Your search keyword '"Zengbao Jiao"' showing total 17 results

1. Simultaneous enhancement of strength and conductivity via self-assembled lamellar architecture

Author

Tielong Han, Chao Hou, Zhi Zhao, Zengbao Jiao, Yurong Li, Shuang Jiang, Hao Lu, Haibin Wang, Xuemei Liu, Zuoren Nie, and Xiaoyan Song

Subjects

Science

Abstract

Abstract Simultaneous improvement of strength and conductivity is urgently demanded but challenging for bimetallic materials. Here we show by creating a self-assembled lamellar (SAL) architecture in W-Cu system, enhancement in strength and electrical conductivity is able to be achieved at the same time. The SAL architecture features alternately stacked Cu layers and W lamellae containing high-density dislocations. This unique layout not only enables predominant stress partitioning in the W phase, but also promotes hetero-deformation induced strengthening. In addition, the SAL architecture possesses strong crack-buffering effect and damage tolerance. Meanwhile, it provides continuous conducting channels for electrons and reduces interface scattering. As a result, a yield strength that doubles the value of the counterpart, an increased electrical conductivity, and a large plasticity were achieved simultaneously in the SAL W-Cu composite. This study proposes a flexible strategy of architecture design and an effective method for manufacturing bimetallic composites with excellent integrated properties.

Published

2024

2. Simultaneous enhancement of strength and ductility via microband formation and nanotwinning in an L12-strengthened alloy

Author

Lu Yang, Dingshan Liang, Zhuo Cheng, Ranxi Duan, Chuanxin Zhong, Junhua Luan, Zengbao Jiao, and Fuzeng Ren

Subjects

L12-strengthened superlattice alloy, Stacking fault energy, Nanotwins, Microbands, Strain hardening, Science (General), Q1-390

Abstract

Metallic alloys with high strength and large ductility are required for extreme structural applications. However, the achievement of ultrahigh strength often results in a substantially decreased ductility. Here, we report a strategy to achieve the strength-ductility synergy by tailoring the alloy composition to control the local stacking fault energy (SFE) of the face-centered-cubic (fcc) matrix in an L12-strengthened superlattice alloy. As a proof of concept, based on the thermodynamic calculations, we developed a non-equiatomic CoCrNi2(Al0.2Nb0.2) alloy using phase separation to create a near-equiatomic low SFE disordered CoCrNi medium-entropy alloy matrix with in situ formed high-content coherent Ni3(Al, Nb)-type ordered nanoprecipitates (∼ 12 nm). The alloy achieves a high tensile strength up to 1.6 GPa and a uniform ductility of 33%. The low SFE of the fcc matrix promotes the formation of nanotwins and parallel microbands during plastic deformation which could remarkably enhance the strain hardening capacity. This work provides a strategy for developing ultrahigh-strength alloys with large uniform ductility.

Published

2024

3. High-Performance Silicon-Rich Microparticle Anodes for Lithium-Ion Batteries Enabled by Internal Stress Mitigation

Author

Yao Gao, Lei Fan, Rui Zhou, Xiaoqiong Du, Zengbao Jiao, and Biao Zhang

Subjects

Silicon anodes, Silicon microparticles, Lithium-ion batteries, Internal stress, Technology

Abstract

Highlights The Sn and Sb incorporation boosts the electronic conductivity and lithium diffusivity of Si anodes, thereby reducing the stress due to lithium concentration gradient. The lithiation of modified electrode mimics isotropic solid solution reaction, rather than the original anisotropic two-phase reaction of Si, effectively weakening the stress concentration. The silicon-rich particles exhibit a capacity of over 1.9 Ah g−1 after 100 cycles at 0.1 A g−1 and maintain the excellent cyclic stability at 3 A g−1.

Published

2023

4. Precipitation behavior of the G-phase strengthened 7Ni maraging steels

Author

Mujin Yang, Daobin Zhang, Zhifu Yao, Zhen Ma, Junhua Luan, Cuiping Wang, Bernd Kuhn, Zengbao Jiao, Yilu Zhao, Tao Yang, Xingjun Liu, and Shuai Wang

Subjects

Alloy design, Ni16X6Si7 G-phase, Precipitation hardening, Maraging steel, Microstructural control, Mining engineering. Metallurgy, TN1-997

Abstract

In this study, G-phase strengthened 7Ni maraging alloys were studied using a combination of thermodynamic prediction based on the TCFE-7 database and advanced experimental techniques, including micro-hardness testing, electron backscatter diffraction (EBSD), in-situ X-ray diffraction (XRD), transmission electron microscopy (TEM), and atom probe tomography (APT). The martensite reversion and phase stability of overcooled austenite were precisely determined for a series of Fe–7Ni–2Si-based alloys, validating the effectiveness of thermodynamic predictions in martensite transformation.Based on these theoretical prediction, aging hardness measurements and microstructural observations further revealed that Ni16X6Si7-G (X = Ti, Nb, Ta) precipitates are effective strengthening phases in 7Ni maraging steel, with the exception of Ni16X6Si7 (X = Mn, Zr) due to their significantly different thermal stabilities. Experimental results showed that the Ni16X6Si7-G (X = Ti, Nb, Ta) precipitates remained stable and densely distributed within the martensitic matrix after aging at 500 °C, resulting in high aging hardness values ranging from 350 to 550 HV. Among the studied alloys, the 1Ti alloy strengthened by the Ni16Ti6Si7-G phase exhibited the finest particle radius (estimated at 1.4 nm) and the highest number density (estimated at 1.9 × 1024/m3). Additionally, it is worth noting that the Ni16Zr6Si7-G phase was believed to form through eutectic reaction with α-Fe during solidification and the Ni16Mn6Si7-G phase was only stable at temperatures below 460 °C and was not detected experimentally.These findings enhance our comprehension of G-phase precipitation and strengthening in 7Ni maraging steel and underscore the potential for utilizing thermodynamic calculations and advanced experimental techniques to guide the design and optimization of high-strength alloys.

Published

2023

5. Performance of a Hierarchically Nanostructured W–Cu Composite Produced via Mediating Phase Separation

Author

Chao Hou, Hao Lu, Zhi Zhao, Xintao Huang, Tielong Han, Junhua Luan, Zengbao Jiao, Xiaoyan Song, and Zuoren Nie

Subjects

Immiscible-component composite, Phase separation, Nanostructure, Mechanical properties, Interface modulation, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The challenge of fabricating nanostructured W–Cu composites by powder metallurgy has been solved by means of modulated phase separation. A hierarchically nanostructured (HN) W–Cu composite was prepared using intermediary Al through sluggish asynchronous phase separation. In addition to a dual network composed of a Cu phase and the W–Cu nanostructure, dense Al-containing nanoprecipitates with a body-centered cubic (bcc) structure are distributed in the W matrix. Compared with a pristine W/Cu interface, the newly formed W/Cu interfaces modulated by Al and the coherent W/Al-containing particle interfaces possess lower energy and enhanced bonding strength due to efficient electron transfer and strong coupling interactions. With a large number of stable heterogeneous interfaces and a “self-locking” geometry, the HN W–Cu composite exhibits excellent resistance against plastic deformation. The combination of the presented composite’s hardness and compressive strength outperforms all other sintered W–Cu composites with the same Cu content. Under a reciprocating sliding load, the reactive Al prevents excessive oxidation. The excellent synergy of the hardness and toughness of the friction-induced surface endows the HN composite with high abrasion resistance. This study provides a new strategy to modulate the structure and energy state of interfaces in metallic composites containing immiscible components in order to achieve high mechanical performance.

Published

2023

6. Ultra-strong tungsten refractory high-entropy alloy via stepwise controllable coherent nanoprecipitations

Author

Tong Li, Tianwei Liu, Shiteng Zhao, Yan Chen, Junhua Luan, Zengbao Jiao, Robert O. Ritchie, and Lanhong Dai

Subjects

Science

Abstract

Abstract High-performance refractory alloys with ultrahigh strength and ductility are in demand for a wide range of critical applications, such as plasma-facing components. However, it remains challenging to increase the strength of these alloys without seriously compromising their tensile ductility. Here, we put forward a strategy to “defeat” this trade-off in tungsten refractory high-entropy alloys by stepwise controllable coherent nanoprecipitations (SCCPs). The coherent interfaces of SCCPs facilitate the dislocation transmission and relieve the stress concentrations that can lead to premature crack initiation. As a consequence, our alloy displays an ultrahigh strength of 2.15 GPa with a tensile ductility of 15% at ambient temperature, with a high yield strength of 1.05 GPa at 800 °C. The SCCPs design concept may afford a means to develop a wide range of ultrahigh-strength metallic materials by providing a pathway for alloy design.

Published

2023

7. Achieving superior low-temperature toughness in high-strength low-carbon steel via controlling lath boundary segregation

Author

Xinghao Wei, Lixin Sun, Zhongwu Zhang, Yang Zhang, Junhua Luan, Zengbao Jiao, Chain Tsuan Liu, and Gang Zhao

Subjects

Low-temperature toughness, Lath boundary segregation, Strengthening mechanism, Cu precipitation strengthening, Mining engineering. Metallurgy, TN1-997

Abstract

The optimal aging temperatures of 400–550 °C for high strength steels falls into the dangerous temperature range of temper-embrittlement. To obtain a good low-temperature toughness, temperatures above 600 °C are usually selected for aging treatments, resulting in a huge loss of strength. In this work, the effects of aging treatments at 500 and 550 °C on the impact performance of a Cu precipitation-strengthened steel at a low temperature of −80 °C were systematically investigated. The solute segregation at lath boundaries is found to be the main factor controlling the low-temperature toughness. Excellent impact performance of ∼180 J at −80 °C along with a high yield strength of ∼1050 MPa and a total elongation of 19% can be obtained by controlling the segregation of solute elements, specifically Mo and Mn at the lath boundaries. The evolutions of matrix and precipitates during aging treatments were investigated. The strengthening and toughening mechanisms are also critically discussed.

Published

2023

8. Achieving ultrahigh strength in oxide-dispersion-strengthened CoCrNi alloy via in situ formation of coherent Y-Ti-O nanoprecipitates

Author

Wenhao Mao, Lu Yang, Feilong Jiang, Jiangping He, Junhua Luan, Zengbao Jiao, and Fuzeng Ren

Subjects

CoCrNi, Medium-entropy alloy, Oxide dispersion strengthening, Coherent nanoprecipitates, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Oxide-dispersion-strengthened CoCrNi alloys were fabricated via in situ oxidation by adding Ti and Y, and non-in-situ oxidation by direct addition of Ti and Y2O3, referring to as Y-ODS and Y2O3-ODS alloys, respectively. Transmission electron microscopy (TEM) and atom probe tomography (APT) characterizations reveal that both alloys consist of an ultrafine-grained face-centered-cubic (fcc) matrix, a high number density of nanoscale Y-Ti-O precipitates and a small number of (Cr0.75Ti0.25)2O3 oxides. However, the nanoscale Y-Ti-O precipitates in the two alloys show distinct phase and microstructure. The Y2O3-ODS alloy contains only incoherent orthorhombic Y2TiO5 nanoprecipitates, but the Y-ODS alloy also contains a high density of fully coherent pyrochlore Y2Ti2O7 nanoprecipitates. The Y-ODS alloy achieves an ultrahigh yield strength of 1660 MPa, which is 320 MPa higher than that of the Y2O3-ODS one, but maintains the same ductility. Quantitative analysis of the strengthening mechanism indicates that such large difference in strength is mainly attributed to the presence of coherent Y2Ti2O7 nanoprecipitates in Y-ODS alloy. This study should provide significant insight into the design of ODS high/medium-entropy alloys via in situ oxidation during mechanical alloying and consolidation.

Published

2023

9. Native Oxidation and Complex Magnetic Anisotropy‐Dominated Soft Magnetic CoCrFeNi‐Based High‐Entropy Alloy Thin Films

Author

Junyi Zhang, Xiao Wang, Xiaona Li, Yuehong Zheng, Renwei Liu, Junhua Luan, Zengbao Jiao, Chuang Dong, and Peter K. Liaw

Subjects

electrical resistivity, high‐entropy thin films, magnetic anisotropic, native oxidation, soft magnetic, Science

Abstract

Abstract Soft magnetic high‐entropy alloy thin films (HEATFs) exhibit remarkable freedom of material‐structure design and physical‐property tailoring, as well as, high cut‐off frequencies and outstanding electrical resistivities, making them potential candidates for high‐frequency magnetic devices. In this study, a CoCrFeNi film with excellent soft magnetic properties is developed by forming a novel core–shell structure via native oxidation, with ferromagnetic elements Fe, Co, and Ni as the core and the Cr oxide as the shell layer. The core–shell structure enables a high saturation magnetization, enhances the electrical resistivity, and thus reduces the eddy‐current loss. For further optimizing the soft magnetic properties, O is deliberately introduced into the HEATFs, and the O‐incorporated HEATFs exhibit an electrical resistivity of 237 µΩ·cm, a saturation magnetization of 535 emu cm−3, and a coercivity of 23 A m−1. The factors that determine the ferromagnetism and coercivity of the CoCrFeNi‐based HEATFs are examined in detail by evaluating the microstructures, magnetic domains, chemical valency, and 3D microscopic compositional distributions of the prepared films. These results are anticipated to provide insights into the magnetic behaviors of soft magnetic HEATFs, as well as aid in the construction of a promising material‐design strategy for these unique materials.

Published

2022

10. Ultrahigh strength and ductility in newly developed materials with coherent nanolamellar architectures

Author

Lei Fan, Tao Yang, Yilu Zhao, Junhua Luan, Gang Zhou, Hao Wang, Zengbao Jiao, and Chain-Tsuan Liu

Subjects

Science

Abstract

Nano-lamellar materials with ultrahigh strengths are highly desirable for technological applications. Here the authors report a nanolamellar architecturing approach by utilizing coherent L12 structures to achieve ultrahigh strength and ductility in Ni-Fe-Co-Cr-Al-Ti multicomponent alloys.

Published

2020

11. Simultaneous enhancement of strength and ductility via microband formation and nanotwinning in an L12-strengthened alloy.

Author

Lu Yang, Dingshan Liang, Zhuo Cheng, Ranxi Duan, Chuanxin Zhong, Junhua Luan, Zengbao Jiao, and Fuzeng Ren

Subjects

ALLOYS, DUCTILITY, STACKING faults (Crystals), TENSILE strength, THERMODYNAMICS

Abstract

Metallic alloys with high strength and large ductility are required for extreme structural applications. However, the achievement of ultrahigh strength often results in a substantially decreased ductility. Here, we report a strategy to achieve the strength-ductility synergy by tailoring the alloy composition to control the local stacking fault energy (SFE) of the face-centered-cubic (fcc) matrix in an L12-strengthened superlattice alloy. As a proof of concept, based on the thermodynamic calculations, we developed a non-equiatomic CoCrNi2 (Al0.2 Nb0.2) alloy using phase separation to create a near-equiatomic low SFE disordered CoCrNi medium-entropy alloy matrix with in situ formed high-content coherent Ni3 (Al, Nb)-type ordered nanoprecipitates (~ 12 nm). The alloy achieves a high tensile strength up to 1.6 GPa and a uniform ductility of 33%. The low SFE of the fcc matrix promotes the formation of nanotwins and parallel microbands during plastic deformation which could remarkably enhance the strain hardening capacity. This work provides a strategy for developing ultrahigh-strength alloys with large uniform ductility. [ABSTRACT FROM AUTHOR]

Published

2024

12. Ultrahigh strength and ductility in newly developed materials with coherent nanolamellar architectures

Author

C.T. Liu, Yilu Zhao, Hao Wang, L. Fan, Zengbao Jiao, Tao Yang, Gang Zhou, and Junhua Luan

Subjects

010302 applied physics, Multidisciplinary, Materials science, Ductile materials, Science, General Physics and Astronomy, Tensile ductility, Mechanical properties, 02 engineering and technology, General Chemistry, Work hardening, Metals and alloys, 021001 nanoscience & nanotechnology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, 0103 physical sciences, Ultimate tensile strength, Lamellar structure, Dislocation, Composite material, 0210 nano-technology, Ductility, Stress concentration

Abstract

Nano-lamellar materials with ultrahigh strengths and unusual physical properties are of technological importance for structural applications. However, these materials generally suffer from low tensile ductility, which severely limits their practical utility. Here we show that markedly enhanced tensile ductility can be achieved in coherent nano-lamellar alloys, which exhibit an unprecedented combination of over 2 GPa yield strength and 16% uniform tensile ductility. The ultrahigh strength originates mainly from the lamellar boundary strengthening, whereas the large ductility correlates to a progressive work-hardening mechanism regulated by the unique nano-lamellar architecture. The coherent lamellar boundaries facilitate the dislocation transmission, which eliminates the stress concentrations at the boundaries. Meanwhile, deformation-induced hierarchical stacking-fault networks and associated high-density Lomer-Cottrell locks enhance the work hardening response, leading to unusually large tensile ductilities. The coherent nano-lamellar strategy can potentially be applied to many other alloys and open new avenues for designing ultrastrong yet ductile materials for technological applications., Nano-lamellar materials with ultrahigh strengths are highly desirable for technological applications. Here the authors report a nanolamellar architecturing approach by utilizing coherent L12 structures to achieve ultrahigh strength and ductility in Ni-Fe-Co-Cr-Al-Ti multicomponent alloys.

Published

2020

13. Precipitation behavior in G-phase strengthened ferritic stainless steels

Author

Xingjun Liu, Ivan Povstugar, Mujin Yang, Junhua Luan, D.J.M. King, Cuiping Wang, Mark R. Wenman, Bernd Kuhn, Zengbao Jiao, and Yuren Wen

Subjects

Materials science, Polymers and Plastics, Alloy, 02 engineering and technology, Atom probe, engineering.material, 01 natural sciences, Indentation hardness, Lattice mismatch, law.invention, chemistry.chemical_compound, law, ddc:670, Ferrite (iron), 0103 physical sciences, Silicide, Chemical composition, 010302 applied physics, Precipitation (chemistry), Metallurgy, Metals and Alloys, 021001 nanoscience & nanotechnology, Electronic, Optical and Magnetic Materials, chemistry, Ceramics and Composites, engineering, 0210 nano-technology

Abstract

A series of G-phase strengthened ferritic stainless steels Fe-20Cr-3Ni-3Si-X (X = 2Mn, 1Mn-2Ti, 1Mn-2Nb and 1Mn-2Ta) are characterized after aging using experimental (microhardness, TEM and APT) and theoretical (DFT) techniques. The results indicate that the Ni16Mn6Si7 G-phase shows sluggish precipitation during aging treatment. This was attributed to the small difference in the enthalpy of formation between the Ni16Mn6Si7 G- and BCC phase and the requirement of high Ni:Fe ratio. A superfine Ni16Ti6Si7 G-phase was found to precipitate as a core accompanied with an “envelope” of Fe2TiSi-L21 Heusler phase during early aging (≤24 h) in the Ti containing alloy. This morphology is predicted to occur due to early Ni clustering in ferrite and a negative Ni concentration gradient away from the cluster that favors Fe2TiSi formation. The G-phases show only particle coarsening without obvious chemical composition evolution for further aging up to 96 h. A prominent hardness increase of 100-275 HV was also observed during aging. These findings provide valuable insight into methods for precipitating low lattice mismatch silicide phases for the development of future high strength steels.

Published

2021

14. Atom-probe study of Cu and NiAl nanoscale precipitation and interfacial segregation in a nanoparticle-strengthened steel

Author

C.T. Liu, Junhua Luan, Wei Guo, Zengbao Jiao, and Jonathan D. Poplawsky

Subjects

Nial, Materials science, Nanoparticle, 02 engineering and technology, Atom probe, 01 natural sciences, law.invention, Cu and NiAl precipitate, law, Phase (matter), 0103 physical sciences, lcsh:TA401-492, General Materials Science, interfacial segregation, computer.programming_language, 010302 applied physics, Austenite, Precipitation (chemistry), atom-probe tomography, Metallurgy, 021001 nanoscience & nanotechnology, Surface energy, nanoscale precipitation, Chemical engineering, high-strength steel, Martensite, lcsh:Materials of engineering and construction. Mechanics of materials, 0210 nano-technology, computer

Abstract

The Cu and NiAl nanoscale precipitation and interfacial segregation in the martensite and austenite phases within a high-strength steel were studied by atom-probe tomography (APT). In the martensite phase, APT reveals the precipitation of isolated NiAl nanoparticles and NiAl/Cu co-precipitates, indicating that NiAl nanoparticles form first in the precipitation sequence. In comparison, the austenite phase contains only Cu nanoparticles with Ni segregation at the particle/matrix interface, in which the Ni segregation reduces the Cu nanoparticle interfacial energy. In addition, Mn and C exhibit an enrichment at the martensite/austenite interface, and the mechanism for the interfacial segregation was also discussed.

Published

2017

15. Advanced Multicomponent Alloys : From Fundamentals to Applications

Author

Zengbao Jiao, Tao Yang, Zengbao Jiao, and Tao Yang

Subjects

Metals, Composite materials, Building materials

Abstract

This book integrates aspects of computational materials science, physical metallurgy, alloy design, structure-properties relationships, and applications of advanced multicomponent alloys. It can serve as a textbook for courses on advanced structural and functional materials for undergraduate and graduate students. Notably, the book compiles cutting-edge research on the progress of materials science of multicomponent alloys from fundamentals to engineering applications. It can be of considerable interest for researchers and scientists in the field of materials science and engineering, mechanical engineering, and metallurgy engineering. In addition, this book not only summarizes the compositions, properties, and applications of various types of multicomponent alloys but also presents a complete idea on the efficient design of materials and processes to satisfy targeted performance in materials and structures. Thus, it can also be used as a reference book for engineers and researchersin industries.

Published

2022

16. Group precipitation and age hardening of nanostructured Fe-based alloys with ultra-high strengths

Author

Zengbao Jiao, C.Y. Yu, Junhua Luan, C.T. Liu, and Michael K Miller

Subjects

010302 applied physics, Multidisciplinary, Materials science, Structural material, Nanostructure, Kinetics, Nucleation, Nanoparticle, 02 engineering and technology, Atom probe, 021001 nanoscience & nanotechnology, 01 natural sciences, Article, law.invention, Precipitation hardening, law, Chemical physics, 0103 physical sciences, Hardening (metallurgy), 0210 nano-technology

Abstract

The precipitation of nanoparticles plays a key role in determining the properties of many structural materials and the understanding of their formation and stabilization mechanisms has been a long standing interest in the material field. However, the critical issues involving the group precipitation of various nanoparticles and their cooperative hardening mechanism remain elusive in the newly discovered Fe-based alloys with nanostructures. Here we quantitatively elucidate the nucleation mechanism, evolution kinetics and hardening effects of the group-precipitated nanoparticles in the Fe-Cu-Ni-Al-based alloys by atom probe tomography together with both first-principles and thermodynamic calculations. Our results provide the compelling evidence for two interesting but complex group precipitation pathways of nanoparticles, i.e., the Cu-rich and NiAl-based precipitations. The co-existence of the two precipitation pathways plays a key role in age hardening kinetics and ultimately enhances the hardening response, as compared to the single particle type of strengthening, therefore providing an effective new approach for strengthening materials for structural applications.

Published

2016

17. Enhancing glass-forming ability via frustration of nano-clustering in alloys with a high solvent content

Author

Jintao Gao, Michael K Miller, Dong Ma, Xun-Li Wang, Hui Li, Alexandru D. Stoica, Yuan Wu, Yang Ren, Zengbao Jiao, and Z.P. Lu

Subjects

Multidisciplinary, Materials science, media_common.quotation_subject, Doping, Nucleation, Frustration, Enthalpy of mixing, Article, law.invention, Chemical engineering, law, Phase (matter), Nano, Crystallization, Solid solution, media_common

Abstract

The glass-forming ability (GFA) of alloys with a high-solvent content such as soft magnetic Fe-based and Al-based alloys is usually limited due to strong formation of the solvent-based solid solution phase. Herein, we report that the GFA of soft magnetic Fe-based alloys (with >70 at.% Fe to ensure large saturation magnetization) could be dramatically improved by doping with only 0.3 at.% Cu which has a positive enthalpy of mixing with Fe. It was found that an appropriate Cu addition could enhance the liquid phase stability and crystallization resistance by destabilizing the α-Fe nano-clusters due to the necessity to redistribute the Cu atoms. However, excessive Cu doping would stimulate nucleation of the α-Fe nano-clusters due to the repulsive nature between the Fe and Cu atoms, thus deteriorating the GFA. Our findings provide new insights into understanding of glass formation in general.

Published

2013