Your search keyword '"Elmas Benzeri karbon"' showing total 3 results

1. Effects of Hard Thin-Film Coatings on Adhesion of Early Colonizer Bacteria Over Titanium Surfaces.

Author

Velioglu, Neslin, Akova, Tolga, and Ozkomur, Ahmet

Subjects

BACTERIAL colonies, THIN films, BACTERIAL adhesion, TITANIUM nitride, SURFACE coatings, DIAMOND-like carbon

Abstract

Copyright of Implant Dentistry is the property of Lippincott Williams & Wilkins and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2016

2. Plazma destekli kimyasal buhar biriktirme yöntemi ile tantal katkılı elmas benzeri karbon film üretimi ve karakterizasyonu

Author

Orhon, Nilüfer, Kazmanlı, Muhammet Kürşat, Metalurji ve Malzeme Mühendisliği Ana Bilim Dalı, Kazmanlı, M. Kürşat, Malzeme Mühendisliği YL., and Materials Engineering MSc.

Subjects

elmas benzeri karbon, plazma destekli kimyasal buhar biriktirme, tantal, plasma assisted chemical vapor deposition, Metalurji Mühendisliği, tantalum, Metallurgical Engineering, Chemical vapor deposition, Tantalum, diamond like carbon

Abstract

Tez (Yüksek Lisans) -- İstanbul Teknik Üniversitesi, Fen Bilimleri Enstitüsü, 2012, Thesis (M.Sc.) -- İstanbul Technical University, Institute of Science and Technology, 2012, Bu çalışmada manyetik alan sıçratma ve plazma destekli kimyasal buhar biriktirme sistemi ile tantal katkılı elmas benzeri karbon ince film üretimi, üretim parametrelerinin optimizasyonu ve filmlerin karakterizasyonu amaçlanmıştır. Bu sistemde temel özellik kaplama sıcaklığının düşük olmasıdır. Altlık malzemesi olarak tek kristal silisyum plaka veya paslanmaz çelik numuneler üzerine öncelikle 2 dk süreyle metalik Ta kaplanmış, üzerine a-C:H yapısı büyütülmeye çalışılmıştır. Metalik Ta kaplanmasının nedeni filmin yüzeye tutunmasını iyileştirmektir. Kaplama parametrelerinin optimizasyonu için basınç, bias potansiyeli, katot gücü, gaz akış oranı, kaplama süresi gibi temel değişkenlerin etkileri incelenmiştir. Yapılan kaplamaların faz analizi için X-ışını difraktometresi, kalınlık ve yapı analizi için taramalı elektron mikroskobu, yapıdaki karbon atomlarının bağ yapılarını belirlemek için de Raman spektrometresi yöntemleri kullanılmıştır. Karakterizasyon sonucunda karbür fazının oluşumu için en iyi katot gücünün 0,2 kW, fakat katot zehirlenmesinin önüne geçmek için kullanılması gereken güç değerinin 0,3 kW olduğu belirlenmiştir. Kaplama basıncı olarak 0,5 Pa, gaz akış oranı CH4/Ar ≈ 1 ve kaplama süresi 1 sa olarak optimize edilmiştir. 350 V bias potansiyelinde daha kalın bir kaplama elde edilmiştir. Tüm incelemeler sonucunda en büyük problem katot zehirlenmesi, dolayısıyla kaplama homojenizasyonunun sağlanamaması olmuştur., Diamond-like carbon films is a metastable form of amorphous carbon structure that containing significant amounts of sp3 bond. Diamond like carbon is a wide band gap semiconductor with a high mechanical hardness, chemical stability and optical transmittance. Diamond-like carbon films are widely used as a protective coating of the optical windows, magnetic storage discs, car parts, biomedical coatings and micro-electro mechanic storage discs. Tantalum is a very hard, malleable, ductile and quite heavy transition metal. Tantalum is a very heavy silvery white highly refractory metal. Its heaviness is not only an enabling factor in its concentration from the cassiterite-bearing sands, but also in some industrial applications. Tantalum carbide is one of the hardest substances known and it is used in tools for cutting very hard metals and alloys. Hardness and high melting point makes it suitable for making high temperature dies in combination. In this study, to take advantage of tantalum and tantalum carbide because of good wear characteristic were used for doping in diamond-like carbon films. Variety of materials derived from carbon films for replacement and improvement of properties of diamond-like carbon films. These materials are similar to diamond-like carbon film structure, but also may contain metal atoms (Me-DLC) in addition to carbon and hydrogen. Many modifications to the diamond-like carbon films, is to reduce the high internal stress of diamond-like carbon films of by lowering the already low friction coefficient in order to reduce the surface energies. The objectives of this study are; the production of tantalum doped diamond-like carbon thin films in a magnetron based plasma assisted chemical vapor deposition system, characterization of these films and the optimization of production parameters. Sputtering and doping of the metal into the a-C:H structure within the system was intended. Observation of carbide formation, and its effects on the mechanical and tribological properties of the films was aimed. The key feature of this system is very low coating temperatures. Therefore, this system is very suitable for polymer-like coatings. DLC has very good wear resistance and low friction coefficient. It was proposed that doping of tantalum into DLC may further improve wear behaviors of the structure due to the known wear resistance enhancing effects of tantalum. In experiments, single crystal silicon wafer and stainless steel substrates were used. Prior to loading the substrate into the deposition chamber, the substrate was cleaned in ultrasonic cleaner with acetone for duration of 10 min. The substrate piece was cleaned with alcohol, air dried and placed in the deposition chamber. The samples were placed in front of the target, in an upright position on the anode. The distance between the cathode and the sample was determined as 9 cm. The samples were subjected to atomic sized final cleaning with glow discharge in chamber. Plasma was generated with argon gas at 5 Pa chamber pressure for duration of 10 min. Bias voltage was 650 V, frequency was 150 kHz, argon gas flow was 65 sccm used for the formation of plasma, respectively. Metallic tantalum was coated on the samples for 2 minutes and a-C:H structure was tried to be grew on the metallic tantalum film. The reason of the coating metallic tantalum on the surface was to improve the adherence to DLC structure. Ta doped DLC films were then produced with previously optimized parameters .The basic variables such as bias potential, target power, gas flow rate; deposition time and pressure to optimize coating parameters were investigated. X-ray diffractometer was used for the phase analysis of the coatings. Cu-Kα radiation that produced in 40 kV and 40 mA was used for the determination of phase. θ=2° scanning angle was chosen and scans were carried out between 20°-120°. All diffractograms were normalized according to the highest violence in this study and qualitative information was obtained about the rate of the phases. Thickness measurements were taken with the cross-sectional view by scanning electron microscopy and EDS analysis was performed from the cross-sectional view for elemental content analysis. Accelerating voltage was chosen during EDS analyzes of the 10 kV, for cross sectional views 5 kV. Raman spectroscopy was used to analyze the carbon bonds in DLC films. HeNe laser source was used, working with power 17mW. 632,817 nm wavelength used in the analysis and were screened between the wavelengths of 400-2000 cm-1. All analyzes were taken 3x3 mode and this mode has been sufficient for the appearance of the expected peaks. 10X magnification of the lens on the device that options were chosen. Berkovich nanoindenter was used to determine the mechanical properties. 5 mN forces were used for each test during analysis. Each sample was measured over 20 points and the average results were evaluated. Elasticity modulus of the films as a result of the hardness tests was examined. Ball on disc tribometer method was used to determine to wear properties. Tribology test using stainless steel balls were made in dry conditions on the stainless steel samples. 4 mm radius of gyration, 5 cm/s rotation speed and 4 N loads were used during the test. One of the most important parameters affecting the coating structure is the ratio of argon/methane and the appropriate coatings can be obtained when this ratio is approximately equal to 1. Increases the amount of methane is observed cathode poisoning and decreases the amount of methane is observed in the metallic coating. Decomposition in the plasma and the formed homogeneous coatings provided the best way, the pressure value determined to 0.5 Pa. Over this pressure value, amount of carbon reduces in the structure. Increase the potential of bias reduces the amount of tantalum in the structure. Therefore, decreasing the formation of tantalum carbide, declining rate of crystallization and more graphitic structure was observed. Accordingly, it is preferred to be 350 V bias potential. The amount of power applied to magnetron, understood that a precise position for the problem of the cathode poisoning. Tantalum carbide structure clearly not been seen in samples coated with 0.3 kW and sufficiently Ta is not sputtered with 0.2 kW because of cathode poisoning. Using different power units is thought to be achieved optimization with scanning range in these two values. Optimum coating time is observed for 1 hour. Again, because of the forming nonconductive layer on the cathode, the coating is weakened or stopped for a while after the plasma is considered and as a result of this is thought to decrease the deposition rate. 2 and 4 hours no difference in the thickness of coatings also provides support to this idea. As a result of the measurement of mechanical properties, Vickers hardness ranged from 797-928 in structures containing tantalum carbide. Other structures were measured the average hardness of 650 Vickers. Understood that the forming of tantalum carbide is increases the hardness. Result of the hardness tests, modulus of elasticity values were measured between 88-105 GPa. In the literature, diamond-like carbon film is given lower elasticity modulus. Accordingly, the addition of tantalum in diamond-like carbon film to increase the modulus of elasticity and thus can be said to reduce the elastic feature. Compared to modulus of elasticity, moduli of elasticity of structures including tantalum carbide are higher than others. Had a negative effect on the elastic properties can be proposed that the formation of tantalum carbide. Tribological analysis result, coefficient of friction of the a-C:H structure including tantalum was determined as 0.1. As a result of all investigations, the biggest problem was cathode poisoning, therefore, been of making a homogeneous coating., Yüksek Lisans, M.Sc.

Published

2012

3. Production, Characterization And Tribological Properties Of Molybdenum Doped Diamond-like Carbon Films

Author

Alp, Emre, Kazmanlı, Kürşat, Malzeme Bilimi ve Mühendisliği, Material Science and Engineering, Kazmanlı, M. Kürşat, Kazmanlı, Muhammet Kürşat, and Metalurji ve Malzeme Mühendisliği Ana Bilim Dalı

Subjects

Thin Films, Molybdenum, Tribology, İnce Film, Nano-Kompozit, Thin films, İ nce filmler, Metallurgical Engineering, Elmas-Benzeri Karbon, Nano-composites, Carbon, Mühendislik Bilimleri, Nanocomposites, Diamond-like Karbon, Amorphous structures, Tribological properties, Diamond-Like Carbon, Metalurji Mühendisliği, Molibden, Triboloji, Engineering Sciences, Elmas Benzeri karbon

Abstract

Tez (Yüksek Lisans) -- İstanbul Teknik Üniversitesi, Fen Bilimleri Enstitüsü, 2012, Thesis (M.Sc.) -- İstanbul Technical University, Institute of Science and Technology, 2012, Karbon temelli kaplamalar birçok bilim dalına konu olmakta ve endüstriyel olarak kullanılmaktadır. Karbon doğada bol bulunan ve endüstriyel anlamda ekonomik bir elementtir. Karbon temelli malzemeler, elmasta olduğu gibi yüksek sertlik ve termal iletkenlik gösterirken, grafitte yumuşak ve yağlayıcı özellik göstermektedir. Bunların yanında karbonun karbon nano tüp, fuleren, karbon-karbon kompozit camsı karbon ve karbon nano fiberler gibi allotropları vardır. Elmas benzeri karbon ince filmler yüksek sertlik, düşük sürtünme ve yüksek aşınma dirençlerinden dolayı katı yağlayıcı olarak tribolojik uygulamalarda kullanımı oldukça yaygındır. Elmas benzeri karbon filmler ilk olarak 1950’lerde Schmellenmeier tarafından keşfedilmiştir ancak Eisenberg ve Chabot’un 1970’lerde yaptıkları çalışmalar ile ilgi çekmiştir. Daha sonra ki yıllarda hakkında bir çok bilimsel yayın yapılmış ve patent alınmıştır. Elmas benzeri karbon filmlerin tribolojik uygulamalardaki performansı büyük oranda onun altlığa yapışma özelliğine bağlıdır. Silikon ve titanyum gibi karbür yapabilen altlıklara ve arakatman kullanılarak yapılan uygulamalarda yapışma mukavemeti iyidir. Elmas benzeri karbon filmlerin doğasından kaynaklanan yüksek basma gerilmeleri içermesi ve yüksek sıcaklıklarda faz değiştirmesi dezavantajlarındandır. Nano kristal yapılar ya da nano fazlar içeren elmas benzeri karbon filmler fiziksel ve kimyasal buhar biriktirme teknikleriyle zorlu şartlarda kullanım için üretilebilmektedir. Son yıllarda hibrit buhar biriktirme sistemlerinin geliştirilmesiyle elmas benzeri karbon filmlerin özelliklerinin daha kolay kontrol edilebilmesiyle endüstriyel uygulamalardaki dayanım gereklilikleri ve performansları arttırılmıştır. Metaller (Ti, Cu, W, Mo, Ta, Cr, Ni…), hafif elementler (B,Si, N, O, F) veya bunların kombinasyonlarıyla alaşımlanan ya da katkılanan elmas benzeri karbon filmlerin sertlik, iç gerilme, yapışma, tribolojik özellikleri, elektrik ve termal iletkenlikleri ve biyo-uyumlulukları değiştirilebilmektedir. Amorf yapı içerisine gömülen katkılandırılmış elementler matriks içerisinde tek bir faz olarak ya da ayrı bir ikincil faz olarak nano ölçeklerde oluşturulabiliyor. Bu nano kompozit ya da çok katmanlı filmler geliştirilmiş sertlik, tokluk ve yapışma özellikleriyle üstün aşınma dirençleri sergilemektedirler. Elmas benzeri karbon filmlere Nb, Ti, W ve Mo gibi karbür yapma afiniteleri yüksek metalik elementlerin katkılanması onun amorf matriks içerisinde nano kristal karbür taneleri olarak dağılmasına yol açmaktadır. Bu nano kompozit kaplamaların sertlik değerleri 30 Gpa’ ın üstüne çıkan değerler gösterebilmektedir. Hatta hidrojen içermeyen atmosferlerde üretilen elmas benzeri karbon ince filmlerin sertliklerinin neredeyse 90 GPa’ a kadar çıktığı belirtilmiştir. Elmas benzeri karbon filmlerin tribolojik uygulamalarda kullanımının çok büyük bir ilgi görmesinin nedeni yüksek sertlik ve yüksek kimyasal kararlılık göstermesiyle birlikte çok düşük sürtünme katsayısı ve aşınma katsayısı göstermesidir. Son yıllarda, elmas benzeri karbon yapıların tribolojik uygulamalarda kullanımı artan bir ivmeyle devam etmektedir. Bu çalışma, metan ve argon gaz ortamında yüksek vakum değerlerinde paslanmaz çelik altlık üzerine darbeli manyetik alanda sıçratma ve plazma destekli kimyasal buhar biriktirme hibrit yöntemiyle amorf karbon matriks içerisine molibden katkılamayı amaçlamaktadır. Metan-argon gaz karışımındaki argon miktarının değiştirilmesiyle amorf matriks içerisinde farklı molibden içerikleri oluşturulmuştur. Elmas benzeri karbon amorf matrikste artan oranda molibden katkısının oluşumu metan gazının kaplama ünitesine akış hızı sabit tutularak argon gazının kaplama ünitesine giriş hızı artırılarak yapılmıştır. Değişen molibden içeriğiyle matriks içerisinde oluşan nano-molibden karbür fazlarının aşınma ve sürtünme davranışlarına etkisi irdelenmiştir. Üretilen faklı molibden içerikli elmas benzeri karbon filmlerin yapısal ve kompozisyonel değerleri Raman spektrometresi, XRD ve EDS tekniklerini kullanan cihazların yardımıyla incelenirken sertlik ve tribolojik özellikleri mikrosertlik ve disk üzeri top aşınma cihazlarının yardımıyla incelenmiştir. Molibden katkılı elmas benzeri karbon filmlerin paslanmaz çelik altlığa yapışma özellikleri için kaplamalara çizik testi uygulanmıştır. Bunun yanında çizik testinin doğruluğunu pekiştirmek ve kaplamada oluşacak kırık tiplerine göre yorumlamak amacıyla Rockwell Testi uygulanmıştır. Bütün sonuçlar irdelendiğinde molibden katkısının kritik bir değere kadar elmas benzeri karbon kaplamaların sürtünme ve aşınma özellikleri makul bir değerdeyken molibden katkısının artmasıyla kaplamaların sürtünme ve aşınma özellikleri kötüleşmiştir., Thin films whose thickness is typically less than several microns are produced by the deposition of individual atoms on any substrate. Historically, thin films have been used for about half a century in producing instrument hard coatings, optical coatings, thin-film batteries, electronic devices, photovoltaic devices, memory devices and decorative parts. Thin film technology is still being developed by a technological advancement since it is a key factor in the twenty-first century development of new materials such as nanometer materials and/or a man-made superlattices. Thin film materials are also suitable for minimization of toxic materials. Thin film processing also saves on energy consumption in production and is considered an environmentally benign material technology for the next century. Among all physical phenomena, friction perhaps is one of the greatest challenges for the industrial and scientific communities. Friction has a direct connection about to energy efficiency and environmental cleanliness of all moving mechanical systems. We rarely think about friction or appreciate the value of its importance in daily life. However, there is no doubt that it is a major cause of lost energy, and as well as hazardous emissions to our world. Consequently, the search for further reducing friction in engineering systems has real-life effects for not only conserving our limited energy resources, but also saving our planet from hazardous emissions. The friction between two solid surfaces in solid-state contact is the resistance to tangential motion of one surface over the other. In the field of tribology, the term friction coefficient is frequently used to describe the resistance to tangential motion. When the extent of physical and/or chemical interactions is extremely small or essentially absent, the surfaces can slide over one another without causing much friction. For this situation, the word “superlubricity” was first used by Motohisa Hirano. Historically, the earliest studies on superlubricity started in mid-1980s, but the real progress occurred during the 1990s. The abundance of raw material and the economic value of the material produced for engineering applications is the most important issue. When we look at from this point, carbon, which exists in more than 90% of all known substances, is one of the most abundant elements in our planet. Carbon has the largest number of allotropes, including diamond, white carbon, graphite, buckyballs, carbon nanotubes, and other forms of fullerenes. Besides these allotropes, there exist several more carbon-based non-crystalline materials, including carbon–carbon composites, bulk glassy carbons, and amorphous Diamond-like carbon films. DLC is the subject of this study because of its low friction property and well wear behaviour. Diamond-like carbon thin films was first reported in the early 1950s. However, base progress and systematic studies started in the 1970s. Over the years, diamond-like carbon films have attracted huge scientific and commercial interest mainly because of their superlow friction and wear, excellent optical, high chemical inertness aand dielectric properties. Especially, Diamond-like carbon films has attracted great interest in tribological applications due to their low friction and good wear baheviour. Unlike synthetic diamond films, the production of diamond-like carbon is rather easy and can be achieved over a broad range of deposition conditions and temperatures. Physical vapor deposition (PVD) and chemical vapor deposition (CVD) methods can be used to produce diamond-like carbon thin films on substrate materials which include metals, ceramics, and certain polymers. The carbonaceous precursors used and the deposition conditions, such as deposition temperature, gas pressure and applied bias voltage on substrate, strongly change the type of bonds (i.e., sp1 , sp2 , sp3 ) that hold carbon atoms together in diamond-like carbon thin films. If a hydrocarbon gas (such as methane, ethane or acetylene) is used as the carbon source, diamond-like carbon films may contain considerable amounts of hydrogen in their microstructures. These highly hydrogenated DLC films (containing more than 40 at.% hydrogen) can be relatively soft but exhibit some of the lowest friction and wear coefficients. Tribological behaviour of diamond-like carbon films strongly depends on test conditions. Friction coefficient of diamond like carbon films can vary in the wide range of 0,01-1 depending on test conditions. In recent years, many scientists in this field have invented more forms of DLC by incorporating certain elements; such as H, N, B, F, Mo, Ta, Ti, Cr, W, and S into their amorphous microstructures. Some of these films are extremely hard -as high as 90 GPa-, while others are rather soft but provide some of the lowest friction and wear coefficients. Diamond-like carbon coatings are often used to prevent wear due to its excellent tribological properties. Diamond-like carbon thin films are very resistant to abrasive and adhesive wear. These films are now used in too many industrial applications, such as metal cutting tools, razor blades, magnetic hard disks, critical engine parts and microelectromechanical systems. Recent investigations have provided special materials with hardness in the range of diamond. The most common compounds developed in hardness applications are basically nitrides, carbides and borides of groups IV, V and VI of the transition metals. TiN, TiC, TiCN, TiAlN, CrN and Al2O3 can be exemplary given such compounds. Diamond-like carbon , WC/C and MoS2 are adequate for tribological applications containing lubrication due to their excellent tribological properties. Both of nitrides and carbide particles embedded in diamond-like carbon have also been produced. The doping of diamond-like carbon with metallic elements leads to structures presenting carbide nanocrystals distributed within the amorphous diamond-like carbon matrix. Metal-containing diamond-like carbon (Me-DLC) films exhibit hardness values above 30 GPa. Alloyed diamond-like carbon coatings is an important category of diamond-like carbon characterized by the incorporation of different elements in their structure to accomplish improved properties in respect to pure diamond-like carbon films. Dopants elements and their combinations are added to modify their properties via controlling content and distribution of the dopant elements such as hardness, internal stress, adhesion, tribological properties, electrical conductivity or biocompatibility. In this study, molybdenum-containing diamond-like carbon films were deposited on stainless steel via hybrid system of pulsed magnetron sputtering (PVD) and plasma enhanced chemical vapour deposition (PECVD) in an argon and methane atmosphere. The aim of this study is to change molybdenum contents in the amorphous matrix of diamond-like carbon. Different molybdenum contents in the amorphous matrix was formed by changing amount of argon gas in the methane-argon gas mixture. Formed nano-molybdenum and nano-molybdenum carbide phases in the amorphous matrix by changing molybdenum contents has been investigated how effects of friction and wear behaviour become. The structure and composition of the molybdenum-containing diamond-like carbon films were characterized by Raman spectroscopy, X-ray diffractometry (XRD) and energy dispersive spectroscopy (EDS). Scratch test has been applied to determine its adhesive strength to substrate. Thin film hardness has been determined by ultra submicron hardness test. A ball-on-disc test was carried out to analyze the wear behavior and frictional properties of different molybdenum-containing diamond-like carbon films., Yüksek Lisans, M.Sc.

Published

2012