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"George Lai?s 1990 book, High-Temperature Corrosion of Engineering Alloys, is recognized as authoritative and is frequently consulted and often cited by those in the industry. His new book, almost double in size with seven more chapters, addresses the new concerns, new technologies, and new materials available for those engaged in high-temperature applications. As we strive for energy efficiency, the realm of high-temperature environments is expanding and the need for information on high temperature materials applications was never greater.In addition to extensive expansion on most of the content of the original book, new topics include erosion and erosion-corrosion, low NOx combustion in coal-fired boilers, fluidized bed combustion, and the special demands of waste-to-energy boilers, waste incinerators, and black liquor recovery boilers in the pulp and paper industry. The corrosion induced by liquid metals is discussed and protection options are presented. Hydrogen damage is characterized and solutions given."

"Low carbon steel (AISI 1005) was coated by hot-dipping into a molten Al-10% Si bath at 700 °C for 18s. After hot-dipping treatment, the coating layers consisted of Al, Si, FeAl3,τ5-Fe2Al8Si, and Fe2Al5. The bare steel and the aluminized steel were isothermally oxidized at 700 °C in ethanol combustion product at atmospheric pressure for 49 h.The aluminized steel shows good performance in high temperatureoxidation because the formation of Al2O3layer on the coating surface. The growth of iron oxide nodules on the surface coating was accelerated by rapid outward diffusion of Fe-ions due to the presence of H2O-vapour generated by ethanol combustion. Thus, the oxidation rate of aluminized steel increased, resulting in a substantial mass-gain as the oxidation time increased. After longer exposure, the τ1-(Al,Si)5Fe3 phase was completely transformed to the FeAl in the outer layer. The FeAl formed near the steel substrate was due to Fe-atoms diffusing into the Fe2Al5 layer when the time and temperature increased."

"From concept to application, this book describes the method of strain-range partitioning for analyzing time-dependent fatigue. Creep (time-dependent) deformation is first introduced for monotonic and cyclic loading. Multiple chapters then discuss strain-range partitioning in details for multi-axial loading conditions and how different loading permutations can lead to different micro-mechanistic effects. Notably, the total-strain method of strain-range partitioning (SRP) is described, which is a methodology that sees use in several industries. Examples from aerospace illustrate applications, and methods for predicting time-dependent metal fatigue are critiqued."

"In this study, modeling of the crossing point temperature (CPT) phenomenon in the low-temperature oxidation of coal was carried out using COMSOL Multiphysics®. Low-temperature oxidation can lead to spontaneous combustion of coal stockpiles. The CPT phenomenon was modeled with the kinetics data obtained from a prior laboratory experimental study. The coupling of the heat-transfer phenomenon through conduction and convection determined the thermal evolution model. In this case, coal received the initial heat of the oven temperature increases. As the coal temperature rose, the heat generated from oxidation was released into the environment via conduction and convection. Meanwhile, oxidation products and oxygen were transferred by convection and diffusion. The effects of moisture and the humidity were not considered. The outcomes of modeling were validated through comparison with the results of experimental tests, and the modeling result agreed well with the experiment tests, with temperature deviations of about 0.9%. The effects of airflow rate, oxygen concentration, porosity, and the initial temperature on low-temperature coal oxidation were also examined."

"In this study, modeling of the crossing point temperature (CPT) phenomenon in the low-temperature oxidation of coal was carried out using COMSOL Multiphysics®. Low-temperature oxidation can lead to spontaneous combustion of coal stockpiles. The CPT phenomenon was modeled with the kinetics data obtained from a prior laboratory experimental study. The coupling of the heat-transfer phenomenon through conduction and convection determined the thermal evolution model. In this case, coal received the initial heat of the oven temperature increases. As the coal temperature rose, the heat generated from oxidation was released into the environment via conduction and convection. Meanwhile, oxidation products and oxygen were transferred by convection and diffusion. The effects of moisture and the humidity were not considered. The outcomes of modeling were validated through comparison with the results of experimental tests, and the modeling result agreed well with the experiment tests, with temperature deviations of about 0.9%. The effects of airflow rate, oxygen concentration, porosity, and the initial temperature on low-temperature coal oxidation were also examined."

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Plasma electrolytic oxidation (PEO) merupakan metode konversi permukaan logam menjadi lapisan oksida dengan bantuan plasma yang bertujuan untuk meningkatkan sifat mekanik permukaan dan ketahanan korosi logam. Retakan dan pori menurunkan ketahanan korosi dan sifat mekanik lapisan. Dalam penelitian ini digunakan zat aditif SiO₂ dan metode post-alkali treatment pada lapisan PEO yang ditumbuhkan pada paduan magnesium AZ31 dan commercially pure titanium (CP-Ti). PEO dilakukan di dalam larutan 95 g/l Na₃PO₄ + 2 g/l KOH menggunakan rapat arus DC  sebesar 300 A.m^-2 selama 10 menit. NP-SiO₂ sebanyak 2 g/l ditambahkan di dalam larutan PEO. Setelah logam terlapisi, post-alkali treatment dilakukan di dalam larutan 0,5 M NaOH pada suhu 80 ºC selama 30 menit. Morfologi permukaan dan kandungan unsur lapisan dianalisis menggunakan SEM-EDS dan XPS. Komposisi fasa kristal diteliti menggunakan X-ray Difraction (XRD). Sifat mekanik lapisan PEO diuji dengan metode vickers microhardness dan ketahanan aus dievaluasi menggunakan metode Ogoshi. Sifat korosi dianalisis dengan uji polarisasi, EIS, dan uji rendam. Sifat bioaktivitas diteliti dengan cara perendaman sampel dalam larutan SBF. Hasil penelitian menunjukkan penambahan aditif SiO₂ dan post-alkali treatment dapat meningkatkan ketahanan korosi dan sifat mekanik lapisan PEO pada logam Mg dan Ti. Pada PEO-Mg, lapisan PEO/SiO₂+AT memiliki nilai rapat arus korosi paling rendah dan nilai kekerasan paling tinggi dibandingkan dengan sampel lainnya yaitu berturut-turut 7,34x10^-7 A.cm^-2 dan 359 HV. Tren yang sama juga dihasilkan pada PEO-Ti, lapisan PEO/SiO₂+AT memiliki nilai rapat arus korosi relatif rendah dan nilai kekerasan paling tinggi dibandingkan dengan sampel lainnya yaitu berturut-turut 3,4x10^-9 A.cm^-2 dan 305 HV.

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Plasma electrolytic oxidation (PEO) is a method of converting metal surfaces into an oxide layer with the help of plasma which aims to improve the surface mechanical properties and corrosion resistance of metals. Cracks and pores reduce the corrosion resistance and mechanical properties of the coating. In this research, SiO₂ additives and post-alkali treatment methods were used on PEO layers grown on AZ31 magnesium alloy and commercially pure titanium (CP-Ti). PEO was carried out in a solution of 95 g/l Na₃PO₄ + 2 g/l KOH using a DC current density of 300 A.m^-2 for 10 minutes. SiO₂ additive with a concentration of 2 g/l was added to the PEO solution. After the metal is coated, post-alkali treatment is carried out in a 0.5 M NaOH solution at a temperature of 80 ºC for 30 minutes. The surface morphology and element content of the layers were analyzed using SEM-EDS and XPS. The composition of the crystal phase was investigated using XRD. The mechanical properties of the PEO coating were tested using the vickers microhardness and the wear resistance was evaluated using the Ogoshi method. Corrosion properties were analyzed by polarization test, EIS, and immersion test. The bioactivity properties were studied by immersing the samples in SBF. The research results show that the addition of SiO₂ and post-alkali treatment can improve the corrosion resistance and mechanical properties of PEO layers on Mg and Ti metals. In PEO-Mg, the PEO/SiO²+AT layer has the lowest corrosion current density value and the highest hardness value compared to other samples, namely 7.34x10^-7 A.cm^-2 and 359 HV respectively. The same trend was also produced on PEO-Ti, the PEO/SiO²+AT layer had a relatively low corrosion current density value and the highest hardness value compared to other samples, namely 3.4x10^-9 A.cm^-2 and 305 HV respectively.

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