become a widespread, clean, and sustainable energy source. However, integrating offshore wind energy with the onshore AC grids presents many stability and control challenges that hinder the reliability and resilience of AC grids, particularly during faults. To address this issue, current grid codes require offshore wind farms (OWFs) to remain connected during and after faults. This requirement is challenging because, depending on the fault location and power flow direction, DC link over- or under-voltage can occur, potentially leading to the shutdown of converter stations. Therefore, this necessitates the proper understanding of key technical concepts associated with the integration of OWFs. To help fill the gap, this article performs an in-depth investigation of existing alternating current fault ride through (ACFRT) techniques of modular multilevel converter-based high-voltage direct current (MMC-HVDC) for OWFs. These techniques include the use of AC/DC choppers, flywheel energy storage devices (FESDs), power reduction strategies for OWFs, and energy optimization of the MMC. This article covers both scenarios of onshore and offshore AC faults. Given the importance of wind turbines (WTs) in transforming wind energy into mechanical energy, this article also presents an overview of four WT topologies. In addition, this article explores the advanced converter topologies employed in HVDC systems to transform three-phase AC voltages to DC voltages and vice versa at each terminal of the DC link. Finally, this article explores the key stability and control concepts, such as small signal stability and large disturbance stability, followed by future research trends in the development of converter topologies for HVDC transmission such as hybrid HVDC systems, which combine current source converters (CSCs) and voltage source converters (VSCs) and diode rectifier-based HVDC (DR-HVDC) systems. [ABSTRACT FROM AUTHOR]

Published

2024

23. Evaluation of Mechanical Energy Consumption in WPC Production from Pine (Pinus sylvestris) and Hemp (Cannabis sativa L.) with ABS Thermoplastic Additions.

Author

Roman, Kamil, Grzegorzewska, Emilia, Fedorowicz, Katarzyna, and Michalczewski, Jakub

Subjects

*WOOD chips, *MECHANICAL energy, *ENERGY consumption, *HOT water, *LIGNOCELLULOSE, *SCOTS pine

Abstract

This study investigates lignocellulosic biocomposites' physicochemical properties and strength parameters with varying thermoplastic content. Biocomposites were prepared using wood (Pinus sylvestris) or hemp shives (Cannabis sativa L.) combined with 25% and 50% ABS regranulate. The research focused on evaluating the mechanical energy consumption during the compaction of wood-ABS biocomposites with different pine fractions pretreated with hot water extraction (HWE) and analyzing the relationship between strength and thermoplastic content. Results indicate that the composition of the mixture and the size of the hemp shives fraction did not significantly influence energy consumption during densification. Energy values ranged from 1.234 × 10⁻8 J to 8.296 × 10⁻8 J. While the densification of pine after HWE was unsuccessful without ABS, preheating the mixtures with ABS facilitated the production of a uniform composite. The work required for densification ranged from 1.404 × 10⁻5 J to 2.711 × 10⁻5 J for fractions without ABS. For mixtures with ABS, the work required was 1.954 × 10⁻5 J for fraction 0 ÷ 0.4 (f1) and 0.042 × 10⁻5 J for fraction 0.4 ÷ 0.8. [ABSTRACT FROM AUTHOR]

Published

2024

24. Textile Triboelectric Nanogenerator: Future Smart Wearable Energy‐Integration Technology.

Author

Zhao, Zhizhen and Hu, Youfan

Subjects

*NANOGENERATORS, *WEARABLE technology, *ENERGY harvesting, *ELECTROTEXTILES, *MECHANICAL energy, *TRIBOELECTRICITY, *ELECTROSTATIC induction

Abstract

Triboelectric nanogenerator (TENG) technology based on the coupling of triboelectric effect and electrostatic induction has shown great potential in the energy‐integration field. In recent years, the emerging of textile triboelectric nanogenerators (t‐TENGs) has enabled the rapid development of wearable energy‐integration technologies. The efficient mechanical energy harvesting and self‐powered sensing capabilities of TENGs and the advantages of textiles can be combined to create t‐TENGs for the construction of smart fabrics. Herein, a comprehensive review of t‐TENGs is presented. This review begins from the working mechanism of conventional TENGs, after which the construction of triboelectric layers with fibers, yarns, and fabrics is discussed. Then, the different working modes of t‐TENGs derived from TENGs, the critical features of t‐TENGs and power management strategies are discussed. Finally, this review ends with a description of the recent progress in typical wearable applications based on t‐TENGs. The light weight, low cost, flexibility, stretchability, washability, diverse material options, and excellent electrical performance of t‐TENGs will make this technology a great choice for smart energy‐integrated wearable devices in the future. [ABSTRACT FROM AUTHOR]

Published

2024

25. Review of recent advances in piezoelectric material for nanogenerator application: preparation methods, material selection, performance, applications, and future outlook.

Author

Mohamed Mustakim, Nurul Syafiqah, Kamaruzaman, Dayana, Abdullah, Mohd Hanapiah, Malek, Mohd Firdaus, Parimon, Norfarariyanti, Ahmad, Mohd Khairul, Abu Bakar, Suriani, Vasimalai, Nagamalai, Ramakrishna, Seeram, and Mamat, Mohamad Hafiz

Subjects

*PIEZOELECTRIC materials, *ELECTRIC power, *NANOGENERATORS, *MECHANICAL energy, *PIEZOELECTRIC devices

Abstract

Extensive research has focused on green and renewable energies to address the increasing demand for flexible, reliable, and self-sustaining advanced technology and electrical supplies. Piezoelectric nanogenerators (PENGs) have garnered significant interest as a pioneering energy-harvesting technology, due to their notable advancements and capacity to effectively capture and convert mechanical energy from the environment into electrical power. This review article seeks to cover the latest developments and innovations in piezoelectric materials for PENG applications. It explores key topics, such as the strategic selection of piezoelectric materials to optimize energy-harvesting efficiency, advancements in fabrication techniques, and the evaluation of PENGs performance. Throughout this manuscript, critical points are highlighted that require further investigation in the field of high-performance piezoelectric material fabrication. Ongoing research is crucial for improving the flexibility and durability of functional materials, thus advancing the development of superior electronic devices with enhanced piezoelectric properties. Furthermore, addressing enhancements in the electromechanical properties of current piezoelectric materials is imperative. This review article aims to support researchers in their quest for a comprehensive understanding of piezoelectric mechanisms and offers valuable insights for the progression and refinement of PENGs, which have broad potential applications. An overview of the PENGs applications, piezoelectric materials selection, fabrication methods and PENGs performance discussed in this review paper. [ABSTRACT FROM AUTHOR]

Published

2024

26. Study on the mechanism and prevention system of creep induced instability of isolated coal pillars considering time effect.

Author

Song, Weihua, Yu, Shiqi, and Rong, Hai

Subjects

*COAL mining, *ROCK creep, *IMPACT (Mechanics), *ROCK properties, *MECHANICAL energy, *EMISSION control, *ACOUSTIC emission testing, *COAL gasification

Abstract

In response to the frequent occurrence of impact events in isolated coal pillars between the upper (lower) mountain areas of mining areas under conditions without obvious mining disturbance, this study takes multiple isolated coal pillar impact events that occurred in Zhaolou Coal Mine and Gengcun Coal Mine as examples. It conducts a mechanism study on the creep-induced impact ground pressure of isolated coal pillars considering the time effect. The occurrence of such impact ground pressure accidents often exhibits significant "lag" and "spontaneity". Due to the unclear mechanism of occurrence and the difficulty in grasping the unloading timing, this type of impact ground pressure has become a typical hidden disaster, posing a serious threat to the deep mining of coal mines. Based on the analysis of the creep mechanical properties of coal and rock mass, the uniaxial compression acoustic emission creep test of coal body, and the FLAC3D numerical simulation, a creep instability impact mechanical model of coal and rock mass is established. This model reveals the mechanism of creep instability impact and the stress evolution law of coal and rock mass during creep. The mechanical and energy criteria for the occurrence of impact ground pressure in isolated coal pillars under the action of unstable creep are proposed. The study shows that the action of high ground stress is a necessary condition for the occurrence of "lag-type" impact ground pressure in isolated coal pillars. Long-term unstable creep will weaken the support strength of the entry. When the elastic energy accumulated in the isolated coal pillar exceeds its ultimate bearing capacity, impact instability will occur. Based on the mechanism of occurrence of such impact accidents, targeted deep hole blasting unloading measures are proposed, providing a good reference value for the prevention and control of "lag-type" impact ground pressure accidents in isolated coal pillars. [ABSTRACT FROM AUTHOR]

Published

2024

27. A comparative simulation study of piezoelectric properties in zigzag and armchair boron nitride nanotubes: by discovering a pioneering protocol.

Author

Adel, Moein, Keyhanvar, Peyman, Zahmatkeshan, Masoumeh, Tavangari, Zahed, and Keyhanvar, Neda

Subjects

*BORON nitride, *PIEZOELECTRICITY, *MECHANICAL energy, *ENERGY harvesting, *FINITE element method

Abstract

Piezoelectric nanostructures have attracted significant attention owing to their capacity for converting mechanical energy into electrical energy, enabling applications in biomedical fields, actuators, and energy harvesting devices. Boron nitride nanotubes (BNNTs) exhibit unique properties that make them attractive candidates for piezoelectric applications. However, the influence of BNNT chiralities on their piezoelectric behavior has not been thoroughly explored. In this study, we investigated the piezoelectric effect of zigzag and armchair chiralities of BNNT structures, aiming to elucidate the relationship between chirality and piezoelectric response by discovering a novel protocol for simulating the electrical behavior of BNNTs at the nanoscale level. We employed a computational method to examine the piezoelectric potential of BNNT structures. First, we established an equivalent-sized three-dimensional (3D) model of zigzag and armchair BNNT structures using nanotube modeler software. The obtained models were then subjected to mesh analysis to generate finite element method simulations. The simulations were finally performed to analyze the electrical response of the BNNT structures under external mechanical forces. We observed that the electrical responses of zigzag BNNT were 1.6 times greater than armchair one. In conclusion, our study sheds light on the piezoelectric potential of zigzag and armchair chiralities of BNNT structures. Furthermore, our findings contribute to the understanding of the electrical properties of BNNTs and their potential for various medical and industrial applications. The knowledge gained from this study provides a foundation for further research and development in the field of piezoelectric nanostructures, paving the way for innovative advancements in nanotechnology. [ABSTRACT FROM AUTHOR]

Published

2024

28. Relationship of peak capillary blood lactate accumulation and body composition in determining the mechanical energy equivalent of lactate during sprint cycling.

Author

Meixner, Benedikt Johannes, Nusser, Valentin, Koehler, Karsten, Sablain, Mattice, Boone, Jan, and Sperlich, Billy

Subjects

*BLOOD lactate, *BODY composition, *MECHANICAL energy, *COOLDOWN, *REGRESSION analysis

Abstract

Aim: A 15-s all-out sprint cycle test (i.e., νLamax-test) and the post-exercise change in capillary blood lactate concentration is an emerging diagnostic tool that is used to quantify the maximal glycolytic rate. The goal of this study was to determine the relation between 15 s-work, change in capillary blood lactate concentration (∆La) and body composition in a νLamax-test. Method: Fifty cyclists performed a 15 s all-out sprint test on a Cyclus2 ergometer twice after a previous familiarization trial. Capillary blood was sampled before and every minute (for 8 min) after the sprint to determine ∆La. Body composition was determined employing InBody720 eight-electrode impedance analysis. Result: Simple regression models of fat-free mass (FFM) and also the product of FFM and ∆La showed similar ability to predict 15 s-work (R2 = 0.79; 0.82). Multiple regression combining both predictors explains 93% of variance between individuals. No differences between males and females were found regarding 15 s-work relative to the product of fat-free mass and ∆La. Considering pairs of similar FFM, a change 1 mmol/l of ∆La is estimated to be equal to 12 J/kg in 15 s-work (R2 = 0.85). Discussion: Fifteen s-work is both closely related to FFM and also the product of ∆La and lactate-distribution space approximated by FFM. Differences in 15 s-work between males and females disappear when total lactate production is considered. Considering interindividual differences, the mechanical energy equivalent of blood lactate accumulation seems a robust parameter displaying a clear relationship between ∆La and 15 s-work relative to FFM. [ABSTRACT FROM AUTHOR]

Published

2024

29. High-performance triboelectric nanogenerator based on biocompatible electrospun polycaprolactone nanofiber and counter convex PDMS for low-frequency mechanical energy harvesting.

Author

Nguyen, Vu Viet Linh, Vu, Thi Kieu Tien, Huynh, Dai Phu, and Bui, Van-Tien

Subjects

*NANOGENERATORS, *MECHANICAL energy, *ENERGY harvesting, *OPEN-circuit voltage, *SHORT-circuit currents, *POLYCAPROLACTONE

Abstract

Triboelectric nanogenerators (TENGs) made from biocompatible materials serve as promising integrated power sources for portable wearable electronics due to many advantages such as lightweight, high flexibility, simple technique, and excellent breathability. In this work, we report the fabrication of electrospun polycaprolactone micro-nanofiber films (s-PCL) and convex-microdome-patterned polydimethylsiloxane (c-PDMS) utilizing electrospinning and micromolding techniques. These materials, s-PCL and c-PDMS, are utilized as positively and negatively charged tribosurfaces, respectively, in the development of a bioTENG device. The developed TENG device can generate a superior power output of 2 mW with an open-circuit voltage (VOC) of 188 V and short-circuit current (ISC) of 18.5 µA, even under a low triggering frequency of 5 Hz. In addition, TENG possesses outstanding durability and output performance stability over a continuous operation of nearly 16,000 cycles. Furthermore, the TENG demonstrates its capacity to harvest mechanical energy and convert it into electricity, capable of directly illuminating more than 100 LEDs. The electrospun s-PCL- and c-PDMS-based TENG can be considered for self-powdered wearable devices attached to fingers, wrists, feet, and other human body parts. [ABSTRACT FROM AUTHOR]

Published

2024

30. Study on the mechanical properties and energy absorption of Gyroid sandwich structures with different gradient rules.

Author

Hao, Bo, Zhao, Yuxin, and Zhu, Zhiming

Subjects

*SANDWICH construction (Materials), *SINE function, *UNIFORM spaces, *FINITE element method, *MECHANICAL energy

Abstract

In the present study, a series of lattice structures with Gyroid minimal surfaces were meticulously designed to incorporate linear density gradients and two distinct trigonometric function-based density gradients. These advanced architectures were subsequently compared and contrasted with a uniform lattice sandwich structure. The mechanical behavior and energy absorption characteristics of the four lattice sandwich structures were rigorously investigated through a combination of experimental testing and finite element analysis (FEA). The results of this comprehensive analysis revealed that during compression, all four gradient lattice structures exhibited varying degrees of shear slip, which manifested as discernible discrepancies in their respective stress–strain curves. Relative to the uniform lattice structure, the linear gradient lattice sandwich structure exhibited an enhancement in elastic modulus by 1.69%, while the square sine function gradient lattice sandwich structure showed a significant increase of 14.45% in elastic modulus. Conversely, the square cosine function gradient lattice sandwich structure experienced a reduction in elastic modulus by 9.61%. Employing either a linear gradient or a square sine function density gradient design was found to augment the load-bearing capacity of the uniform lattice structure. Notably, when the strain in the uniform structure reached densification strain, it absorbed energy exceeding 5.842 MJ/m3, indicating superior energy absorption capabilities among the four structures examined, thus rendering it particularly suitable for applications where high energy absorption is imperative. Furthermore, finite element simulations were conducted to validate the experimental findings, and the simulation results demonstrated a high degree of correlation with the experimental data, with discrepancies less than 6%, thereby confirming the reliability of the FEA model in predicting the performance of these intricate lattice structures. [ABSTRACT FROM AUTHOR]

Published

2024

31. Low moisture texturised protein from sunflower press cake.

Author

Morejón Caraballo, Sophie, Fischer, Simon Vincent, Masztalerz, Klaudia, Lech, Krzysztof, Rohm, Harald, and Struck, Susanne

Subjects

*MEAT alternatives, *EXTRACELLULAR matrix proteins, *MECHANICAL energy, *SUNFLOWERS, *MOISTURE

Abstract

Summary: The aim of the present study was to texturise protein from sunflower press cake (SPC) for being consumed as dry snack or, in its hydrated state, as a meat analogue. In preliminary experiments, feed moisture (15–25 g 100 g−1) and extrusion temperature (180 °C–200 °C) were varied when processing commercial sunflower protein flour with a protein content of 51.8 g per 100 g dry matter using low moisture single‐screw extrusion. The extrudates were analysed with regard to specific mechanical energy needs, texture properties in dry and hydrated state, colour, expansion ratio and water binding capacity. Extrusion parameters for achieving maximum expansion, textural force and minimal product moisture were found to be 180 °C and 15 g 100 g−1. Consequently, texturised protein was derived from deoiled SPC using these extrusion parameters. Initial deoiling of the press cake was necessary as it improved texturisation; a higher SME input reached led to increased cross‐linking of the protein matrix. The light coloured and significantly expanded extrudates with high water binding capacity and could serve as basis for further development of snack products or meat analogues. [ABSTRACT FROM AUTHOR]

Published

2024

32. A comprehensive review of advances in design of micro-texture on tool surface and its cutting performance.

Author

Niu, Qiulin, Wu, Meiyi, Liu, Lipeng, Gao, Jingyi, and Jing, Lu

Subjects

*GEOMETRIC surfaces, *MECHANICAL energy, *PRODUCTION methods, *CUTTING tools, *PERFORMANCE theory

Abstract

By producing micro-textures with different geometric parameters on the tool surface, the cutting performance of the tool can be effectively improved. Scientists have carried out the design and development of microstructures on the surface of tools based on the study of the performance of microstructured tools. Based on this, this theory first summarizes the production methods of surface microstructures, which are divided into photothermal energy composite processing, electrothermal energy composite processing, and mechanical energy processing according to the different energies. The effects of microtexturing on tool wear, tool strength, and tool life are then examined. Then, the geometric design of surface microtexturing tools from simple texturing to heterogeneous texturing is reviewed, and the mechanism of microtexturing tools is analyzed. Finally, the development direction of tools with surface micro-texture is given to provide guidance for the optimized design of the micro-texture of tool surfaces. [ABSTRACT FROM AUTHOR]

Published

2024

33. Application of catalytic technology based on the piezoelectric effect in wastewater purification.

Author

Liu, Gaolei, Li, Chengzhi, Li, Donghao, Xue, Wendan, Hua, Tao, and Li, Fengxiang

Subjects

*PIEZOELECTRICITY, *WATER purification, *PIEZOELECTRIC materials, *SEWAGE, *MECHANICAL energy, *AIR purification, *ENERGY harvesting

Abstract

[Display omitted] • The catalytic mechanism and material preparation based on the piezoelectric effect. • The application of the piezoelectric effect in wastewater purification is expounded. • The development of the piezoelectric effect-assisted water purification technology. • The challenges and prospects of the piezoelectric effect in wastewater purification. The demands of human life and industrial activities result in a significant influx of toxic contaminants into aquatic ecosystems. In particular, organic pollutants such as antibiotics and dye molecules, bacteria, and heavy metal ions are represented, posing a severe risk to the health and continued existence of living organisms. The method of removing pollutants from water bodies by utilizing the principle of the piezoelectric effect in combination with chemical catalytic processes is superior to other wastewater purification technologies because it can collect water energy, mechanical energy, etc. to achieve cleanliness and high removal efficiency. Herein, we briefly introduced the piezoelectric mechanisms and then reviewed the latest advances in the design and synthesis of piezoelectric materials, followed by a summary of applications based on the principle of piezoelectric effect to degrade pollutants in water for wastewater purification. Moreover, water purification technologies incorporating the piezoelectric effect, including piezoelectric effect-assisted membrane filtration, activation of persulfate, and battery electrocatalysis are elaborated. Finally, future challenges and research directions for the piezoelectric effect are proposed. [ABSTRACT FROM AUTHOR]

Published

2024

34. Integrated Triboelectric Nanogenerator for Energy Harvesting: Efficient Absorption of Wind in 6–16 m s−1 Velocity Range and Wave Energy.

Author

Feng, Chuqiao, Ji, Shijun, and Li, Wen

Subjects

OCEAN energy resources, WAVE energy, WIND speed, MECHANICAL energy, OCEAN

Abstract

The ocean harbors an abundance of resources, encompassing not only wave energy but also considerable wind energy. Triboelectric nanogenerator (TENG), as a technology for harvesting low‐frequency, high‐entropy mechanical energy, has shown distinct advantages in the collection and application of marine and wind energy. This study introduces a triboelectric Wind and wave energy harvester (TWWEH), an energy collector based on TENG, which can be used to harness wind and wave energy. The TWWEHs comprise a wind‐driven TENG (W‐TENG) for wind energy collection and a ring‐shaped TENG (R‐TENG) for wave energy collection. The proposed vertically integrated TENG architecture enhances spatial utilization rate. Under oscillatory conditions of 0.8 Hz and ±30°, the R‐TENG generates a peak power of 0.20 mW. While at a wind speed of 10 m s−1, a peak power of the W‐TENG can reach 0.11 mW. This research provides a promising solution to harvest wave and wind energy from the ocean, offering significant potential applications in establishing self‐powered oceanic assessment and meteorological systems. [ABSTRACT FROM AUTHOR]

Published

2024

35. Mathematical Modeling and Experimental Tests of Working Parameters of Piston-Radial Pumps in Hydraulic Systems of Mobile Machines.

Author

Radosavljević, Milan, Petrović, Radovan, Žeželj, Boris, Belović, Duško, and Cvejić, Stefan

Subjects

CONCRETE construction, MECHANICAL energy, PRESSURE sensors, POWER density, AGRICULTURAL equipment

Abstract

Modern methods of designing and constructing hydraulic pumps can no longer be imagined without the use of appropriate mathematical models, phenomena and processes that take place in concrete constructions. A mathematical model of a process represents an analytical interpretation with certain assumptions. Obtaining a mathematical model requires detailed theoretical research, based on knowledge of the laws of fundamental sciences and scientific disciplines, in order to fully understand and interpret the process, upon which assumptions are adopted and model equations are defined. As mobile machines continue to evolve, so do the demands on their hydraulic systems. Efficiency, automation and other major industry trends present ongoing development opportunities for the hydraulic systems used in mobile applications. Hydraulic systems remain an important component in a range of mobile applications, from construction and agricultural equipment to heavy trucks, because of the power density they can provide for a range of work functions. The power density of hydraulics remains unmatched in many applications. The pump, as an essential hydraulic component, converts mechanical energy into hydraulic energy with a relatively small amount and speed of fluid. [ABSTRACT FROM AUTHOR]

Published

2024

36. Advanced emerging ambient energy harvesting technologies enabled by transition metal dichalcogenides: Opportunity and challenge.

Author

Sun, Ning, Wang, Yan, Liu, Xianya, Li, Jianmin, Wang, Shiyan, Luo, Yixiang, Feng, Zhe, Dong, Jie, Zhang, Mengyang, Wang, Fengshun, Li, Yang, and Wang, Longlu

Subjects

MECHANICAL energy, CLEAN energy, WATER harvesting, ENERGY conversion, RENEWABLE energy sources

Abstract

Environmental pollution and global warming caused by fossil fuels have become increasingly serious issues. Therefore, it is urgent to explore novel strategies to obtain sustainable, renewable and clean energy. Fortunately, ambient energy harvesting technologies, which are receiving increasing attention, provide an optimal solution. Additionally, the investigation of two-dimensional (2D) materials represented by transition metal dichalcogenides (TMDs) significantly facilitates the advancement of ambient energy harvesting technologies due to their unique properties, enabling the application of ambient energy harvesting. Herein, we summarized recent advances in the application of TMDs in thermal energy harvesting, osmotic energy harvesting, mechanical energy harvesting, water energy harvesting and radiofrequency energy harvesting respectively. In the meanwhile, we listed some representative structure and device optimization strategies for enhancing the energy conversion performance of these ambient energy harvesters, aiming to provide valuable insights for future investigations towards further optimization. Finally, we highlight the pressing issues currently faced in the application of the TMDs ambient energy harvesting technologies and propose some potential solutions to these challenges. We aimed to provide a comprehensive review in the applications of the energy harvesting technologies, in order to provide innovative insights for optimizing existing TMDs-based technologies. [ABSTRACT FROM AUTHOR]

Published

2024

37. Experimental Study on the Dynamic Mechanical Properties and Critical Crushing Energy Dissipation Characteristics of Rocks Under Three-Dimensional Dynamic–Static Combinations of Loading Scenarios.

Author

Tian, Xingchao, Tao, Tiejun, and Xie, Caijin

Subjects

THRESHOLD energy, MECHANICAL energy, ENERGY density, DEAD loads (Mechanics), LOGARITHMIC functions, ENERGY dissipation

Abstract

To investigate the mechanical and energy dissipation characteristics of gray sandstone at critical failure, dynamic impact compression tests were conducted under different axial pressure and confining pressure levels. The critical energy dissipation density of gray sandstone under different dynamic-static combination loading conditions was determined, and an empirical model for predicting the critical energy dissipation density was established. The conclusions of the current research are: (1) the dynamic peak stress increases and then decreases with increasing axial pressure and increases with increasing confining pressure. The axial pressure turning points of dynamic peak stress from strong to poor under 4 MPa, 8 MPa, and 12 MPa confining pressure conditions were 22.54 MPa, 22.05 MPa, and 23.64 MPa, respectively. (2) The second type of cut line modulus increases and then decreases with the increase of axial pressure, showing a quadratic law of change. (3) When there is no axial pressure, the critical energy dissipation density increases and then decreases with the increase of confining pressure, showing an exponential function change rule. Under the condition of axial pressure, the critical energy dissipation density increases with the increase of confining pressure, showing the change rule of logarithmic function, and increases with the increase of axial pressure and then decreases, showing the change rule of quadratic function. (4) Under the conditions of confining pressure of 4 MPa, 8 MPa, 12 MPa, and axial pressure of 25.00 MPa, 28.33 MPa, and 20.00 MPa, the critical dissipation densities reached the maximum values of 7.01 J cm−3, 7.38 J cm−3, and 8.40 J cm−3, respectively. The empirical model can better predict the critical absorbed energy density of gray sandstone under different dynamic and static combinations loading conditions. [ABSTRACT FROM AUTHOR]

Published

2024

38. rGO-Embedded Polymer Nanocomposite Layer for Improved Performance of Triboelectric Nanogenerator.

Author

Rana, Shilpa and Singh, Bharti

Subjects

ENERGY harvesting, MECHANICAL energy, ELECTRICAL energy, CONDUCTING polymers, SURFACE charges, ELECTROSTATIC induction

Abstract

A triboelectric nanogenerator (TENG) working on a contact electrification and electrostatic induction principle is a promising energy source for fulfilling the energy demand of low power electronic devices by converting the ambient mechanical energy to useful electrical energy. Here, a polymer nanocomposite film-based triboelectric nanogenerator has been designed by embedding reduced graphene oxide (rGO) nanosheets in a polyvinylidene fluoride (PVDF) matrix as one of the friction layers. The PVDF nanocomposite film-based TENG was constructed and examined for structural, electrical, and surface properties with varied weight percentages of rGO nanofillers (0.0 wt%, 0.5 wt%, 1.0 wt%, 1.5 wt%, and 2.0 wt%). The experimental results demonstrate that the addition of rGO in a PVDF matrix considerably increased the output performance of the TENG device. The TENG device with 1.5 wt% of rGO can deliver the maximum output voltage and current of 95.9 V, and 16.8 μA, respectively, which are ~ 3 and ~ 7 times the voltage and current produced by pristine PVDF film-based TENG. The enhanced performance of the nanogenerator is attributed to the addition of conductive nanofillers in the polymer matrix which improves the surface charge density of polymer nanocomposite films by forming a conduction network, resulting in more effective charge transfer. Moreover, the output of the nanogenerator is stored in the capacitor and used to drive commercial LEDs, revealing the TENGs' potential applications for designing self-powered electronic devices. [ABSTRACT FROM AUTHOR]

Published

2024

39. Poor Joint Work in the Lower Limbs during a Tennis Forehand Groundstroke after a Cross-Over Step Inhibits an Increase in the Racket Speed.

Author

Kawamoto, Yuta, Suzuki, Takahito, Iino, Yoichi, Yoshioka, Shinsuke, Takeshita, Daisuke, and Senshi, Fukashiro

Subjects

MECHANICAL energy, THROWING (Sports), RACKETS (Sporting goods), TENNIS players, TENNIS

Abstract

A forward run-up and stepping are used to accelerate hitting tools or throwing objects in sports. This study aimed to investigate the effect of a forward cross-over step on the speed of a hitting tool by analyzing the joint work and mechanical energy of the whole body and the hitting tool using inverse dynamics. Thirteen advanced tennis players performed forehand groundstrokes at maximum effort with and without a forward cross-over step. From the whole body plus racket perspective, the body-weight-normalized mechanical energy at the start of the hitting motion increased by 1.74 ± 0.42 J·kg-1 due to the cross-over step. However, the increase in the magnitude of total negative joint work, primarily attributed to the lower limbs, was 1.38 ± 0.31 J·kg-1 due to the cross-over step, conventionally regarded as energy absorption. Consequently, the mechanical energy of the whole body plus the racket at ball impact was comparable between the conditions. Nevertheless, from the segmental perspective, the mechanical work performed by the net shoulder joint force of the playing upper limb with the cross-over step during the hitting motion was greater than that without the crossover step. Subsequently, the slight increase in the mechanical energy of the playing upper limb plus racket (0.25 ± 0.21 J·kg-1) resulted in increased racket speed (4.3%). Considering the comparable total mechanical energy and a resultant increase in racket speed, players and coaches should not overestimate the effect of the forward step on racket speed. [ABSTRACT FROM AUTHOR]

Published

2024

40. In-situ monitoring of polymer mechanochemistry: what can be learned from small molecule systems.

Author

Willis-Fox, Niamh

Subjects

*CHEMICAL reactions, *CHEMICAL amplification, *POWER transmission, *MECHANICAL energy, *MECHANICAL chemistry

Abstract

Using mechanical energy to drive chemical transformations is an exciting prospect to improve the sustainability of chemical reactions and to produce products not achievable by more traditional methods. In-situ monitoring of reaction pathways and chemical transformations is vital to deliver the reproducible results required for scale up to realize the potential of mechanochemistry beyond the chemistry lab. This mini review will discuss the recent advances in in-situ monitoring of ball milling and polymer mechanochemistry, highlighting the potential for shared knowledge for scale up. [ABSTRACT FROM AUTHOR]

Published

2024

41. Enhancing Power Generation in Triboelectric Nanogenerators via Integration of Graphene Nanoplatelets and Polyvinyl Alcohol.

Author

Okbaz, Abdulkerim, Yar, Adem, Karabiber, Abdulkerim, Lin, Geng-Sheng, Tong, Zhaohui, and Saeed, Muhammad Ahsan

Subjects

*ENERGY harvesting, *NANOGENERATORS, *MECHANICAL energy, *POWER resources, *ELECTRICAL energy, *TRIBOELECTRICITY

Abstract

Triboelectric nanogenerators (TENGs) provide promising power supply solutions by transforming mechanical energy into electrical energy. However, enhancing electrical performance of TENGs is essential for their widespread practical applications and commercialization. In this study, we fabricated TENGs in vertical contact‐separation mode using a tribopositive material—polyvinyl alcohol (PVA) slime—which is biocompatible, flexible, and wearable, decorated with graphene nanoplatelets (GnPs), and paired with tribonegative silicone. We analyzed the correlation between the electrical performance of the TENGs and the inherent triboelectric properties of the constituent material, including the evaluation of surface roughness, the measurement of the contact potential difference (CPD), and the material's dielectric constant. The incorporation of GnPs increased the dielectric constant of the composite material and its electron‐donating tendency, thus, increasing the contact potential difference. The GnPs concentration of 1 wt% was identified as the optimal value, resulting in a 42% increase in power density. The 1 wt% GnPs@PVA&Silicone TENG exhibited an open‐circuit voltage of 718 V and a peak power density of 15.3 W/m2. This study sheds light on enhancing the energy harvesting efficiency of TENGs through the utilization of biocompatible tribopositive and tribonegative materials. [ABSTRACT FROM AUTHOR]

Published

2024

42. An Easy Nanopatch Promotes Peripheral Nerve Repair through Wireless Ultrasound‐Electrical Stimulation in a Band‐Aid‐Like Way.

Author

Liu, Yang, Zhang, Zhifa, Zhao, Ziteng, Xu, Yongde, Duan, Xiaofeng, Zhao, Yantao, Ma, Wenjing, Yang, Yong, Yang, Yafeng, and Liu, Zhiqiang

Subjects

*PERIPHERAL nerve injuries, *LABORATORY rats, *MECHANICAL energy, *PERIPHERAL nervous system, *POWER resources

Abstract

Low‐intensity pulsed ultrasound (LIPUS) and electrical stimulation (ES) are effective methods that promote neural repair. However, ES usually requires electrode implantation and a power supply, which are an inconvenience to future applications. Meanwhile, it is difficult to combine ultrasound and ES through traditional methods. Herein, a nanopatch consisting of an oriented barium titanate (BTO)‐incorporated polycaprolactone (PCL) nanofiber membrane for electricity generation and a layer of graphene oxide (GO)‐doped gelatin methacryloyl (GelMA) for neural interaction is developed. This band‐aid‐like BTO@PCL/GO@GelMA nanopatch has an excellent piezoelectric performance. In vitro, the nanopatches significantly promote axonal growth under LIPUS treatment. In a rat model of erectile dysfunction caused by peripheral nerve injury, the nanopatch is easily attached to a damaged nerve similar to a band‐aid. With the assistance of ultrasound, some mechanical energy is converted into electricity by the nanopatch, and synergistic neural stimulation of ultrasound and electricity is achieved. In this way, the nanopatch significantly promoted corpus cavernosum nerve repair, resulting in the improvement of tissue structure and erectile function as well as increased conception rate in female rats. In conclusion, the nanopatch offers a synergistic ultrasound‐ES for nerve repair easily and represents a novel strategy for peripheral nerve repair. [ABSTRACT FROM AUTHOR]

Published

2024

43. Piezocatalysts and Piezo‐Photocatalysts: From Material Design to Diverse Applications.

Author

Jia, Pengwei, Li, Jianming, and Huang, Hongwei

Subjects

*PIEZOELECTRICITY, *PIEZOELECTRIC materials, *MECHANICAL energy, *CHEMICAL energy, *ENVIRONMENTAL remediation, *PHOTOCATALYSTS

Abstract

Piezocatalysis and piezo‐photocatalysis technology is a continuously developing catalytic technology based on the piezoelectric effect of catalysts, which breaks the barrier between mechanical and chemical energy. The piezoelectric polarization field formed by the mechanical deformation of piezoelectric materials is proven to effectively manipulate band structures, improve the separation of electron‐hole pairs and enhance the catalytic activity, thus alleviating energy crises and environmental issues. Herein, this review first introduces the technology of piezocatalysis and piezo‐photocatalysis, comprehensively summarizes the synthesis methods of piezo(photo)catalysis materials, and analyzes and discusses the measures to optimize the performance of piezo(photo)catalysts. The following systematically summarizes the characteristics and development of the current main piezo(photo)catalytic systems, and discusses the application of first principles calculations in piezo(photo)catalysis in combination with practical researches. Subsequently, the main application progress of piezo(photo)catalysis in environmental remediation, energy conversion, and biomedical therapy fields is presented. In the end, the current challenges, development direction, and future prospects are prospected. [ABSTRACT FROM AUTHOR]

Published

2024

44. Bidirectional Phase Transformations in Multi‐Principal Element Alloys: Mechanisms, Physics, and Mechanical Property Implications.

Author

Sun, Jiayi, Li, Heqing, Chen, Yujie, and An, Xianghai

Subjects

*PHASE transitions, *MECHANICAL energy, *METALLURGY, *ALLOYS, *PHYSICS

Abstract

The emergence of multi‐principal element alloys (MPEAs) heralds a transformative shift in the design of high‐performance alloys. Their ingrained chemical complexities endow them with exceptional mechanical and functional properties, along with unparalleled microscopic plastic mechanisms, sparking widespread research interest within and beyond the metallurgy community. In this overview, a unique yet prevalent mechanistic process in the renowned FeMnCoCrNi‐based MPEAs is focused on: the dynamic bidirectional phase transformation involving the forward transformation from a face‐centered‐cubic (FCC) matrix into a hexagonal‐close‐packed (HCP) phase and the reverse HCP‐to‐FCC transformation. The light is shed on the fundamental physical mechanisms and atomistic pathways of this intriguing dual‐phase transformation. The paramount material parameter of intrinsic negative stacking fault energy in MPEAs and the crucial external factors c, furnishing thermodynamic, and kinetic impetus to trigger bidirectional transformation‐induced plasticity (B‐TRIP) mechanisms， are thorougly devled into. Furthermore, the profound significance of the distinct B‐TRIP behavior in shaping mechanical properties and creating specialized microstructures c to harness superior material characteristics is underscored. Additionally, critical insights are offered into key challenges and future striving directions for comprehensively advancing the B‐TRIP mechanism and the mechanistic design of next‐generation high‐performing MPEAs. [ABSTRACT FROM AUTHOR]

Published

2024

45. Programmable heterogeneous lamellar lattice architecture for dual mechanical protection.

Author

Yuanyuan Tian, Xin Zhang, Boyuan Hou, Jarlöv, Asker, Chunyang Du, and Kun Zhou

Subjects

*BODY centered cubic structure, *UNIT cell, *FACE centered cubic structure, *THRESHOLD energy, *MECHANICAL energy

Abstract

Shear bands frequently appear in lattice architectures subjected to compression, leading to an unstable stress–strain curve and global deformation. This deformation mechanism reduces their energy absorption and loading-bearing capacity and causes the architectures to prioritize mechanical protection of external components at the expense of the entire structure. Here, we leverage the design freedom offered by additive manufacturing and the geometrical relation of dual-phase nanolamellar crystals to fabricate heterogeneous lamellar lattice architectures consisting of body-centered cubic (BCC) and face-centered cubic (FCC) unit cells in alternating lamella. The lamellar lattice demonstrates more than 10 and 9 times higher specific energy absorption and energy absorption efficiency, respectively, compared to the BCC lattice. The drastic improvement arises as the nucleation of shear bands is inhibited by the discrete energy threshold for plastic buckling of adjacent heterogeneous lattice lamella during loading. Despite its lower density than the FCC lattice, the lamellar lattice exhibits significant enhancement in plateau stress and crushing force efficiency, attributed to the strengthening effect induced by simultaneous deformation of unit cells in the BCC lattice lamella and the resulting cushion shielding effect. The design improves the global mechanical properties, making lamellar lattices compare favorably against numerous materials proposed for mechanical protection. Additionally, it provides opportunities to program the local mechanical response, achieving programmable internal protection alongside overall external protection. This work provides a different route to design lattice architecture by combining internal and external dual mechanical protection, enabling a generation of multiple mechanical protectors in aerospace, automotive, and transportation fields. [ABSTRACT FROM AUTHOR]

Published

2024

46. Dynamical clustering and wetting phenomena in inertial active matter.

Author

Caprini, Lorenzo, Breoni, Davide, Ldov, Anton, Scholz, Christian, and Löwen, Hartmut

Subjects

*MECHANICAL energy, *NUCLEATION, *ARREST, *CONTAINERS, *WETTING, *PHASE separation

Abstract

Dynamical clustering is a key feature of active matter systems composed of self-propelled agents that convert environmental energy into mechanical motion. At the micron scale, where overdamped dynamics dominate, particles with opposite motility can obstruct each other's movement, leading to transient dynamical arrest. This arrest can promote cluster formation and motility-induced phase separation. However, in macroscopic agents, where inertia plays a significant role, clustering is heavily influenced by bounce-back effects during collisions, which can impede cluster growth. Here we present an experiment based on active granular particles, in which inertia can be systematically tuned by changing the shaker frequency. As a result, a set of phenomena driven and controlled by inertia emerges. Before the suppression of clustering, inertia induces a transition in the cluster's inner structure. For small inertia, clusters are characterized by the crystalline order typical of overdamped particles, while for large inertia clusters with liquid-like order are observed. In addition, in contrast to microswimmers, where active particles wet the boundary by primarily forming clusters attached to the container walls, in an underdamped inertial active system, walls do not favor cluster formation and effectively annihilate motility-induced wetting phenomena. As a consequence, inertia suppresses cluster nucleation at the system boundaries. Active matter systems composed of self-propelled agents exhibit dynamical clustering. In this work, the authors demonstrate that inertia induces a solid-liquid transition within the cluster structure and suppresses wetting phenomena at the container boundary. [ABSTRACT FROM AUTHOR]

Published

2024

47. Metal-free small molecule-based piezoelectric energy harvesters.

Author

Sahoo, Supriya, Deka, Nilotpal, Panday, Rishukumar, and Boomishankar, Ramamoorthy

Subjects

*MECHANICAL energy, *PIEZOELECTRIC materials, *ENERGY harvesting, *COMPOSITE materials, *PIEZOELECTRICITY

Abstract

Organic and metal-free molecules with piezoelectric and ferroelectric properties have gained wide interest for their applications in the domain of mechanical energy harvesting due to their desirable properties such as light weight, thermal stability, mechanical flexibility, feasibility to achieve high Curie temperatures, and ease of synthesis. However, the understanding and design of these materials for piezoelectric energy harvesting applications is still in its early stages. This review paper presents a comprehensive overview of the fundamental characterization of piezoelectricity for a range of organic ferro- and piezoelectric materials and their composites. It also discusses the limitations of traditional piezoelectric materials and highlights the advantages of organic materials in this area in the introduction part. In addition, the paper provides a detailed description of peptide-based and other biomolecular piezoelectric materials as a bio-friendly alternative to current materials. This perspective aims to guide researchers in designing functional organic materials and composites for practical mechanical energy harvesting applications and to highlight current limitations and future perspectives in this emerging area of research. [ABSTRACT FROM AUTHOR]

Published

2024

48. Direct observation of deformation and resistance to damage accumulation during shock loading of stabilized nanocrystalline Cu-Ta alloys.

Author

Hornbuckle, B. C., Koju, R. K., Kennedy, G., Jannotti, P., Lorenzo, N., Lloyd, J. T., Giri, A., Solanki, K., Thadhani, N. N., Mishin, Y., and Darling, K. A.

Subjects

MATERIALS science, MECHANICAL energy, DISLOCATION structure, ENERGY transfer, THRESHOLD energy

Abstract

Energy absorption by matter is fundamental to natural and man-made processes. However, despite this ubiquity, developing materials capable of withstanding severe energy fluxes without degradation is a significant challenge in materials science and engineering. Despite recent advances in creating alloys resistant to energy fluxes, mitigating the damage caused by the absorption and transfer of mechanical energy remains a critical obstacle in both fundamental science and technological applications. This challenge is especially prominent when the mechanical energy is transferred to the material by shock loading. This study demonstrates a phenomenon in which microstructurally stabilized nanocrystalline Cu-Ta alloys can undergo reversal or nearly complete recovery of the dislocation structure after multiple shock-loading impacts, unlike any other known metallic material. The microstructure of these alloys can withstand repeated shock-wave interactions at pressures up to 12 GPa without any significant microstructural damage or deterioration, demonstrating an extraordinary capacity to be virtually immune to the detrimental effects of shock loading. This study reveals that under 12 GPa shock loading, stabilized nanocrystalline Cu-3Ta can generate and reabsorb dislocations, enabling near-complete recovery without microstructural deterioration. This behavior contrasts with other known metals. [ABSTRACT FROM AUTHOR]

Published

2024

49. Multiscale modeling of metal-hydride interphases—quantification of decoupled chemo-mechanical energies.

Author

Alvares, Ebert, Sellschopp, Kai, Wang, Bo, Kang, ShinYoung, Klassen, Thomas, Wood, Brandon C., Heo, Tae Wook, Jerabek, Paul, and Pistidda, Claudio

Subjects

HYDROGENATION kinetics, MECHANICAL energy, STRAINS & stresses (Mechanics), MULTISCALE modeling, CHEMICAL energy

Abstract

The quantification of interphase properties between metals and their corresponding hydrides is crucial for modeling the thermodynamics and kinetics of the hydrogenation processes in solid-state hydrogen storage materials. In particular, interphase boundary energies assume a pivotal role in determining the kinetics of nucleation, growth, and coarsening of hydrides, alongside accompanying morphological evolution during hydrogenation. The total interphase energy arises from both chemical bonding and mechanical strains in these solid-state systems. Since these contributions are usually coupled, it is challenging to distinguish via conventional computational approaches. Here, a comprehensive atomistic modeling methodology is developed to decouple chemical and mechanical energy contributions using first-principles calculations, of which feasibility is demonstrated by quantifying chemical and elastic strain energies of key interfaces within the FeTi metal-hydride system. Derived materials parameters are then employed for mesoscopic micromechanical analysis, predicting crystallographic orientations in line with experimental observations. The multiscale approach outlined verifies the importance of the chemo-mechanical interplay in the morphological evolution of growing hydride phases, and can be generalized to investigate other systems. In addition, it can streamline the design of atomistic models for the quantitative evaluation of interphase properties between dissimilar phases and allow for efficient predictions of their preferred phase boundary orientations. [ABSTRACT FROM AUTHOR]

Published

2024

50. Fabricating and Engineering Woody‐Biomass Aerogels for High‐Performance Triboelectric Nanogenerators for Energy Harvesting and Biomechanical Monitoring.

Author

Li, Longwen, Wang, Ruolin, Fu, Yang, Jin, Zhenhui, Chen, Jiansong, Du, Haishun, Pan, Xuejun, and Wang, Yi‐Cheng

Subjects

*NANOGENERATORS, *ENERGY harvesting, *RENEWABLE natural resources, *MESOPOROUS materials, *MECHANICAL energy, *TRIBOELECTRICITY

Abstract

Woody biomass is an abundant renewable resource. In this study, aerogels for versatile triboelectric devices are fabricated from poplar biomass via a dissolution‐and‐regeneration method with concentrated lithium bromide solution as the solvent. To improve the aerogels' structural homogeneity, two treatments—ball‐milling the raw poplar woody biomass before its dissolution, and, separately, ultrasonication following its dissolution—were applied. These treatments altered the porous structures and mechanical properties of the resulting aerogels, leading to a marked increase in their triboelectric performance. Removing the majority of the lignin from the aerogels was also explored, and resulted in triboelectric output ≈5 times greater than that of pristine woody biomass aerogel (i.e., without ball milling, ultrasonication, or lignin reduction). The underlying mechanisms of such increases were found to be both chemical and physical. Next, triboelectric devices were fabricated using the optimal (i.e., low‐lignin) aerogel for energy harvesting and biomechanical monitoring. These devices were able to: 1) respond sensitively to force, likely due to the aerogel's porous structures; 2) capture mechanical energy, charge capacitors, and power small portable electronics; and 3) monitor biomechanical movements including respiration, joint motions, and gait‐pattern changes. [ABSTRACT FROM AUTHOR]

Published

2024