Your search keyword '"Mechanical engineering"' showing total 2,263,184 results

1. A new mechanical engineering strategy based on microsphere probe and its application in transition metal dichalcogenides.

Author

Yang, Rui, Cui, Yi, Yang, Zicong, Qin, Feng, Rao, Junhao, Yuan, Hongtao, and Qiu, Caiyu

Subjects

*ATOMIC force microscopy, *STRAINS & stresses (Mechanics), *MECHANICAL engineering, *ELECTRONIC modulation, *TRANSITION metals

Abstract

Mechanical engineering of 2D materials allows continuous and reversible modulation of their electronic and photonic properties. Although photoluminescence (PL) measurement is an effective way to monitor the effects of mechanical forces on 2D semiconductors, there is currently a lack of techniques to enhance PL signals during stress application. This study presents an innovative mechanical engineering approach that integrates a dielectric microsphere as an atomic force microscopy (AFM) probe into a Raman-AFM system. Force–distance curve tests and COMSOL simulations were performed to analyze and estimate the compressive stress exerted by the microsphere. Importantly, the PL signals of transition metal dichalcogenides subjected to microsphere probe's force were enhanced and reveal distinct mechanical responses depending on the substrate rigidity: compressive pressures for rigid substrates and tensile strains for flexible ones. Notably, this strategy not only amplifies spectral signals in real time but also achieves fine stress modulation in the precise targeted material region, demonstrating its superiority in sensitive mechanical engineering applications. Our work offers a new avenue for the deliberate design of mechanical strains in 2D materials, which is crucial for optimizing the performance of related devices. [ABSTRACT FROM AUTHOR]

Published

2024

2. A State-Space Method for Vibration of Double-Beam Systems with Variable Cross Sections

Author

Li, Yongxue, Guo, Hui, Xiong, Feng, Xie, Lingzhi, Gong, Jian, and Sun, Lizhi

Subjects

Engineering, Aerospace Engineering, Double-beam system, Variable cross section, Transverse vibration, State-space method, Civil Engineering, Mechanical Engineering, Civil engineering, Mechanical engineering

Abstract

In this paper, a state-space method for double-beam systems with variable cross sections is developed, making it possible to calculate the transverse vibration of the double-beams accurately and effectively. Due to the variability in the double-beam cross sections with the viscoelastic interlayer in between, the governing equations of vibration for the systems become highly coupled partial differential equations, making the problem difficult to solve. A basic double-beam system is introduced to modify the original governing equations to two inhomogeneous differential equations. Given the separation of variables, several mode-shape coefficients and a state variable are defined to construct the state-space equations. The coupling terms and variables are transferred into the constant coefficient matrix of the state-space equations, decoupling them. Numerical procedures are presented to solve the state-space equations to obtain homogenous and inhomogeneous solutions, including the natural frequencies and mode shapes in free vibration and the dynamic responses in forced vibration, respectively. The method has substantial advantages in decoupling high-order partial differential equations and can be further extended to solve complex structural systems. Numerical results also demonstrate that the method is accurate and efficient. Finally, an engineering application with a rail-bridge with a floating slab track is discussed in detail with the method.

Published

2024

3. A simple model for short-range ordering kinetics in multi-principal element alloys

Author

Abu-Odeh, Anas, Xing, Bin, Cao, Penghui, Uberuaga, Blas Pedro, and Asta, Mark

Subjects

Engineering, Materials Engineering, Mechanical Engineering, Condensed Matter Physics, Materials, Materials engineering, Mechanical engineering, Condensed matter physics

Abstract

Short-range ordering (SRO) in multi-principal element alloys influences material properties such as strength and corrosion. While some degree of SRO is expected at equilibrium, predicting the kinetics of its formation is challenging. We present a simplified isothermal concentration-wave (CW) model to estimate an effective relaxation time of SRO formation. Estimates from the CW model agree to within a factor of five with relaxation times obtained from kinetic Monte Carlo (kMC) simulations when above the highest ordering instability temperature. The advantage of the CW model is that it only requires mobility and thermodynamic parameters, which are readily obtained from alloy mobility databases and Metropolis Monte Carlo simulations, respectively. The simple parameterization of the CW model and its analytical nature makes it an attractive tool for the design of processing conditions to promote or suppress SRO in multicomponent alloys.

Published

2024

4. Elucidating the role of Cr migration in Ni-Cr exposed to molten FLiNaK via multiscale characterization

Author

Mills, Sean H, Hayes, Ryan D, Bieberdorf, Nathan, Zeltmann, Steven E, Kennedy, Alexandra M, Capolungo, Laurent, Asta, Mark, Scarlat, Raluca O, and Minor, Andrew M

Subjects

Engineering, Materials Engineering, Physical Sciences, Corrosion, STEM HAADF, Scanning electron microscopy, Phase field modeling, Four-dimensional scanning electron, microscopy, Energy dispersive spectroscopy, Inductively coupled plasma optical emission, spectroscopy, Condensed Matter Physics, Mechanical Engineering, Materials, Materials engineering, Mechanical engineering, Condensed matter physics

Abstract

Structural materials used in nuclear reactor environments are subjected to coupled extremes such as high temperature, irradiation, and corrosion which act in concert to degrade their functional performance. Connecting alloy microstructure such as grain boundaries, and accumulating point defects with corrosion attack and pore morphology is critical to understanding underlying mechanisms. We uncover the compositional variations and morphology at multiple length scales in corrosion-damaged Ni-Cr alloy after exposure to oxidants in molten fluoride salts. A complex network of dense corrosion pores is detected by surface-level SEM observations. The corrosion pores take on a 1-dimensional morphology and are enriched with Ni and depleted of Cr 1–5 µm from the pore surface. STEM-EDS and 4D-STEM strain maps acquired simultaneously highlight the local variations in composition and structure of a ≤ 200 nm Cr-rich layer identified from a cross-section taken at the bottom of an isolated corrosion pore between the Ni-Cr alloy matrix and the embedded salt. However, the absence of an observed interface between the Ni-Cr alloy matrix and the FCC-structured Cr-rich layer suggests that Cr plating from the salt did not transpire. These findings support a proposed Cr lattice diffusion mechanism rather than Cr-precipitation from the salt to accommodate temperature transient conditions during sample cooling. Through the development of a 1D phase field model, these results are rationalized by formation energies for the Ni- and Cr-oxidation into the molten salt. This study reveals the locally altered microstructure caused by high temperature corrosion in non-steady-state molten salt nuclear reactor environments.

Published

2024

5. Renewable-battery hybrid power plants in congested electricity markets: Implications for plant configuration

Author

Kim, James Hyungkwan, Millstein, Dev, Wiser, Ryan, and Mulvaney-Kemp, Julie

Subjects

Engineering, Electronics, Sensors and Digital Hardware, Affordable and Clean Energy, Climate Action, Electrical and Electronic Engineering, Mechanical Engineering, Interdisciplinary Engineering, Energy

Abstract

Examining coupled renewable-battery power plants (“hybrids”) in congested areas provides insights into a future of increased wind and solar penetration. Our study focuses on two types of congested regions, Variable Renewable Energy (VRE)-rich Areas and Load Centers, and explores likely plant configuration choices for developers and transmission network planners. This paper examines how hybrid value, comprising energy and capacity value, varies by plant configuration and congested region type considering factors such as storage duration, battery degradation, and ability to charge from the grid. We select plant locations from across the seven main U.S. independent system operators (ISOs). Hybrid value for each configuration is computed based on profit-maximizing plant operation given perfect foresight, according to observed wholesale power market real time prices from 2018 to 2021. In VRE-rich Areas, the median increase in energy value from extending storage duration from one to 4 h is 29.4 % for solar and 26.8 % for wind, assuming low battery degradation costs and storage sized to 100 % of the plant's nameplate generation capacity. Increasing storage duration beyond 4 h does not substantially increase its value from energy markets, even in VRE-rich Areas. We find that solar hybrids reach a 90 % capacity credit with 4 h of storage, while wind hybrids require 8 h of storage, based on the capacity factor of each hybrid during the top 100 net load hours.

Published

2024

6. Synthesis and growth of solution-processed chiral perovskites

Author

Driessen, Sander, Sarigul-Ozbek, Sevgi, Sutter-Fella, Carolin M, and Tao, Shuxia

Subjects

Chemical Engineering, Engineering, Electrical Engineering, Mechanical Engineering, chiral perovskite, chiral ligand, growth mechanism, crystallization kinetics, solution processing, low-dimensional, Chemical engineering, Electrical engineering, Mechanical engineering

Abstract

In materials science, chiral perovskites stand out due to their exceptional optoelectronic properties and the versatility in their structure and composition, positioning them as crucial in the advances of technologies in spintronics and chiroptical systems. This review underlines the critical role of synthesizing and growing these materials, a process integral to leveraging their complex interplay between structural chirality and distinctive optoelectronic properties, including chiral-induced spin selectivity and chiroptical activity. The paper offers a comprehensive summary and discussion of the methods used in the synthesis and growth of chiral perovskites, delving into extensive growth techniques, fundamental mechanisms, and strategic approaches for the engineering of low-dimensional perovskites, alongside the creation of novel chiral ligands. The necessity of developing new synthetic approaches and maintaining precise control during the growth of chiral perovskites is emphasized, aiming to enhance their structural chirality and boost their efficiency in spin and chiroptical selectivity.

Published

2024

7. Solid phase epitaxy of SrRuO3 encapsulated by SrTiO3 membranes

Author

Zhou, Jieyang, Feng, Mingzhen, Shih, Hudson, Takamura, Yayoi, and Hong, Seung Sae

Subjects

Engineering, Materials Engineering, Electrical and Electronic Engineering, Mechanical Engineering, Materials engineering, Nanotechnology, Condensed matter physics

Abstract

Solid phase epitaxy (SPE) has been widely employed for various thin-film materials, making it valuable for industrial applications due to its scalability. In complex oxides, SPE has been limited to a few materials because of the challenges in maintaining stoichiometric control during growth, particularly when volatile phases are present at high temperatures. Here, we investigate the impact of encapsulation layers on the SPE of complex oxides, using SrRuO3 (SRO) as a model system. An amorphous SRO layer was deposited on a SrTiO3 (STO) substrate, followed by the transfer of a single-crystalline STO membrane as an encapsulation layer in order to suppress the evaporation of volatile species (RuO2) during the SPE process. Whereas both encapsulated and unencapsulated SRO layers were successfully crystallized, the unencapsulated films suffered a substantial loss of Ru ions—exceeding 20%—compared to their encapsulated counterparts. This loss of Ru ions led to a loss of metallicity in the unencapsulated SRO layers, whereas the encapsulated layers retained their metallic ferromagnetic properties. This study demonstrates that the encapsulation provided by oxide membranes effectively suppresses stoichiometric loss during SPE, presenting a new strategy in stabilizing a broader class of functional oxides as epitaxial thin films.

Published

2024

8. Roadmap on low-power electronics

Author

Ramesh, Ramamoorthy, Salahuddin, Sayeef, Datta, Suman, Diaz, Carlos H, Nikonov, Dmitri E, Young, Ian A, Ham, Donhee, Chang, Meng-Fan, Khwa, Win-San, Lele, Ashwin Sanjay, Binek, Christian, Huang, Yen-Lin, Sun, Yuan-Chen, Chu, Ying-Hao, Prasad, Bhagwati, Hoffmann, Michael, Hu, Jia-Mian, Yao, Zhi, Bellaiche, Laurent, Wu, Peng, Cai, Jun, Appenzeller, Joerg, Datta, Supriyo, Camsari, Kerem Y, Kwon, Jaesuk, Incorvia, Jean Anne C, Asselberghs, Inge, Ciubotaru, Florin, Couet, Sebastien, Adelmann, Christoph, Zheng, Yi, Lindenberg, Aaron M, Evans, Paul G, Ercius, Peter, and Radu, Iuliana P

Subjects

Engineering, Physical Sciences, Materials Engineering, Nanotechnology, Condensed Matter Physics, Electrical and Electronic Engineering, Mechanical Engineering, Materials engineering, Condensed matter physics

Published

2024

9. Design principles for enabling an anode-free sodium all-solid-state battery

Author

Deysher, Grayson, Oh, Jin An Sam, Chen, Yu-Ting, Sayahpour, Baharak, Ham, So-Yeon, Cheng, Diyi, Ridley, Phillip, Cronk, Ashley, Lin, Sharon Wan-Hsuan, Qian, Kun, Nguyen, Long Hoang Bao, Jang, Jihyun, and Meng, Ying Shirley

Subjects

Engineering, Materials Engineering, Affordable and Clean Energy, Electrical and Electronic Engineering, Environmental Engineering, Electrical engineering, Mechanical engineering

Abstract

Anode-free batteries possess the optimal cell architecture due to their reduced weight, volume and cost. However, their implementation has been limited by unstable anode morphological changes and anode–liquid electrolyte interface reactions. Here we show that an electrochemically stable solid electrolyte and the application of stack pressure can solve these issues by enabling the deposition of dense sodium metal. Furthermore, an aluminium current collector is found to achieve intimate solid–solid contact with the solid electrolyte, which allows highly reversible sodium plating and stripping at both high areal capacities and current densities, previously unobtainable with conventional aluminium foil. A sodium anode-free all-solid-state battery full cell is demonstrated with stable cycling for several hundred cycles. This cell architecture serves as a future direction for other battery chemistries to enable low-cost, high-energy-density and fast-charging batteries.

Published

2024

10. Achieving 19% efficiency in non-fused ring electron acceptor solar cells via solubility control of donor and acceptor crystallization

Author

Zeng, Rui, Zhang, Ming, Wang, Xiaodong, Zhu, Lei, Hao, Bonan, Zhong, Wenkai, Zhou, Guanqing, Deng, Jiawei, Tan, Senke, Zhuang, Jiaxin, Han, Fei, Zhang, Anyang, Zhou, Zichun, Xue, Xiaonan, Xu, Shengjie, Xu, Jinqiu, Liu, Yahui, Lu, Hao, Wu, Xuefei, Wang, Cheng, Fink, Zachary, Russell, Thomas P, Jing, Hao, Zhang, Yongming, Bo, Zhishan, and Liu, Feng

Subjects

Engineering, Materials Engineering, Electrical and Electronic Engineering, Environmental Engineering, Electrical engineering, Mechanical engineering

Abstract

Non-fused ring electron acceptors (NFREAs) potentially have lower synthetic costs than their fused counterparts. However, the low backbone planarity and the presence of bulky substituents adversely affect the crystallinity of NFREAs, impeding charge transport and the formation of bicontinuous morphology in organic solar cells. Here we show that a binary solvent system can individually control the crystallization and phase separation of the donor polymer (for example, D18) and the NFREA (for example, 2BTh-2F-C2). We select solvents such as chloroform and o-xylene that evaporate at different temperatures and rates and have different solubility for D18. Upon evaporation of chloroform, D18 starts to assemble into fibrils. Then, the evaporation of o-xylene induces the rapid formation of a fibril network that phase segregates 2BTh-2F-C2 into pure domains and leads to a bicontinuous morphology. The well-defined interpenetrating network morphology affords an efficiency of 19.02% on small-area cells and 17.28% on 1 cm2 devices.

Published

2024

11. Industrial Process Fault Detection Based on Siamese Recurrent Autoencoder

Author

Ji, Cheng, Ma, Fangyuan, Wang, Jingde, Sun, Wei, and Palazoglu, Ahmet

Subjects

Control Engineering, Mechatronics and Robotics, Engineering, Engineering Practice and Education, Machine Learning and Artificial Intelligence, Networking and Information Technology R&D (NITRD), Chemical Engineering, Mechanical Engineering, Chemical engineering

Abstract

Although deep autoencoders excel at extracting intricate features, their application in process monitoring is limited by the requirement for large sample sizes and interpretability of latent representations. This work presents a special deep learning structure named Siamese network to detect abnormal deviations in nonlinear dynamic processes. By leveraging the capability of Siamese architecture to process multiple inputs simultaneously, the training sample size expands exponentially, which enhances the learning potential of the model. Furthermore, a long short-term memory unit is integrated to enable the capture of long-term process dynamics. To refine the distribution of latent features extracted from diverse data types, a contrastive loss function is proposed, which strengthens the model's fault detection capabilities and enhances its interpretation of latent representations. Then T2 statistic is established on the latent space to perform fault detection. The effectiveness of the method is demonstrated through case studies on simulation processes and an industrial process.

Published

2025

12. The atomic-level structure and stability of interfaces of Pt nanoparticles in alumina: An experimental and computational evaluation

Author

Clauser, AL, Sarfo, K Oware, Ophus, C, Ciston, J, Giulian, R, Árnadóttir, L, and Santala, MK

Subjects

Engineering, Physical Sciences, Condensed Matter Physics, Materials Engineering, Mechanical Engineering, Materials, Materials engineering, Mechanical engineering, Condensed matter physics

Abstract

The atomic-level structure of interfaces between Pt and a transition form of Al2O3 were studied using a combination of electron microscopy and first principles calculations. A model system of Pt nanoprecipitates in Al2O3 were formed in sapphire wafers via high-energy ion implantation of Pt followed by thermal annealing at 1000 °C in air. The Pt nanoparticles took the form of tetrahedra and truncated tetrahedra primarily bound by {111}Pt facets. The high prevalence of these facets motivated the development of density functional theory (DFT) based models of (111)Pt interfaces with six different chemical terminations of (2¯01) θ-alumina. The atomic-level structure of the Pt/Al2O3 interfaces was characterized with aberration-corrected scanning transmission electron microscopy (STEM) and the experimental images were compared to STEM image simulations of the DFT models. The model interface with Pt bonded to oxygen-terminated θ-Al2O3, with the Pt located on top of the O and with an underlying layer of octahedral Al, provided the best match to the experimental images. This interfacial termination is also the most stable for the thermal annealing conditions used based on thermodynamic calculations of the interfacial energy as a function of temperature and oxygen partial pressure. This experimentally verified model provides a basis for improving models of Pt/γ-alumina interfaces.

Published

2024

13. Evaluation of a Commercial MoS2 Dry Film Lubricant for Space Applications

Author

Johnson, Duval A, Gori, Marcello, Vellore, Azhar, Clough, Andrew J, Sitzman, Scott D, Lince, Jeffrey R, and Martini, Ashlie

Subjects

Engineering, Materials Engineering, Fluid mechanics and thermal engineering, Mechanical engineering

Abstract

Molybdenum disulfide coatings, particularly Microseal 200-1, have been extensively used as dry film lubricants for actuating mechanisms in space applications. Although Microseal 200-1 has historically been a popular choice for space missions, recent assessments indicate a need for reexamination. This study evaluates sliding friction in air and dry gaseous nitrogen atmospheres at ambient temperatures with both linear reciprocating and rotary unidirectional tribo-tests. Measurements are performed for Microseal 200-1 applied on substrates and surface treatments commonly used in aerospace components, particularly stainless steel and a titanium alloy. Our findings indicate that the friction of stainless steel balls sliding on Microseal 200-1-coated disks is significantly influenced by the environment as well as the disk substrate material. The average friction coefficient ranges from 0.12 to 0.48 in air and from 0.04 to 0.41 in dry gaseous nitrogen, and the amount of friction is consistently much higher for the Microseal 200-1 on the stainless steel than on the titanium alloy. Microscopy and surface analyses, including scanning electron microscopy, energy-dispersive X-ray spectroscopy, and X-ray fluorescence, of the coatings on stainless steel substrates reveals that the coatings are sparse and relatively thin, likely a key factor contributing to their high friction. This insight underscores the substrate dependence of this widely used coating and highlights the importance of detailed tribological testing in accurately assessing the tribological performance of commercial dry film lubricants, a key step towards improving the reliability and effectiveness of actuating mechanisms for space applications.

Published

2024

14. Optical and acoustic ground effects simulations from terminal defense asteroid disruption via the PI method

Author

Bailey, Brin, Cohen, Alexander N, Lubin, Philip, Robertson, Darrel, Boslough, Mark, Egan, Sasha, Silber, Elizabeth A, and Patel, Dharv

Subjects

Engineering, Aerospace Engineering, Planetary defense, Hypervelocity impacts, Asteroid fragmentation, Acoustic shock waves, Mechanical Engineering, Aerospace & Aeronautics, Aerospace engineering

Published

2024

15. Conforming mesh modeling of multi-physics effect on residual stress in multi-layer powder bed fusion process

Author

Kishore, Mysore Nagaraja, Qian, Dong, Soshi, Masakazu, and Li, Wei

Subjects

Manufacturing Engineering, Engineering, Powder bed fusion, Computational fluid dynamics, Finite element method, Discrete element method, Conforming mesh, Residual stress, Industrial Engineering & Automation, Manufacturing engineering, Mechanical engineering

Abstract

The current research aims to predict the residual stress accumulation and evolution in the powder bed fusion processed multi-layer thin wall structures through a conforming mesh modeling approach. It involves the discrete element method (DEM) interfaced with the volume of fluid (VOF) method using computational fluid dynamics (CFD) coupled with the finite element method (FEM). The conforming mesh approach developed in the research predicts multi-physics, its induced porosity, and the cumulative effect on the residual stress in the powder bed fusion processed Ti-6Al-4V thin wall structures. The results of the residual stress in the multi-layered component from this method were further quantitatively compared with the non-conforming finite element method. The results show the conforming mesh approach was not only effective in capturing the layer geometry, and defects induced during the printing, but also predicted the residual stress in the region of the defect more accurately than the non-conforming mesh methods.

Published

2024

16. Community solar reaches adopters underserved by rooftop solar

Author

O’Shaughnessy, Eric, Barbose, Galen, Kannan, Sudha, and Sumner, Jenny

Subjects

Engineering, Electrical Engineering, Mechanical Engineering, Electrical and Electronic Engineering, Environmental Engineering, Electrical engineering, Mechanical engineering

Abstract

Community solar, a business model where multiple customers buy output from shared solar systems, has expanded solar access among multifamily housing occupants, renters, and low-income households. Policies to enable community solar could be expanded and benefits of access augmented through targeted measures to support community solar adoption in underserved communities.

Published

2024

17. Author Correction: Evaluating community solar as a measure to promote equitable clean energy access

Author

O’Shaughnessy, Eric, Barbose, Galen, Kannan, Sudha, and Sumner, Jenny

Subjects

Engineering, Electrical Engineering, Mechanical Engineering, Electrical and Electronic Engineering, Environmental Engineering, Electrical engineering, Mechanical engineering

Abstract

Correction to: Nature Energyhttps://doi.org/10.1038/s41560-024-01546-2, published online 3 June 2024 In the version of the article initially published, data in Fig. 5b–d were displayed incorrectly and have now been amended in the HTML and PDF versions of the article. The original and corrected figures can be seen below in Fig. 1. (Figure presented.)

Published

2024

18. Machine-learning-assisted long-term G functions for bidirectional aquifer thermal energy storage system operation

Author

Chen, Kecheng, Sun, Xiang, Soga, Kenichi, Nico, Peter S, and Dobson, Patrick F

Subjects

Fluid Mechanics and Thermal Engineering, Engineering, Electrical Engineering, Mechanical Engineering, Machine Learning and Artificial Intelligence, Affordable and Clean Energy, Resources Engineering and Extractive Metallurgy, Interdisciplinary Engineering, Energy, Electrical engineering, Fluid mechanics and thermal engineering, Mechanical engineering

Abstract

Optimization of aquifer thermal energy storage (ATES) performance in a building system is an important topic for maximizing the seasonal offset between energy demand and supply and minimizing the building's primary energy consumption. To evaluate ATES performance with bidirectional operation, this study develops an analytical solution-based model to simulate the spatiotemporal thermal response in an aquifer. The model consists of three temperature response functions, similar to the G functions in borehole thermal energy storage (BTES), to estimate the transient temperature profile in the aquifer during seasonally varying injection and extraction of hot/cold water. Applying machine learning (ML) based data classification and regression techniques to the results of a series of finite element (FE) benchmark simulations of typical ATES configurations, model input parameters are linked to the subsurface thermal, hydrogeological, and ATES operational properties. Compared to the benchmark simulation results, the errors of the proposed model in estimating the annual energy storage and locating the thermally affected area are about 3 % and 1 %, respectively. The model was applied to a previous short-term case study, and the error in the transient production temperature estimation is about 1 %. The long-term heat recovery ratio estimated from the model also compares well to those calculated from the previous study and the validated numerical model. Because of its fast computation, the proposed model can be coupled with the individual building system simulation and used for preliminary ATES design, and this will allow for greater exploration of ATES operational space and, therefore, better choices of ATES operating conditions. The proposed model can also be coupled with the district heating and cooling network simulation for computationally efficient city-scale long-term ATES potential assessment.

Published

2024

19. Exceptional cryogenic-to-ambient impact toughness of a low carbon micro-alloyed steel with a multi-heterogeneous structure

Author

Xu, Xiaoning, Kumar, Punit, Cao, Ruqing, Ye, Qibin, Chu, Yuexin, Tian, Yong, Li, Yi, and Ritchie, Robert O

Subjects

Engineering, Materials Engineering, Heterogeneous structure, Low carbon micro-alloyed steel, Rolling, Impact toughness, Toughening mechanism, Condensed Matter Physics, Mechanical Engineering, Materials, Materials engineering, Mechanical engineering, Condensed matter physics

Abstract

A low-carbon micro-alloyed (LCMA) steel with a body-centered cubic (bcc) crystal structure suitable for extremely low temperatures was developed by overcoming the intrinsic ductile-to-brittle transition in bcc alloys at cryogenic temperatures. The excellent cryogenic-to-ambient impact toughness in the LCMA rolled plate results from its heterogeneous microstructure, which gradually changes from bamboo-like ultrafine grains (∼ 1.1 μm) on the surface to relatively equiaxed coarse grains in the core (∼ 3.4 μm), accompanied by a distinct texture gradient variation. The heterostructured LCMA steel displays a cryogenic impact toughness of ∼200 J/cm2 at 77 K, which is 24 times higher than the coarse-grained LCMA steel. Such high impact toughness of heterostructured LCMA arises from the coordinated deformation mechanisms over different length-scales coupled with delamination toughening. At 77 K, the heterostructured steel plate deforms by forming cellular sub-structures at the core to the surface, which refines the microstructure and promotes hetero-deformation induced (HDI) hardening to improve intrinsic toughening. Moreover, the subsequent delamination process induces extrinsic toughening by shielding and blunting the cracks, with the local plane-stress conditions induced by delamination promoting ductile fracture of the coarse grains in the core regions. This low alloy steel with its heterogeneous microstructure exhibits extraordinary impact toughness at cryogenic temperatures highlights the possibility of materials design strategies for sustainable development.

Published

2024

20. Evaluating community solar as a measure to promote equitable clean energy access

Author

O’Shaughnessy, Eric, Barbose, Galen, Kannan, Sudha, and Sumner, Jenny

Subjects

Engineering, Electrical Engineering, Mechanical Engineering, Affordable and Clean Energy, Electrical and Electronic Engineering, Environmental Engineering, Electrical engineering, Mechanical engineering

Abstract

Rooftop and community solar are alternative product classes for residential solar in the United States. Community solar, where multiple households buy solar from shared systems, could make solar more accessible by reducing initial costs and removing adoption barriers for renters and multifamily building occupants. Here we test whether community solar has expanded solar access in the United States. On the basis of a sample of 11 states, we find that community solar adopters are about 6.1 times more likely to live in multifamily buildings than rooftop solar adopters, 4.4 times more likely to rent and earn 23% less annual income. We do not find that community solar expands access in terms of race. These differences are driven, roughly evenly, by inherent differences between the two solar products and by policies to promote low-income community solar adoption. The results suggest that alternative solar products can expand solar access and that policy could augment such benefits.

Published

2024

21. The Influence of Residual Stress on Fatigue Crack Growth Rates in Stainless Steel Processed by Different Additive Manufacturing Methods

Author

Smudde, Christine M, San Marchi, Christopher C, Hill, Michael R, and Gibeling, Jeffery C

Subjects

Manufacturing Engineering, Engineering, additive manufacturing, directed energy deposition, fatigue crack growth, laser powder bed fusion, microstructure, residual stress, Materials Engineering, Materials, Materials engineering, Mechanical engineering

Abstract

The properties and microstructure of Type 304L stainless steel produced by two additive manufacturing (AM) methods—directed energy deposition (DED) and powder bed fusion (PBF)—are evaluated and compared. Localized heating and steep temperature gradients of AM processes lead to significant residual stress and distinctive microstructures, which may be process-specific and influence mechanical behavior. Test data show that materials produced by DED and PDF have small differences in tensile strengths but clear differences in residual stress and microstructural features. Measured fatigue crack growth rates (FCGRs) for cracks propagating parallel to and perpendicular to the build directions differ between the two AM materials. To separate the influences of residual stress and microstructure, K-control test procedures with decreasing and constant stress intensity factor ranges are used to measure FCGRs in the near-threshold regime (crack growth rates ≤ 1 × 10−8 m/cycle). Residual stress is quantified by the residual stress intensity factor, Kres, measured by the online crack compliance method. Correcting the FCGR data for differences in Kres brings results for specimens of the two AM materials into agreement with each other and with results for wrought specimens, when the latter are corrected for crack closure. Differences in microstructure and tensile strength have an insignificant influence on FCGRs in these tests.

Published

2024

22. Evaluating Possible Formation Mechanisms of Criegee Intermediates during the Heterogeneous Autoxidation of Squalene

Author

Zeng, Meirong and Wilson, Kevin R

Subjects

Engineering, Mechanical Engineering, Life Below Water, Squalene, Oxidation-Reduction, Kinetics, Hydroxyl Radical, Models, Chemical, Autoxidation, Criegee intermediates, beta-Hydroxyperoxy radical, Heterogeneous kinetics, Kineticmodeling, Kinetic modeling, β-Hydroxy peroxy radical, Environmental Sciences

Abstract

Organic molecules in the environment oxidatively degrade by a variety of free radical, microbial, and biogeochemical pathways. A significant pathway is heterogeneous autoxidation, in which degradation occurs via a network of carbon and oxygen centered free radicals. Recently, we found evidence for a new heterogeneous autoxidation mechanism of squalene that is initiated by hydroxyl (OH) radical addition to a carbon-carbon double bond and apparently propagated through pathways involving Criegee Intermediates (CI) produced from β-hydroxy peroxy radicals (β-OH-RO2•). It remains unclear, however, exactly how CI are formed from β-OH-RO2•, which could occur by a unimolecular or bimolecular pathway. Combining kinetic models and multiphase OH oxidation measurements of squalene, we evaluate the kinetic viability of three mechanistic scenarios. Scenario 1 assumes that CI are formed by the unimolecular bond scission of β-OH-RO2•, whereas Scenarios 2 and 3 test bimolecular pathways of β-OH-RO2• to yield CI. Scenario 1 best replicates the entire experimental data set, which includes effective uptake coefficients vs [OH] as well as the formation kinetics of the major products (i.e., aldehydes and secondary ozonides). Although the unimolecular pathway appears to be kinetically viable, future high-level theory is needed to fully explain the mechanistic relationship between CI and β-OH-RO2• in the condensed phase.

Published

2024

23. Effects of interparticle cohesion on the collapse of granular columns

Author

Sharma, Ram Sudhir, Sarlin, Wladimir, Xing, Langqi, Morize, Cyprien, Gondret, Philippe, and Sauret, Alban

Subjects

Civil Engineering, Engineering, Resources Engineering and Extractive Metallurgy, Applied Mathematics, Classical Physics, Mechanical Engineering, Fluid mechanics and thermal engineering

Published

2024

24. Quantifying small-scale anisotropy in turbulent flows

Author

Chowdhuri, Subharthi and Banerjee, Tirtha

Subjects

Fluid Mechanics and Thermal Engineering, Engineering, Applied Mathematics, Classical Physics, Mechanical Engineering, Fluid mechanics and thermal engineering

Abstract

The verification of whether small-scale turbulence is isotropic remains a grand challenge. The difficulty arises because the presence of small-scale anisotropy is tied to the dissipation tensor, whose components require the full three-dimensional information of the flow field in both high spatial and temporal resolution, a condition rarely satisfied in turbulence experiments, especially during field scale measurement of atmospheric turbulence. To circumvent this issue, an intermittency-anisotropy framework is proposed through which we successfully extract the features of small-scale anisotropy from single-point measurements of turbulent time series by exploiting the properties of small-scale intermittency. Specifically, this framework quantifies anisotropy by studying the contrasting effects of burstlike activities on the scalewise production of turbulence kinetic energy between the horizontal and vertical directions. The veracity of this approach is tested by applying it over a range of datasets covering an unprecedented range in the Reynolds numbers (Re≈103-106), sampling frequencies (10 kHz to 10 Hz), surface conditions (aerodynamically smooth surfaces to typical grasslands to forest canopies), and flow types (channel flows, boundary-layer flows, atmospheric flows, and flows over forest canopies). For these diverse datasets, the findings indicate that the effects of small-scale anisotropy persists up to the integral scales of the streamwise velocity fluctuations and there exists a universal relationship to predict this anisotropy from the two-component state of the Reynolds stress tensor. This relationship is important towards the development of next-generation closure models of wall turbulence by incorporating the effects of anisotropy at smaller scales of the flow.

Published

2024

25. Fast In-Hand Slip Control on Unfeatured Objects With Programmable Tactile Sensing

Author

Gloumakov, Yuri, Huh, Tae Myung, and Stuart, Hannah S

Subjects

Data Management and Data Science, Information and Computing Sciences, Engineering, Electronics, Sensors and Digital Hardware, Clinical Research, Mechanical Engineering, Control engineering, mechatronics and robotics, Artificial intelligence

Abstract

Accurate dynamic object manipulation in a robotic hand remains a difficult task, especially when frictional slip is involved. Prior solutions involve extensive data collection to train complex models to control the hand that do not necessarily generalize to other slip circumstances. Our approach focuses on direct slip sensing using a tactile sensor with a capacitive array, coupled with a programmable system on a chip, capable of mode switching and sampling rate adjustment. We characterize the sensor's capacity to sense slip features at higher speeds and introduce a novel methodology for estimating motions. Low-level sensor reprogramming that couples multiple taxels improves slip avoidance and reaction time during rapid slip onset events. The technology also tracks dominant surface vibration frequencies resulting from stick-slip cycles, estimating speed and acceleration of smooth flat surfaces. Using a parallel-jaw robotic gripper, we demonstrate dynamic repositioning of objects lacking trackable surface features within the hand. The goal of this investigation is to support faster reasoning and reflexes for dynamic dexterous robots that experience directional in-hand slip.

Published

2024

26. Evaluating the Potential for Solar-Plus-Storage Backup Power as Homes Become More Efficient, Flexible, and Electrified

Author

Gorman, Will, Barbose, Galen, Miller, Chandler, White, Philip, Carvallo, JP, and Baik, Sunhee

Subjects

Backup power, electric resilience, electrification, energy efficiency, load flexibility, solar+storage, Fluid Mechanics and Thermal Engineering, Engineering, Electrical Engineering, Mechanical Engineering, Affordable and Clean Energy, Electric resilience, Energy efficiency, Load flexibility, Electrification, Solar, Storage, Resources Engineering and Extractive Metallurgy, Interdisciplinary Engineering, Energy, Electrical engineering, Fluid mechanics and thermal engineering, Mechanical engineering

Abstract

Adoption of residential behind-the-meter solar photovoltaic-plus-storage systems (PVESS) is driven, in part, by customer demand for backup power. However, there is limited understanding of how these systems perform over a range of building stock conditions that will evolve with future efficiency and electrification trends, posing challenges for identifying optimal electric resiliency investments. This study quantifies how residential energy consumption impacts the capability of PVESS to provide home backup power during long-duration power interruptions. We model statistically representative distributions of the residential building stock and estimate storage sizes required to provide backup power as a series of building envelope efficiency, load flexibility, and electrification measures are applied. For the baseline building stock, median storage size requirements range from 10 kWh in temperate weather conditions to 90 kWh in hot climates for a 3-day power interruption. Applying energy efficiency and temperature set-point adjustments reduce storage size requirements by 2–45 kWh (16%–53 %). In hot locations, heat pump retrofits reduce median storage sizing by an additional 10–30 kWh while in cold locations, they drive 10–50 kWh of storage capacity increase. Our results suggest that bi-directional EV charging may be essential to enabling PVESS backup of heating and cooling, given their typically large kWh sizes.

Published

2024

27. Ion Implantation-Induced Plastic Phenomena in Metallic Alloys

Author

Warren, Patrick H, Clement, Caleb D, Sun, Yongwen, Ciston, Jim, Ophus, Colin, Yang, Yang, and Wharry, Janelle P

Subjects

Engineering, Materials Engineering, Mechanical Engineering, Resources Engineering and Extractive Metallurgy, Materials, Materials engineering, Mechanical engineering, Resources engineering and extractive metallurgy

Abstract

Ion implantation is widely used for doping semiconductors or electroceramic materials and probing material behaviors in extreme radiation environments. However, implanted ions can induce compressive stresses into the host material, which can induce plasticity and mesoscopic deformation. However, these phenomena have almost exclusively been observed in brittle ionic and/or covalently bonded materials. Here, we present transmission electron microscopy observations of unusual implantation-induced plasticity in two metallic alloys. First, Fe2+ ions induce dislocation plasticity below the implanted layer in a model Fe-P alloy. Next, He+ ions form pressurized cavities which activate the fcc-to-hcp strain-induced martensitic transformation in Alloy 625. In both cases, the plasticity can be explained by a combination of implanted ions being incorporated into the lattice and the creation of irradiation defects. These findings have significant implications for mechanical testing of ion-implanted layers, while also opening pathways for using ion implantation to tune stress distributions in metallic alloys.

Published

2024

28. Fluctuation-induced transitions in anisotropic two-dimensional turbulence

Author

Xu, Lichuan, van Kan, Adrian, Liu, Chang, and Knobloch, Edgar

Subjects

Fluid Mechanics and Thermal Engineering, Engineering, Applied Mathematics, Classical Physics, Mechanical Engineering, Fluid mechanics and thermal engineering

Abstract

Two-dimensional (2D) turbulence features an inverse energy cascade that produces large-scale flow structures such as large-scale vortices (LSVs) and unidirectional jets. We investigate the dynamics of such large-scale structures using extensive direct numerical simulations (DNS) of stochastically forced, viscously damped 2D turbulence within a periodic rectangular (Cartesian) domain [0,Lx]×[0,Ly]. LSVs form and dominate the system when the domain aspect ratio δ=Lx/Ly≈1, while unidirectional jets predominate at δ≳1.1. At intermediate values of δ, both structures are metastable, and fluctuation-induced transitions between LSVs and jets are observed. Based on large-scale energy balance in the condensate, we derive and verify predictions for the dependence of the total kinetic energy and the flow polarity on the nondimensional control parameters. We further collect detailed statistics on the lifetimes of LSVs and jets from DNS runs of up to 10738 viscous diffusive time units in length. The distribution of the lifetimes is consistent with that of a memoryless Poisson process. The data are compatible with an exponential dependence of the mean lifetime on the aspect ratio δ. In addition, the mean lifetimes depend sensitively on the Reynolds number Re: As Re increases, the energy gap between LSV (lower energy) and jet states (higher energy) arising from anisotropic dissipation increases, leading to an increase in lifetimes that is approximately exponential in Re for both LSVs and jets. Similarly, as the ratio of the forcing scale to the domain size increases, the transition rates increase sharply, confirming earlier findings. We investigate the transition dynamics in terms of kinetic energy, flow polarity, modal amplitude, and 2D phase-space diagrams, revealing that the transitions occur in two stages: In the initial stage, an efficient redistribution of kinetic energy by nonlinear triadic interactions facilitates a rapid transition from LSVs to jets and vice versa. In the second stage, the kinetic energy of the newly formed structure slowly adjusts to its associated (higher or lower) equilibrium value on a longer, viscous timescale, leading to a time delay that results in hysteretic transition behavior. Fluctuation-induced transitions may also occur between different numbers of jets. Our findings shed new light on the dynamics of coherent large-scale structures in anisotropic turbulence.

Published

2024

29. Tensile creep behavior of the Nb45Ta25Ti15Hf15 refractory high entropy alloy

Author

Sahragard-Monfared, Gianmarco, Belcher, Calvin H, Bajpai, Sakshi, Wirth, Mark, Devaraj, Arun, Apelian, Diran, Lavernia, Enrique J, Ritchie, Robert O, Minor, Andrew M, Gibeling, Jeffery C, Zhang, Cheng, and Zhang, Mingwei

Subjects

Engineering, Materials Engineering, Creep, High-temperature deformation, Mechanism, Thermally activated processes, High-entropy alloys, Condensed Matter Physics, Mechanical Engineering, Materials, Materials engineering, Mechanical engineering, Condensed matter physics

Abstract

The tensile creep behavior of a vacuum arc-melted Nb45Ta25Ti15Hf15 refractory high entropy alloy was investigated over a constant true stress range of 50–300 MPa at a temperature of 1173 K. Creep tests were carried out in both high vacuum (5 × 10−6 torr) and ultrahigh purity Ar gas to examine the environmental effect. The samples tested in vacuum exhibited power law behavior with a stress exponent of 4.1 and exceptional tensile creep ductility, whereas those tested in Ar suffered significant embrittlement due to HfO2 formation at grain boundaries, which was exacerbated at low applied stresses where extended exposure to residual O2 gas resulted in more extensive brittle intergranular fracture. Phase decomposition occurred after long-term thermal exposure, where a second Hf-rich body-centered cubic phase formed predominantly at grain boundaries but did not cause embrittlement. Compared to the equiatomic TaNbHfZrTi (Senkov alloy) and face-centered cubic multiple-principal element alloys, Nb45Ta25Ti15Hf15 has superior creep resistance, especially at high applied stresses, while maintaining excellent creep ductility. Transmission electron microscopy revealed that creep deformation in Nb45Ta25Ti15Hf15 at 1173 K is controlled by cross-kink collisions from screw dislocations that results in dipole drag at lower strain rates and jog drag at higher strain rates.

Published

2024

30. A Numerical Simulation of PFPE Lubricant Kinetics in HAMR Air Bearing

Author

Tom, Roshan Mathew, Cheng, Qilong, and Bogy, David B

Subjects

Engineering, Aerospace Engineering, Heat-assisted magnetic recording, Air bearing, Lubricant, Smear, Materials Engineering, Mechanical Engineering, Mechanical Engineering & Transports, Materials engineering, Mechanical engineering

Abstract

Abstract: This report investigates the kinetics of lubricant molecules in the HAMR air bearing to understand the initiation and growth of PFPE contamination on the head surface. The collisions with the air bearing induce three forces—drag, thermophoresis, and lift. Of these, we find that lift forces are negligible. Then, a sensitivity analysis of the remaining two forces reveals the conditions where they dominate. Further, a hybrid simulation strategy is utilized to track their movements. The results show that the contaminations (smear) highly depend on the interplay between the thermophoresis and drag forces. We then explain the mechanism of the formation of the various observed patterns. Finally, we offer some recommendations to exploit the air bearing to contain smear on the head.

Published

2024

31. Introduction to Mechanical Design and Manufacturing

Author

Jensen, David, author

Subjects

Engineering and Technology, Mechanical Engineering, Textbooks

Abstract

An introductory text on the design and manufacturing of products from a mechanical engineering perspective.

Published

2024

32. From theORy to application : learning to optimize with Operations Research in an interactive way

Author

Bombelli, Alessandro, author, Atasoy, Bilge, author, Fazi, Stefano, author, and Boschma, Doris, author

Subjects

Engineering and Technology, Mechanical Engineering, Textbooks

Abstract

This book serves as a comprehensive roadmap for navigating the realm of Operations Research (OR). From laying down fundamental mathematical principles to crafting precise modeling techniques and their solution methods, it culminates in a panoramic view of OR models mirroring real-world operations. Delving into diverse applications-from assignment problems to network problems like graph coloring and minimum spanning trees, and navigating through routing problems that are very common in logistics-the book equips readers with practical insights. Each model is accompanied by meticulously detailed examples, seamlessly integrated with hyperlinked codes accessible via an open repository. Moreover, it introduces an engaging dimension with hyperlinks to three serious games replicating some cornerstone OR models, offering a playful yet educational environment for solo or group experimentation.

Published

2024

33. Hydrogen production using curtailed electricity of firm photovoltaic plants: Conception, modeling, and optimization

Author

Yang, Guoming, Yang, Dazhi, Perez, Marc J, Perez, Richard, Kleissl, Jan, Remund, Jan, Pierro, Marco, Cheng, Yuan, Wang, Yi, Xia, Xiang’ao, Xu, Jianing, Lyu, Chao, Liu, Bai, and Zhang, Hao

Subjects

Engineering, Electrical Engineering, Affordable and Clean Energy, Firm generation, Firm photovoltaic plant, Curtailment, Hydrogen production, Refined model, Electrical and Electronic Engineering, Mechanical Engineering, Energy, Chemical engineering, Electrical engineering, Mechanical engineering

Published

2024

34. Coercivity enhancement in hematite/permalloy heterostructures across the Morin transition

Author

Wang, Tianxing D, Basaran, Ali C, Hage, Ralph El, Li, Junjie, Navarro, Henry, Torres, Felipe E, de la Fuente, Oscar R, and Schuller, Ivan K

Subjects

Engineering, Physical Sciences, Condensed Matter Physics, Materials Engineering, Mechanical Engineering, Applied Physics, Materials engineering, Condensed matter physics

Published

2024

35. Methodology for Assessing Retrofitted Hydrogen Combustion and Fuel Cell Aircraft Environmental Impacts

Author

Alsamri, Khaled, De La Cruz, Jessica, Emmanouilidi, Melody, Huynh, Jacqueline, and Brouwer, Jack

Subjects

Aircraft, Fuel Cell, Hydrogen, Hydrogen Fuel cell, Engineering, Aerospace Engineering, Climate Action, Hydrogen Fuelled Aircraft, Proton Exchange Membrane Fuel Cells, Hydrogen Combustion, Cessna Citation, Cost Effectiveness, Liquid Hydrogen, Hydrogen Propulsion, Hydrogen Storage, Hydrogen-Powered Aircraft, Aircraft Propulsion, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Mechanical Engineering, Aerospace & Aeronautics, Aerospace engineering

Abstract

Hydrogen (H2) combustion and solid oxide fuel cells (SOFCs) can potentially reduce aviation-produced greenhouse gas emissions compared to kerosene propulsion. This paper outlines a methodology for evaluating performance and emission tradeoffs when retrofitting conventional kerosene-powered aircraft with lower-emissionH2 combustion and SOFC hybrid alternatives. The proposed framework presents a constant-range approach for designing liquid hydrogen fuel tanks, considering insulation, sizing, center of gravity, and power constraints. A lifecycle assessment evaluates greenhouse gas emissions and contrail formation effects for carbon footprint mitigation, while a cost analysis examines retrofit implementation consequences. A Cessna Citation 560XLS+ case study shows a 5% mass decrease for H2 combustion and a 0.4% mass decrease for the SOFC hybrid, at the tradeoff of removing three passengers. The lifecycle analysis of green hydrogen in aviation reveals a significant reduction in CO2 emissions for H2 combustion and SOFC systems, except for natural-gas-produced H2 combustion, when compared to Jet-A fuel. However, this environmental benefit is contrasted by an increase in fuel cost per passenger-km for green H2 combustion and a rise for natural-gas-produced H2 SOFC compared to kerosene. The results suggest that retrofitting aircraft with alternative fuels could lower carbon emissions, noting the economic and passenger capacity tradeoffs.

Published

2024

36. Saccharomyces cerevisiae CellWall Remodeling in the Absence of Knr4 and Kre6 Revealed by Nano-FourierTransform Infrared Spectroscopy

Author

Bakir, Gorkem, Dahms, Tanya ES, Martin-Yken, Helene, Bechtel, Hans A, and Gough, Kathleen M

Subjects

Biochemistry and Cell Biology, Biological Sciences, beta-Glucans, Cell Wall, Chitin, Glucans, Saccharomyces cerevisiae, Saccharomyces cerevisiae Proteins, Spectroscopy, Fourier Transform Infrared, ATR, Cell wall integrity, attenuated total reflection, chitin, far-field infrared spectroscopy, glucan, knr4Δ, kre6Δ, mannan, synchrotron infrared nanospectroscopy, Analytical Chemistry, Physical Chemistry (incl. Structural), Mechanical Engineering

Abstract

The cell wall integrity (CWI) signaling pathway regulates yeast cell wall biosynthesis, cell division, and responses to external stress. The cell wall, comprised of a dense network of chitin, β-1,3- and β-1,6- glucans, and mannoproteins, is very thin,

Published

2024

37. A robust I–V curve correction procedure for degraded photovoltaic modules

Author

Li, Baojie, Hansen, Clifford W, Chen, Xin, Diallo, Demba, Migan-Dubois, Anne, Delpha, Claude, and Jain, Anubhav

Subjects

Engineering, Electrical Engineering, Electrical and Electronic Engineering, Mechanical Engineering, Interdisciplinary Engineering, Energy

Abstract

To enable health monitoring and fault diagnosis of PV modules using current-voltage characteristics (I–V curves), it is generally necessary to correct the I–V curves measured under different environmental conditions to the standard condition. The most common correction methods are those from IEC 60891: 2021 standard. However, these methods can introduce significant errors when dealing with degraded PV modules due to the inability to account for changes in resistance. To address this, we propose an improved I–V curve procedure, denoted Pdynamic, which considers different types of degradation by dynamically deriving the correction coefficients from the measured I–V curves. To evaluate the performance, we simulate I–V curves across a wide range of irradiance and temperature for the healthy and degraded module, where the degradation involves increased series resistance, decreased shunt resistance, or both. The results reveal that Pdynamic can produce corrected I–V curves closer to the reference ones than Procedures 1, 2, and 4 of the IEC 60891:2021 standard. Moreover, Pdynamic exhibits resilience to both seasonal fluctuations and varying levels of degradation. These results highlight Pdynamic as a promising and robust I–V curve correction method, particularly for degraded PV modules. A Python-based open-source tool for this procedure is also available at https://github.com/DuraMAT/IVcorrection.

Published

2024

38. Effect of fabrication processes on BaTiO3 capacitor properties

Author

Jiang, Yizhe, Tian, Zishen, Kavle, Pravin, Pan, Hao, and Martin, Lane W

Subjects

Engineering, Materials Engineering, Physical Sciences, Electrical and Electronic Engineering, Mechanical Engineering, Materials engineering, Nanotechnology, Condensed matter physics

Abstract

There is an increasing desire to utilize complex functional electronic materials such as ferroelectrics in next-generation microelectronics. As new materials are considered or introduced in this capacity, an understanding of how we can process these materials into those devices must be developed. Here, the effect of different fabrication processes on the ferroelectric and related properties of prototypical metal oxide (SrRuO3)/ferroelectric (BaTiO3)/metal oxide (SrRuO3) heterostructures is explored. Two different types of etching processes are studied, namely, wet etching of the top SrRuO3 using a NaIO4 solution and dry etching using an Ar+-ion beam (i.e., ion milling). Polarization-electric-field hysteresis loops for capacitors produced using both methods are compared. For the ion-milling process, it is found that the Ar+ beam can introduce defects into the SrRuO3/BaTiO3/SrRuO3 devices and that the milling depth strongly influences the defect level and can induce a voltage imprint on the function. Realizing that such processing approaches may be necessary, work is performed to ameliorate the imprint of the hysteresis loops via ex situ “healing” of the process-induced defects by annealing the ferroelectric material in a barium-and-oxygen-rich environment via a chemical-vapor-deposition-style process. This work provides a pathway for the nanoscale fabrication of these candidate materials for next-generation memory and logic applications.

Published

2024

39. Effect of superhydrophobic surfaces on rod bundle flow dynamics

Author

Rodriguez, Angel F and Mäkiharju, Simo A

Subjects

Fluid Mechanics and Thermal Engineering, Engineering, Aerospace Engineering, Mechanical Engineering, Interdisciplinary Engineering, Fluids & Plasmas

Abstract

Pressurized water reactors are designed to operate in a single-phase flow. However, during a flow loss or other off-design conditions liquid temperature may exceed saturation temperature and, if a continuous film of gas forms, a boiling casualty may result. If superhydrophobic surfaces are introduced among the fuel cell assembly, vapor bubbles show an affinity to these surfaces and gas may coalesce to escape faster, resulting in a larger margin to reach critical heat flux. In the present study, we consider air and liquid water mixture examining the overall flow dynamics in a case with no bulk liquid flow, reminiscent of a case with coolant pump failure. The parameter ranges examined span Reynolds number based on gas superficial velocity up to 5300 and produced bubble with bond numbers from 1 to 270, and Weber numbers based on estimated terminal velocity from 0.6 to 150. The Morton number was fixed at 2.63×10-11. As the flow with high gas volume fraction becomes optically opaque and is sensitive to intrusive instrumentation, a custom-built photon-counting dual energy threshold X-ray computed tomography system is employed for measurement of the time average void fraction within the bundle non-intrusively. Two dual plane wire mesh sensors upstream and downstream of the rod bundle are employed to obtain comparison void fraction, velocity profiles and bubble size distributions. Additionally, traditional pressure-based gas holdup measurements are employed to calculate time- and volume-averaged void fraction. The data show that the presence of superhydrophobic surface being present in the rod bundle results in a significantly lower gas volume fraction and higher localized void fraction at the superhydrophobic coating, as compared to those in a similar rod bundle without superhydrophobic internals. Graphical abstract: (Figure presented.)

Published

2024

40. Particle hydrodynamics in acoustic fields: Unifying acoustophoresis with streaming

Author

Zhang, Xiaokang, Minten, Jake, and Rallabandi, Bhargav

Subjects

Fluid Mechanics and Thermal Engineering, Engineering, Applied Mathematics, Classical Physics, Mechanical Engineering, Fluid mechanics and thermal engineering

Published

2024

41. Unraveling the Highly Plastic Behavior of ALD‐Aluminum Oxide Encapsulations by Small‐Scale Tensile Testing

Author

Vogl, Lilian M, Schweizer, Peter, Minor, Andrew M, Michler, Johann, and Utke, Ivo

Subjects

Engineering, Materials Engineering, Nanotechnology, ALD, characterization, EELS, in situ electron microscopy, metal oxides, nanowires, TEM, Materials, Civil engineering, Materials engineering, Mechanical engineering

Abstract

We present a study directly measuring the electron‐beam‐induced plasticity of amorphous Al2O3 coatings. Core–shell nanostructures are employed as small‐scale model systems for two‐dimensional coatings made by atomic layer deposition (ALD). Copper nanowires (NWs) are used as substrates for ALD deposition, representing a model system for interconnects commonly found in integrated circuits. Experiments are performed in situ in a transmission electron microscope (TEM) and further analyzed with electron energy loss spectroscopy (EELS). Our in situ TEM tensile experiments reveal the highly plastic behavior of the ALD shell, which withstands a maximum strain of 188%. Comparable samples under beam‐off conditions show a brittle fracture, which underlines the effect of electron irradiation. The electron‐beam‐activated bond switching within the amorphous network enables compensation of the applied tensile strain, leading to viscous flow. By incorporating an intermediate nanocrystalline layer within the Al2O3 shell, the plasticity is suppressed and brittle fracture occurs. This work directly demonstrates the tuning of mechanical properties in amorphous ALD structures through electron irradiation.

Published

2024

42. Subject-specific one-dimensional fluid dynamics model of chronic thromboembolic pulmonary hypertension

Author

Kachabi, Amirreza, Colebank, Mitchel J, and Chesler, Naomi C

Subjects

Fluid Mechanics and Thermal Engineering, Engineering, Biomedical Engineering, Bioengineering, Lung, Cardiovascular, Aetiology, 2.1 Biological and endogenous factors, Animals, Humans, Hypertension, Pulmonary, Pulmonary Embolism, Hydrodynamics, Pulmonary Artery, Hemodynamics, CTEPH, 1D CFD, Hemodynamics modeling, Wall shear stress, Mechanical Engineering, Biomedical engineering

Abstract

Chronic thromboembolic pulmonary hypertension (CTEPH) develops due to the accumulation of blood clots in the lung vasculature that obstructs flow and increases pressure. The mechanobiological factors that drive progression of CTEPH are not understood, in part because mechanical and hemodynamic changes in the small pulmonary arteries due to CTEPH are not easily measurable. Using previously published hemodynamic measurements and imaging from a large animal model of CTEPH, we applied a subject-specific one-dimensional (1D) computational fluid dynamic (CFD) approach to investigate the impact of CTEPH on pulmonary artery stiffening, time-averaged wall shear stress (TAWSS), and oscillatory shear index (OSI) in extralobar (main, right, and left) pulmonary arteries and intralobar (distal to the extralobar) arteries. Our results demonstrate that CTEPH increases pulmonary artery wall stiffness and decreases TAWSS in extralobar and intralobar arteries. Moreover, CTEPH increases the percentage of the intralobar arterial network with both low TAWSS and high OSI, quantified by the novel parameter φ , which is related to thrombogenicity. Our analysis reveals a strong positive correlation between increases in mean pulmonary artery pressure (mPAP) and φ from baseline to CTEPH in individual subjects, which supports the suggestion that increased φ drives disease severity. This subject-specific experimental-computational framework shows potential as a predictor of the impact of CTEPH on pulmonary arterial hemodynamics and pulmonary vascular mechanics. By leveraging advanced modeling techniques and calibrated model parameters, we predict spatial distributions of flow and pressure, from which we can compute potential physiomarkers of disease progression. Ultimately, this approach can lead to more spatially targeted interventions that address the needs of individual CTEPH patients.

Published

2024

43. A Systems Approach to Biomechanics, Mechanobiology, and Biotransport.

Author

Peirce-Cottler, Shayn M, Sander, Edward A, Fisher, Matthew B, Deymier, Alix C, LaDisa, John F, O'Connell, Grace, Corr, David T, Han, Bumsoo, Singh, Anita, Wilson, Sara E, Lai, Victor K, and Clyne, Alisa Morss

Subjects

Engineering, Biomedical Engineering, Bioengineering, Quality Education, Humans, Biomechanical Phenomena, Biophysics, Systems Analysis, Mechanical Engineering, Biomedical engineering

Abstract

The human body represents a collection of interacting systems that range in scale from nanometers to meters. Investigations from a systems perspective focus on how the parts work together to enact changes across spatial scales, and further our understanding of how systems function and fail. Here, we highlight systems approaches presented at the 2022 Summer Biomechanics, Bio-engineering, and Biotransport Conference in the areas of solid mechanics; fluid mechanics; tissue and cellular engineering; biotransport; and design, dynamics, and rehabilitation; and biomechanics education. Systems approaches are yielding new insights into human biology by leveraging state-of-the-art tools, which could ultimately lead to more informed design of therapies and medical devices for preventing and treating disease as well as rehabilitating patients using strategies that are uniquely optimized for each patient. Educational approaches can also be designed to foster a foundation of systems-level thinking.

Published

2024

44. ExaWind: Open‐source CFD for hybrid‐RANS/LES geometry‐resolved wind turbine simulations in atmospheric flows

Author

Sharma, Ashesh, Brazell, Michael J, Vijayakumar, Ganesh, Ananthan, Shreyas, Cheung, Lawrence, deVelder, Nathaniel, de Frahan, Marc T Henry, Matula, Neil, Mullowney, Paul, Rood, Jon, Sakievich, Philip, Almgren, Ann, Crozier, Paul S, and Sprague, Michael

Subjects

Fluid Mechanics and Thermal Engineering, Control Engineering, Mechatronics and Robotics, Engineering, Affordable and Clean Energy, Electrical and Electronic Engineering, Mechanical Engineering, Interdisciplinary Engineering, Energy, Electrical engineering, Environmental engineering

Abstract

Predictive high-fidelity modeling of wind turbines with computational fluid dynamics, wherein turbine geometry is resolved in an atmospheric boundary layer, is important to understanding complex flow accounting for design strategies and operational phenomena such as blade erosion, pitch-control, stall/vortex-induced vibrations, and aftermarket add-ons. The biggest challenge with high-fidelity modeling is the realization of numerical algorithms that can capture the relevant physics in detail through effective use of high-performance computing. For modern supercomputers, that means relying on GPUs for acceleration. In this paper, we present ExaWind, a GPU-enabled open-source incompressible-flow hybrid-computational fluid dynamics framework, comprising the near-body unstructured grid solver Nalu-Wind, and the off-body block-structured-grid solver AMR-Wind, which are coupled using the Topology Independent Overset Grid Assembler. Turbine simulations employ either a pure Reynolds-averaged Navier–Stokes turbulence model or hybrid turbulence modeling wherein Reynolds-averaged Navier–Stokes is used for near-body flow and large eddy simulation is used for off-body flow. Being two-way coupled through overset grids, the two solvers enable simulation of flows across a huge range of length scales, for example, 10 orders of magnitude going from O(μm) boundary layers along the blades to O(10 km) across a wind farm. In this paper, we describe the numerical algorithms for geometry-resolved turbine simulations in atmospheric boundary layers using ExaWind. We present verification studies using canonical flow problems. Validation studies are presented using megawatt-scale turbines established in literature. Additionally presented are demonstration simulations of a small wind farm under atmospheric inflow with different stability states.

Published

2024

45. Bicrystallography-informed Frenkel–Kontorova model for interlayer dislocations in strained 2D heterostructures

Author

Ahmed, Tusher, Wang, Chenhaoyue, Banerjee, Amartya S, and Admal, Nikhil Chandra

Subjects

Civil Engineering, Engineering, Materials Engineering, Mechanical Engineering, 2D materials, 2D heterostructures, Straintronics, Interface dislocations, Strain engineering, Structural relaxation, Mechanical Engineering & Transports, Civil engineering, Materials engineering, Mechanical engineering

Published

2024

46. Review of state-of-the-art micro and macro-bioreactors for the intervertebral disc

Author

McKinley, Jonathan P and O'Connell, Grace D

Subjects

Engineering, Biomedical Engineering, Pain Research, Bioengineering, Chronic Pain, Biotechnology, Animals, Humans, Intervertebral Disc Degeneration, Quality of Life, Organ Culture Techniques, Intervertebral Disc, Bioreactors, Bioreactor, Complex loading, Disc degeneration, Intervertebral disc, Mechanical Engineering, Human Movement and Sports Sciences, Biomedical engineering, Sports science and exercise

Abstract

Lower back pain continues to be a global epidemic, limiting quality of life and ability to work, due in large part to symptomatic disc degeneration. Development of more effective and less invasive biological strategies are needed to treat disc degeneration. In vitro models such as macro- or micro-bioreactors or mechanically active organ-chips hold great promise in reducing the need for animal studies that may have limited clinical translatability, due to harsher and more complex mechanical loading environments in human discs than in most animal models. This review highlights the complex loading conditions of the disc in situ, evaluates state-of-the-art designs for applying such complex loads across multiple length scales, from macro-bioreactors that load whole discs to organ-chips that aim to replicate cellular or engineered tissue loading. Emphasis was placed on the rapidly evolving more customizable organ-chips, given their greater potential for studying the progression and treatment of symptomatic disc degeneration. Lastly, this review identifies new trends and challenges for using organ-chips to assess therapeutic strategies.

Published

2024

47. Hydrogen storage and geo-methanation in a depleted underground hydrocarbon reservoir

Author

Hellerschmied, Cathrine, Schritter, Johanna, Waldmann, Niels, Zaduryan, Artur B, Rachbauer, Lydia, Scherr, Kerstin E, Andiappan, Anitha, Bauer, Stephan, Pichler, Markus, and Loibner, Andreas P

Subjects

Engineering, Electrical Engineering, Mechanical Engineering, Affordable and Clean Energy, Electrical and Electronic Engineering, Environmental Engineering, Electrical engineering, Mechanical engineering

Abstract

Coupling of power-to-gas processes with underground gas storage could effectively allow surplus electricity to be stored for later use. Depleted hydrocarbon reservoirs could be used as stores, but practical experience of hydrogen storage in such sites is limited. Here we present data from a field trial that stored 119,353 m3 of hydrogen admixed to natural gas in a depleted hydrocarbon reservoir. After 285 days, hydrogen recovery was 84.3%, indicating the process’s technical feasibility. Additionally, we report that microbes mediated hydrogen conversion to methane. In laboratory experiments studying mesocosms that mimic real reservoirs, hydrogen and carbon dioxide were converted to methane (0.26 mmol l−1 h−1 evolution rate) reproducibly over 14 cycles in 357 days. This rate theoretically allows 114,648 m3 of methane per year to be produced in the test reservoir (equivalent to ~1.08 GWh). Our research demonstrates the efficiency of hydrogen storage and the importance of geo-methanation in depleted hydrocarbon reservoirs.

Published

2024

48. Estimating the elastic modulus of concrete under moderately elevated temperatures via impulse excitation technique

Author

Coelho, Tulio, Diniz, Sofia Maria Carrato, and Rodrigues, Francisco

Published

2024

49. Numerical analysis of fire-exposed reinforced concrete sections for assessing post-heating axial and flexural capacity

Author

Gaikwad, Mahesh, Singh, Suvir, Gopalakrishnan, N., Bhargava, Pradeep, and Chourasia, Ajay

Published

2024

50. Modelling intumescent coatings for the fire protection of structural systems: a review

Author

Lucherini, Andrea and de Silva, Donatella

Published

2024