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Öğe Aisi 4340 düşük alaşımlı çeliğe uygulanan plazma nitrürleme sıcaklık ve sürelerinin (mekanik özellikleri etkilemeden) düşürülmesi: bilyalı dövmenin faydalı(2016) Unal, OkanBu projede son yıllarda aşırı plastik deformasyon yöntemi olarakta uygulanmaya başlanan bilyalı dövme işleminin AISI 4340 düşük alaşımlı çelik malzeme üzerinde plazma nitrürleme ile azot difüzyonuna olan etkisi ve mekanik özellikler değişimi incelenmesi amaçlanmıştır. Aşırı bilyalı dövme ile yüzey ve hemen altında dislokasyon yoğunluklu incelmiş tanelerin varlığı optik mikroskop, taramalı elektron mikroskobu ve X-ışını kırınım deseni çalışmaları ile karakterize edilmiştir. AISI 4340 düşük alaşımlı çelik yüzeyinde ultra ince taneli tabaka ile deforme olmuş ve yönlenmiş tanelerin bulunduğu tabaka olmak üzere iki farklı tabaka oluşmuştur. Malzemeler aşırı bilyalı dövme sonrası belirli sıcaklık ve sürelerde plazma nitrürleme işlemine tabi tutulmuşlardır. Mikroyapı analizlerinde ön işlem olarak uygulanan aşırı bilyalı dövme işleminin metalik malzemelerin yüzeyinde oluşan bileşik tabaka kalınlıklarını arttırdığı gözlemlenmiştir. Mikroyapı ve X-ışını kırınım deseni analizlerinde nitrürleme için yeterli olmayan ve yüzeyde nitrür bileşikleri ve tabakasının oluşmadığı koşullarda bile ön işlem olarak aşırı bilyalı dövmenin uygulanması aynı sıcaklık ve süre koşullarında nitrür bileşiklerinin ve bileşik tabakanın oluşumunu gerçekleştirmiştir Metalik malzemelerin belirtilen iki yüzey işlemi uygulaması sonrası dönel eğmeli yorulma testleri gerçekleştirilmiş ve S-N eğrileri çizilmiştir. Plazma nitrürleme öncesi aşırı bilyalı dövme işleminin uygulanması AISI 4340 malzemelerin yorulma ömrünü arttırmıştır.Öğe Analysing the Fatigue Behaviour and Residual Stress Relaxation of Gradient Nano-Structured 316L Steel Subjected to the Shot Peening via Deep Learning Approach(Korean Inst Metals Materials, 2022) Maleki, Erfan; Unal, Okan; Guagliano, Mario; Bagherifard, SaraIn this study, the effect of kinetic energy of the shot peening process on microstructure, mechanical properties, residual stress, fatigue behavior and residual stress relaxation under fatigue loading of AISI 316L stainless steel were investigated to figure out the mechanisms of fatigue crack initiation and failure. Varieties of experiments were applied to obtain the results including microstructural observations, measurements of hardness, roughness, induced residual stress and residual stress relaxation as well as axial fatigue test. Then deep learning approach through neural networks was used for modelling of mechanical properties and fatigue behavior of shot peened material. Comprehensive parametric analyses were performed to survey the effects of different key parameters. Afterward, according to the results of neural network analysis, further experiments were performed to optimize and experimentally validate the desirable parameters. Based on the obtained results the favorable range of shot peening coverage regarding improved mechanical properties and fatigue behavior was identified as no more than 1750% considering Almen intensity of 21 A (0.001 inch). Graphic abstractÖğe Application of Deep Neural Network to Predict the High-Cycle Fatigue Life of AISI 1045 Steel Coated by Industrial Coatings(Mdpi, 2022) Maleki, Erfan; Unal, Okan; Seyedi Sahebari, Seyed Mahmoud; Reza Kashyzadeh, Kazem; Danilov, IgorIn this study, deep learning approach was utilized for fatigue behavior prediction, analysis, and optimization of the coated AISI 1045 mild carbon steel with galvanization, hardened chromium, and nickel materials with different thicknesses of 13 and 19 mu m were used for coatings and afterward fatigue behavior of related specimens were achieved via rotating bending fatigue test. Experimental results revealed fatigue life improvement up to 60% after applying galvanization coat on untreated material. Obtained experimental data were used for developing a Deep Neural Network (DNN) modelling and accuracy of more than 99%.was achieved. Predicted results have a fine agreement with experiments. In addition, parametric analysis was carried out for optimization which indicated that coating thickness of 10-15 mu m had the highest effects on fatigue life improvement.Öğe Assessing the efficacy of several impact-based mechanical techniques on fatigue behavior of additive manufactured AlSi10Mg(Elsevier Science Sa, 2023) Maleki, Erfan; Bagherifard, Sara; Unal, Okan; Shao, Shuai; Shamsaei, Nima; Guagliano, MarioPost-processing methods to reduce issues associated with the presence of internal and external anomalies are often necessary for obtaining adequate structural performance for additively manufactured products. However, the choice of the proper post-treatment and the corresponding parameters is still a challenge requiring adaption to the material type, geometry, size and undeniably costs. In this study, four different pure impact-based mechanical operations involving ultrasonic nanocrystal surface modification (UNSM), ultrasonic shot peening (USSP), severe shot peening (SSP), and severe vibratory peening (SVP) to investigate their efficacy on the fatigue behavior of hourglass AlSi10Mg specimens manufactured via laser powder bed fusion (LPBF) were considered. Experimental characterizations involving microstructural approach, porosity level and surface texture, hardness and residual stresses measurements, as well as tensile and fatigue testing, were conducted. The results exhibited considerable improvement in mechanical/physical performances leading to substantially enhanced fatigue performance of the mechanically treated specimens. Based on a cost-performance analysis, it was found that UNSM, while having reasonable cost, presented considerable improvement on fatigue behavior.Öğe Comprehensive analysis of pulsed plasma nitriding preconditions on the fatigue behavior of AISI 304 austenitic stainless steel(Springer, 2021) Unal, Okan; Maleki, Erfan; Varol, RemziThis study aims to draw an exact boundary for microstructural and mechanical behaviors in terms of pulsed plasma nitriding conditions. The pulsed plasma nitriding treatment was applied to AISI 304 austenitic stainless steel at different temperatures and durations. Results reveal that nitriding depth increased as process temperature and duration increase. The nitriding depth remarkably increased at 475 degrees C for 8 h and at 550 degrees C for 4 h. An austenite structure was transformed into a metastable nitrogen-oversaturated body-centered tetragonal expanded austenite (S-phase) during low-temperature plasma nitriding. The S-phase was converted to CrN precipitation at 475 degrees C for 8 h and at 550 degrees C for 4 h. Surface hardness and fatigue limit increased through plasma nitriding regardless of process conditions. The best surface hardness and fatigue limit were obtained at 550 degrees C for 4 h because of the occurrence of CrN precipitation.Öğe A Critical Review on Improving the Fatigue Life and Corrosion Properties of Magnesium Alloys via the Technique of Adding Different Elements(Mdpi, 2023) Kashyzadeh, Kazem Reza; Amiri, Nima; Maleki, Erfan; Unal, OkanMagnesium is the eighth-most abundant element in the world and its alloys have a widespread application in various industries such as electronic and transport (i.e., air, land, and sea) engineering, due to their significant mechanical properties, excellent machinability, high strength to weight ratios, and low cost. Although monolithic Mg metal is known as the lightest industrial metal (magnesium density is 30% less than the density of the aluminum, and this unique property increases the attractiveness of its usage in the transportation industry), one of the significant limitations of magnesium, which affects on its applications in various industries, is very high reactivity of this metal (magnesium with an electronegativity of 31.1 can give electrons to almost all metals and corrodes quickly). To overcome this problem, scholars are trying to produce magnesium (Mg) alloys that are more resistant to a variety of loads and environmental conditions. In this regard, Mg alloys include well-known materials such as aluminum (Al), Zinc (Zn), Manganese (Mn), Silicon (Si), and Copper (Cu), etc., and their amount directly affects the properties of final products. In the present review paper, the authors attempted to present the latest achievements, methods, and influential factors (finish-rolling, pore defects, pH value, microstructure, and manufacturing processes, etc.) on the fatigue life and corrosion resistance of most significant Mg alloys, including AM50, AM60, AZ31, AZ61, AZ80, AZ91, ZK60, and WE43, under various conditions. The summarized results and practical hints presented in this paper can be very useful to enhance the reliability and quality of Mg-made structures.Öğe Effect of combined shot peening and ultrasonic nanocrystal surface modification processes on the fatigue performance of AISI 304(Elsevier Science Sa, 2019) Amanov, Auezhan; Karimbaev, Ruslan; Maleki, Erfan; Unal, Okan; Pyun, Young-Sik; Amanov, TileubayIn this study, the fatigue performance of AISI 304 subjected to shot peening (SP), ultrasonic nanocrystal surface modification (UNSM) and the combination of SP + UNSM processes was systematically assessed by rotary bending fatigue (RBF) tester at different stress levels. The purpose of combining SP and UNSM processes is to find out whether SP following UNSM process can further improve the fatigue life of AISI 304 in comparison with the SP and UNSM processes alone. Interestingly, the fatigue strength of AISI 304 was deteriorated by the combination of SP + UNSM processes in comparison with the UNSM process alone, but the combination of SP + UNSM processes demonstrated a higher fatigue strength in comparison with the SP process alone.Öğe Effect of pre-heat treatment on fatigue behavior of severe shot peened and plasma nitrided aisi 4140 steel(2018) Unal, OkanBu çalışmada, mekanik ve termal yüzey işlemi uygulanmış AISI 4140 düşük alaşımlı çeliğin yorulma davranışı üzerinde ön ısıl işlem uygulamalarının (tavlama, normalizasyon, yağda su verme, temperleme) etkisinin belirlenmesi amaçlanmaktadır. Plastik olarak deforme olmuş, aşırı derecede inceltilmiş ve yönlendirilmiş taneli tabaka aşırı bilyalı dövme yoluyla elde edilmiş ve darbeli plazma nitrürleme ile yüzey jiziksle ve mekanik özellikleri iyileştirilmiştir. Numuneler, optik, taramalı elektron mikroskopisi, X-ışını kırınımı ve yarı yükseklik pik genişliği (YYPG) analizi ile karakterize edilmiş olup, yüzey topoğrajfvası farklı ön-ısıl işlemler altındaki numunelerin yorulma davranışlarını belirlemeden önce yüzey pürüzlülüğü ölçümleri ile incelenmeye çalışılmıştır. Sonucçlar, bilyalı dövme ve plazma nitrürleme kombinasyonun tüm numunelerde yorulma dayanımın iyileştirdiği hatta tavlanmış ve normalizasyon ısıl işlemi görmüş numunelerin yorulma limitlerini sadece temperlenmiş numunelerle kıyaslanabilir seviyelere iyileştirmiştir.Öğe Effect of severe shot peening and ultra-low temperature plasma nitriding on Ti-6Al-4V alloy(Pergamon-Elsevier Science Ltd, 2018) Unal, Okan; Maleki, Erfan; Varol, RemziIn this study, the fatigue behavior of Ti-6Al-4V alloy is tend to be improved by severe plastic deformation via shot peening and plasma nitriding. Shot peening with sub-branches: Conventional shot peening (A12-14), severe shot peening (A28-30 and A34-36) and repeening (N6-8) are exposed. Besides plasma nitriding is implemented at 500 degrees C, 550 degrees C and 600 degrees C with the durations of 4, 8 and 16 h. Due to utilization of shot peening as prior severe plastic deformation during diffusion of nitrogen, two methods are applied in sequence. Severe shot peening forms ultra-fine crystals and oriented grains by disintegrating of a and 13 phases just below the surface and increases surface roughness. Plasma nitriding temperature increase the compound layer thickness and the treatment leads to vanish of 13 particles through a certain line for diffusion layer. Prior severe plastic deformation by severe shot peening generally triggers the formation of thicker compound layer and emerges distinct diffusion depth with finer and oriented precipitation. The phase's intensity obtained from XRD peaks has been amplified by the application of prior shot peening. Each shot peening provides fatigue improvement on the other hand plasma nitriding application regardless of being pre or post treatments diminish the fatigue resistance. (C) 2018 Elsevier Ltd. All rights reserved.Öğe Effect of severe vibratory peening on microstructural and tribological properties of hot rolled AISI 1020 mild steel(Elsevier Science Sa, 2020) Das, Turan; Erdogan, Azmi; Kursuncu, Bilal; Maleki, Erfan; Unal, OkanIn this study, microstructural and mechanical performance of AISI 1020 were investigated after severe vibratory peening (SVP) for emerging the potential and performance of this novel treatment among surface severe plastic deformation (SSPD) methods. The specimens were subjected to SVP treatment of V1, V2, and V3 conditions at 20, 40 and 60 min. durations, respectively. Optical microscope (OM) and SEM images demonstrated two layered gradient structure. XRD analysis showed the oxide layer was completely vanished besides surface nanocrystallization by severe plastic deformation (SPD). The microhardness test revealed an average improvement of 48% compared to the untreated specimen. SVP caused raising of hardness from surface to a depth of approximately 900 mu m. In wear tests, the volume loss after SVP were less. The hardness improvement due to deformation overcame the negative effect caused by roughness increase. However, the friction coefficient of the unpeened specimen was the lowest at all loads.Öğe Effect of Shot-Peening Process and Nanoparticle-Added Lubricant on the Tribological Performance of Aluminium-Based Sliding Bearing Material(Wiley, 2024) Korkmaz, Seyma; Cetin, M. Huseyin; Simsir, Hamza; Unal, Okan; Temel, FarabiIn this study, it is aimed to increase the wear and fatigue performance of aluminium-based sliding bearing material by using silver nanoparticles (AgNPs) added lubricant and shot-peening process. The main purpose is to minimise the wear of the bearing material by penetrating AgNPs added lubricants into the rough surfaces formed by shot peening. Almen intensity, coverage and shot size parameters in the shot-peening process were analysed in terms of hardness, surface roughness and fatigue strength. The shot-peened aluminium bronze was subjected to wear experiments under dry, pure water and AgNPs added lubricant conditions. The wear test results were analysed in terms of friction coefficient, wear volume and surface roughness parameters, and the interaction of lubricant and shot-peening parameters was evaluated. According to the results of the shot-peening experiments, the Almen intensity was the most effective parameter in terms of hardness and surface roughness (91.62%). It was concluded that the hardness value was 8% higher at high Almen (12-14A) intensity compared with low Almen intensities, and the shot-peening process could increase the fatigue strength by similar to 21 times. According to the wear tests, the most effective parameters were 4-6 Almen intensity and AgNP-added lubricant.Öğe Effects of constrained groove pressing, severe shot peening and ultrasonic nanocrystal surface modification on microstructure and mechanical behavior of S500MC high strength low alloy automotive steel(Elsevier, 2021) Karademir, Ibrahim; Celik, Mustafa B.; Husem, Fazil; Maleki, Erfan; Amanov, Auezhan; Unal, OkanS500MC high strength low alloy automotive steel is exposed to bulk severe plastic deformation (SPD) via constrained groove pressing (CGP) and surface severe plastic deformation (S2PD) via severe shot peening (SSP) and ultrasonic nanocrystal surface modification (UNSM). SSP and UNSM could create a nanocrystallization layer till 50-100 mu m away from outmost surface. EBSD investigations showed average nano-grain size obtained via SSP and UNSM was found to be below 100 nm regime. The strength was improved via 1st to 4th pass of CGP, but elongation percentage decreased abruptly. UNSM achieves both strength-ductility improvement with gradient structure. SSP improves the total elongation however a slight decrease on strength is observed. SSP and UNSM showed better wear and friction resistance particularly at lower loads compared to CGP and untreated specimens. Nevertheless, wear and friction behavior at higher loads showed better responses for Bulk-SPD applications regardless of pass numbers. The frictional load increase played a detrimental role in removing a nano crystallization surface layer and diminishing the positive influence of SSP and UNSM.Öğe Effects of Conventional and Severe Shot Peening on Residual Stress and Fatigue Strength of Steel AISI 1060 and Residual Stress Relaxation Due to Fatigue Loading: Experimental and Numerical Simulation(Korean Inst Metals Materials, 2021) Maleki, Erfan; Farrahi, Gholam Hossein; Reza Kashyzadeh, Kazem; Unal, Okan; Gugaliano, Mario; Bagherifard, SaraThis study investigates and compares the effects of different shot peening treatments including conventional and severe shot peening on microstructure, mechanical properties, fatigue behavior, and residual stress relaxation of AISI 1060 steel. Shot peening treatments were applied with two Almen intensities of 17 and 21 A and a wide ranges of coverage (100%-1500%). Various microstructural observations were carried out to analyze the evolution of microstructure. Microhardness, residual stress and surface roughness measurements and also axial fatigue test were performed. Moreover, the extent of the residual stress relaxation during cyclic loading was investigated by means of XRD measurements. Furthermore, numerical simulation of residual stress relaxation due to fatigue loading was carried out and validated against experimental investigations. The comparison indicated a good agreement for the surface residual stress relaxation up to 100 cycles. The experimental results indicated the efficiency of severe shot peening processes in obtaining nanostructured surface layer and achieving superior mechanical properties and fatigue behavior. Also, residual stress measurements revealed that stress relaxation started with a high rate at the initial stages of loading and gradually increased at higher number of cycles which was lower in the case of severely shot peened samples compared to the conventionally treated ones.Öğe Effects of conventional shot peening, severe shot peening, re-shot peening and precised grinding operations on fatigue performance of AISI 1050 railway axle steel(Elsevier Sci Ltd, 2022) Unal, Okan; Maleki, Erfan; Karademir, Ibrahim; Husem, Fazil; Efe, Yusuf; Das, TuranIn this study, effects of conventional shot peening, severe shot peening, re-shot peening and precised grinding were performed to AISI 1050. By two-stage operations (SSP + RSP), residual stress depth and the magnitude on the surface were quite high. While deepest compressive stress was measured in A24 + G, maximum stress was observed in A24 + N14. Grinding and re-shot peening powerfully reduced the roughness. The increase in SP intensity improved the hardness considerably, besides the most effective hardness depth was observed after A36. N7 and N14 contributed effective results in the low cycle fatigue, whereas A24, A18, A18 + N14 and A36 in high cycle fatigue.Öğe Effects of conventional, severe, over, and re-shot peening processes on the fatigue behavior of mild carbon steel(Elsevier Science Sa, 2018) Maleki, Erfan; Unal, Okan; Kashyzadeh, Kazem RezaThe present study investigates experimentally the effects of different shot peening treatments, including conventional, severe, over, and re-shot peening on microstructure, mechanical properties, and fatigue behavior of AIM 1050 mild carbon steel. Different shot peening treatments were performed using various effective parameters by considering the influences of increasing Almen intensity and coverage. Optical microscopy and field emission scanning electron microscopy observations and X-Ray diffraction measurements were carried out to analyze grains refinement in each shot peening treatment. Microhardness and residual stress measurements were taken from shot peened surfaces to the core material to investigate the mechanical properties. The fatigue behaviors of the specimens were examined by using the axial fatigue test. The results indicated that post-grinding, re-shot peening, and severe shot peening processes have significant effects on fatigue life improvement.Öğe Effects of different mechanical and chemical surface post-treatments on mechanical and surface properties of as-built laser powder bed fusion AlSi10Mg(Elsevier Science Sa, 2022) Maleki, Erfan; Bagherifard, Sara; Unal, Okan; Sabouri, Farshad; Bandini, Michele; Guagliano, MarioLaser powder bed fusion (LPBF) materials have various surface defects, which can detrimentally affect the mechanical properties and fatigue behavior of these materials. Surface post-processing can be crucial to reduce or eliminate these surface imperfections. In this study, the effects of different post-processing methods including shot peening, ultrasonic nanocrystalline surface modification and severe vibratory peening as well as electrochemical polishing and other hybrid treatments obtained from their combination were surveyed on microstructure, surface and mechanical properties of LPBF AlSi10Mg specimens. Two different processes with varying levels of kinetic energy were considered for each mechanical surface treatment. The results indicate that mechanical treatments can effectively modify the surface morphology, improve surface hardness and induce compressive residual stresses. In addition, electro-chemical polishing was highly efficient in surface roughness reduction and increasing the wettability of the hybrid mechanically and chemically treated specimens.Öğe Effects of Laser Shock Peening on Corrosion Resistance of Additive Manufactured AlSi10Mg(Mdpi, 2023) Maleki, Erfan; Unal, Okan; Shao, Shuai; Shamsaei, NimaMechanical properties of Al alloys make them an ideal candidate for different sections of marine, aerospace, automotive, etc. industries. Recently taking the advantages of additive manufacturing (AM), many complex infrastructures/components can be fabricated with very high design freedom via Al alloys. Although Al alloys have good natural corrosion resistance, however improving this property attracts lots of attention in the past few years. Post-processing methods can play a key role for addressing the issues related to internal and surface anomalies associated with as-built AM parts. Generally, these anomalies have detrimental effects on mechanical properties. In the present study, the effect of laser shock peening (LSP) treatment with different laser pulse overlaps and energies was investigated comprehensively on microstructure, surface texture, porosity, hardness, residual stresses as well as corrosion resistance of laser powder bed fused (L-PBF) AlSi10Mg samples. LSP provides strain deformation on the surface, and the deformation enhances by laser beam energy. LSP1 (laser energy of 1.5 J and 50% overlap) and LSP3 (laser energy of 4.5 J and 50% overlap) introduce maximum local strain of 7.5 and 10.7, respectively. The surface roughness of as-built state mu m in terms of Rv was effectively diminished to 16.33 after LSP6 (laser energy of 4.5 J and 75% overlap). The results indicated that due to the modified surface texture, improved hardness and induced high compressive residual stresses in the surface layer. (surface hardness improvement and inducing high surface compressive residual stresses were obtained after LSP6 up to 26% and 289 MPa, respectively); the LSP treated samples exhibited higher corrosion resistance with the corrosion rate decreasing down to 50% as compared to the as-built state.Öğe The effects of microstructural and chemical surface gradients on fatigue performance of laser powder bed fusion AlSi10Mg(Elsevier Science Sa, 2022) Maleki, Erfan; Bagherifard, Sara; Unal, Okan; Bandini, Michele; Guagliano, MarioInternal and surface imperfections are known to reduce the fatigue strength of parts fabricated by laser powder bed fusion (LPBF). Post-treatment can play a key role to ameliorate the adverse effects of these defects. In this study, severe vibratory peening, as a novel surface treatment based on severe plastic deformation, was applied for the first time on LPBF material. The effects of this mechanical surface treatment were investigated individ-ually and in combination with heat treatment on microstructural and mechanical properties of V-notched LPBF AlSi10Mg samples. The results revealed the simultaneous formation of microstructural and chemical gradients on the surface layer of the mechanically treated samples, resulting in remarkable mechanical properties' improvement. In addition, the hybrid thermal and mechanical post-treatment significantly improved the fatigue life compared to the as-built condition, through affecting multiple physical phenomena regarding surface and subsurface characteristics.Öğe Effects of pack boriding temperature on wear and corrosion performance of high-strength armor steel(ICE Publishing, 2025-01-28) Neccaroglu, Vahap; Karademir, Ibrahim; Unal, OkanThis study systematically investigates the effects of pack boriding on the microstructure, hardness, wear, and corrosion resistance of armor steel. A saw-like boride layer was formed as a result of the treatment at temperatures of 800, 900, and 1000 °C. The thickness of the boride layer was positively influenced by increases in temperature. At 1000 °C, the microhardness of the borided surface achieved a maximum level of 3250 HV0.02. The wear resistance of the borided specimens was improved significantly, resulting in a notable reduction in volume losses. Furthermore, the boriding process enhanced the corrosion resistance of the steel by a factor of three to four. Specimens borided at 1000 °C demonstrated the highest level of corrosion resistance.Öğe Effects of severe plastic deformation on pre-osteoblast cell behavior and proliferation on AISI 304 and Ti-6Al-4V metallic substrates(Elsevier Science Sa, 2019) Tevlek, Atakan; Aydin, Halil Murat; Maleki, Erfan; Varol, Remzi; Unal, OkanIn this study, titanium alloy (Ti-6Al-4V) and austenitic stainless steel (AISI 304) biomedical alloys were subjected to surface severe plastic deformation (SSPD) via severe shot peening (SSP) with the conditions of A28-30 Almen intensity. SSP is widely accepted as much more effective than the conventional surface modification techniques since it forms a nano-grain layer with large number of dislocations and grain boundaries. The SSP treatment in this study was led to a very thin rough layer in Ti-6Al-4V titanium alloy compared to that of AISI 304. The thicker layer of AISI 304 was created by twin-twin intersections and a martensite structure transformations. SSP treatment was resulted in a severe plastically deformed material surface and led to an increase in full width half maximum (FWHM) that expresses grain size reduction below nanometer regime. Also, SSP treatment increased the surface roughness of materials by forming pits and bumps and led to deterioration on surface topography. Besides physical and microstructural innovations, SSP treatment was improved the surface mechanical properties of the metals. On the other hand, it was noted that the effects of the alteration of surface topography and structural innovations (nano-grain crystal-deformation induced layer) were led to improved cellular behavior and increased cell proliferation regardless of material type.
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