International Journal of Materials Research Volume 111 Issue 9

International Journal of Materials Research

Volume 111 Issue 9

Contents
Journal Overview

September 7, 2020 Page range: 709-709

Cite

Editorial

Welcome to Prof. Joachim Bill as a new editor for IJMR

September 7, 2020 Page range: 710-710

Cite

Original Contributions

Fabrication of highly porous merwinite scaffold using the space holder method

Maryam Abdollahi asl, Hamed Ghomi September 7, 2020 Page range: 711-718

More Cite

Abstract

In this study, for the first time, the space holder method was used to fabricate a 3D macroporous nanostructured merwinite scaffold with highly interconnected spherical pores. The nanostructured merwinite powders were prepared by the sol-gel method and an optimal calcination cycle was ascertained. The average values of true and apparent porosities of the prepared scaffolds calculated in the range 85–81% and 80–74%, respectively, while the macropore sizes are determined in the range of 400–600 μm. The compressive strength of the prepared scaffold was obtained to be about 0.18–0.29 MPa. Immersion testing in simulated body fluid proved the appropriate bioactivity and biodegradability of the prepared scaffolds. Our study indicated the merwinite scaffold possessed suitable mechanical strength along with highly porous structure and apatite-formation ability which could be used for bone tissue engineering applications.

Improvement of AISI 4340 steel properties by intermediate quenching – microstructure, mechanical properties, and fractography

Afshin Mehrabi, Hassan Sharifi, Mohsen Asadi Asadabad, Reza Amini Najafabadi, Ali Rajaee September 7, 2020 Page range: 711-779

More Cite

Abstract

AISI 4340 is one of the most widely used steels in high-risk industries such as military, nuclear and aerospace. The strength of this steel is capable of increasing to 1 825 MPa with quench and temper heat treatment, but it results in low toughness, low impact properties and brittle-fracture especially at low temperatures. In this study, the intermediate quenching treatment was used to induce ferritic–martensitic dual-phase (∼50/50 ferrite/martensite) microstructure that led to an impact energy of 93.6 kJ m −2 , which was 241% higher than that of quench and temper treatment. Moreover, mechanical tests revealed tensile strength and hardness of 911.5 MPa and 43 HRC, respectively. Also, fractographic analysis confirmed the occurrence of the desirable ductile fracture mechanism.

Experimental measurement and thermodynamic model predictions of the distributions of Cu, As, Sb and Sn between liquid lead and PbO–FeO–Fe2O3–SiO2 slag

Denis Shishin, Taufiq Hidayat, Ummul Sultana, Maksym Shevchenko, Evgueni Jak September 7, 2020 Page range: 733-743

More Cite

Abstract

Due to the increasing complexity of materials processed in primary and secondary lead smelting, better control of impurity elements is required. In the present study, distributions of Cu, As, Sb and Sn between PbO–FeO–Fe 2 O 3 –SiO 2 slag and Pb metal are characterized experimentally and analyzed using thermodynamic calculations. Experimental methodology involved closed-system equilibration of sample mixtures at high temperature followed by rapid quenching. The compositions of phases were measured using electron probe X-ray microanalysis and laser ablation inductively coupled plasma mass spectrometry. Thermodynamic calculations were performed using the FactSage software coupled with an internal thermodynamic database. Experimentally obtained distribution coefficients wt.% in slag/wt.% in metal at 1 200 °C (1 473 K) follow the sequence Sn >> Cu > As ≈ Sb at P (O 2 ) < 10 −9.5 atm and Sn >> As ≈ Sb > Cu at P (O 2 ) > 10 −8.5 atm. Model predictions are in good agreement with the experiment.

Effect of Co substitution on the magnetic properties and magnetocaloric effects of Ni–Co–Mn–Sn alloys

Zhigang Zheng, Lei Lei, Weiqi Zeng, Zhaoguo Qiu, Yuan Hong, Dechang Zeng September 7, 2020 Page range: 744-752

More Cite

Abstract

Ni–Mn–Sn-based magnetic refrigeration materials have a coupling ability of structure transformation and magnetic transition to improve their magnetocaloric effects. In this work, the influence of the Co doping on Curie temperature, structure and magnetocaloric properties of Ni 43- x Co x Mn 46 Sn 11 ( x = 0, 1, 2, 3) alloys prepared by melt-spinning were investigated by means of X-ray diffraction, Differential Scanning Calorimetry and Vibrating Sample Magnetometry. It was found that the crystal structure of samples changes from 4O modulated martensite to L2 1 cubic austenite with increasing temperature. The magnetic phase diagram of Ni 43- x Co x Mn 46 Sn 11 system was constructed from thermomagnetic curves. Increasing Co content enhanced the Curie temperature of L2 1 cubic austenite from 279 K to 354 K, however, shifted the transition temperature of martensitic down to lower temperature, 170 K. As for the sample with x = 3, it only has ferromagnetic–paramagnetic second order magnetic transition, and no structural transformation was observed. The sensitivity of martensitic transformation induced by magnetic field can be improved up to − 3.52 K · T −1 . Under 0–5 T, the maximum values of magnetic entropy change, refrigerant capacity and the adiabatic temperature change are improved by 60.5%, 59.0% and 17.5%, respectively. The results indicate that the relatively large martensitic transformation sensitivity and magnetocaloric effects make these alloys good candidates in the range of 150–300 K.

Effect of the synthesis parameters on the structural and magnetic properties of strontium hexaferrite synthesized via the Pechini method

Alfonso Enrique Ramírez Sanabria, Norleth Jairo Solarte Ordoñez, Valeria Nastar Córdova, José Antonio Huamani Coaquira, Sonia Gaona Jurado September 7, 2020 Page range: 753-760

More Cite

Abstract

Strontium hexaferrite (SrFe 12 O 19 –SF6) is a magnetic material of great interest in various research fields due to its high coercive field ( H c ) and its high saturation magnetization. In this research, the effect of synthesis parameters on the structure and magnetic response was studied. It was evidenced that the parameters such as pH value and iron precursor type have a strong influence on the crystalline structure of the samples, since the pure phase of strontium hexaferrite was obtained by two different pathways (ferrous and ferric) and only at pH = 5. It was determined that there are differences in the magnetic response of both samples; the ferrous pathway generates the largest values of both saturation magnetization (74.3 emu g −1 ) and coercive field (5.2 kOe).

Investigation on microstructural and mechanical properties of sub-zero processed AISI 440C steel

Vignesh Kumar, Rama Thirumurugan, Shanmugam September 7, 2020 Page range: 761-770

More Cite

Abstract

Sub-zero processing is an effective method to enhance the mechanical properties of steel due to the complete removal of residual austenite, and better precipitation of secondary carbides. Especially, the sub-zero processing temperature significantly influences the mechanical properties of steel. In the present study, the impacts of shallow and deep sub-zero processing on the microstructure, hardness, wear characteristics, and toughness of 440C martensitic steel were evaluated. An attempt has been made to correlate the influences of microstructural changes on these measured properties. It was found that although shallow sub-zero processing was capable of reducing the amount of residual austenite, deep sub-zero processing was required for its complete removal. Due to the low-temperature martensite formation at −196 °C, deep sub-zero processed specimens possessed a twinned martensite microstructure that significantly improved their strength. Furthermore, deep sub-zero processing increased the volume of micro-carbides by driving alloying carbides to the nearby defects. Hence, deep sub-zero processing led to a 15% improvement in hardness and up to a 60% improvement in wear resistance with an 11% drop in toughness. In contrast, shallow sub-zero processing improved the hardness and wear resistance by 7% and 23%, respectively, with a 30% drop in toughness.

Effects of rail flash-butt welding and post-weld heat treatment processes meeting different national standards on residual stresses of welded joints

Rui Ma, Dan Huang, Jiao Zhang, Yang Zhang, Qibing Lv September 7, 2020 Page range: 780-787

More Cite

Abstract

This study investigates residual stresses of the welded joint heat-affected zone for the processes that meet the Chinese and European standards of field rail welding. Furthermore, this study investigates the factory rail welding process and different normalizing methods in China. According to the residual stresses data and the Debye ring test result, the residual stresses distribution of the welded joint meets the Chinese standard and uses induction normalizing treatment resulting in the best service performance and an improvement in grain size uniformity. In the absence of a normalizing process, the ideal welding process that meets the Chinese standard is actually inferior to that which meets the European standard, with regard to a uniform distribution of the residual stresses of the welded joint.

DGM News

September 7, 2020 Page range: 788-790

Cite

About this journal

The International Journal of Materials Research (IJMR) publishes original high quality experimental and theoretical papers and reviews on basic and applied research in the field of materials science and engineering, with focus on synthesis, processing, constitution, and properties of all classes of materials. Particular emphasis is placed on microstructural design, phase relations, computational thermodynamics, and kinetics at the nano to macro scale. Contributions may also focus on progress in advanced characterization techniques.
All articles are subject to thorough, independent peer review.