Hasil Pencarian  ::  Simpan CSV :: Kembali

"Determination of gamma emiter radionuclides impuritis in 99Mo fission products of llow enriched uranium. Determination of the gamma emitter radionuclides impuritis in 99Mo fission produc from low enriched uranium (LEU) by lod-thio extraction methods was carried ourt..."

"Pengembangan terhadap paduan zirkonium sebagai biomaterial yang diproduksi melalui proses metalurgi serbuk diteliti dengan diberikan perlakuan panas pada komposisi unsur paduan molibdenum (3%, 6%, dan 9% massa Molibdenum) serta dihubungkan terhadap densitas dan porositas, struktur mikro dan kekerasan menggunakan pengujian Rockwell C.Dari hasil pengujian didapatkan bahwa struktur mikro yang dominan terbentuk adalah fasa α-Zr dan Mo2Zr, dan dengan pemberian perlakuan panas struktur mikro yang terlihat menjadi lebih jelas batas butirnya. Dari hasil uji densitas dan porositas, poros yang terbentuk semakin bertambah seiring bertambahnya jumlah Molibdenum yang diberikan, perlakuan panas memberikan efek yang buruk karena akan menambah jumlah poros dari molibdenum yang menguap diatas suhu 600oC. Dari hasil kekerasan yang dicapai unsur molibdenum tidak memberikan efek yang terlalu signifikan walau kekerasan bertambah seiring dengan jumlah molibdenum yang bertambah, dengan perlakuan panas kekerasan turun dikarenakan porositas setelah diberi perlakuan panas bertambah.

---

Development of zirconium alloy as biomaterial produced by powder metallurgy method is studied from effect of heat treatment with different compositions of molybdenum. ( 3%, 6% and 9% weight of Molybdenum), its density and porosity, microstucture and hardness using Rockwell C method. From the experimental, the dominan microstructure formed is α-Zr and Mo2Zr phase and by heat treatment it is clearer to see boundary and grain boundary. From density and porosity test, the formed porous increase as composition molybdenum increase, heat treatment give negative effect, mollybdenum will formed molybdenum oxided vollatile when heated above 6000C. From hardness test, molybdenum does not give significant effect to the hardness. The hardness increase as the composition of molybdenum increase, also hardness decrease due to the increase of porosity after heat-treatment."

"Paduan biomaterial terner Zr-xMo-yNb dengan variasi Zr-1Mo-1Nb, Zr-6Mo-3Nb, dan Zr-3Mo-6Nb yang diproduksi melalui metalurgi serbuk diberi perlakuan panas pada suhu 850°C kemudian dikuens dengan oli. Pengaruhnya terhadap struktur mikro, densitas dan porositas, serta kekerasan diteliti dan dibandingkan dengan paduan yang sama yang tidak diberi perlakuan panas. Struktur mikro paduan didominasi fasa α-Zr dan beberapa paduan mengandung α-Zr+(Mo,Nb)2Zr yang keras. Rangsangan panas mengakibatkan batas butir menjadi lebih jelas terlihat. Namun, perlakuan panas ini justru menambah porositas mikro sehingga nilai kekerasan paduan yang tidak dan yang diberi perlakuan panas relatif sama. Bertambahnya jumlah porositas akan diikuti dengan menurunnya nilai densitas.

---

In this paper, three ternary biomaterial alloys of Zr-1Mo-1Nb, Zr-6Mo-3Nb, Zr-3Mo-6Nb were fabricated through powder metallurgy process and heat-treated to 850°C, followed by quenching in oil. The effects of heat-treatment on microstructure, density, micro-porosity, and hardness was observed and compared to the non-heat-treated samples of the same compositions. α-Zr phase exists predominantly in the microstructure of the samples. Some of the samples, however, also features hard intermetallic phase of α-Zr+(Mo,Nb)2Zr. Unfortunately, the heat also increased the number of micro-porosity which affected the hardness of the samples. This increase in micro-porosity also lead to the decrease of density."

"Molybdenum disulfide (MoS2), yang merupakan bagian dari kelompok material yang disebut dengan transition metal dichalcogenides, menarik banyak perhatian dikarenakan sifat-sifat fisis yang unik yang dimilikinya. Single layer material ini mengalami transisi indirect band gap ke direct band gap, yang karenanya dapat dimanfaatkan untuk berbagai aplikasi optoelektronik. Untuk mempelajari struktur pita (band structure) dari material ini secara detail. pendekatan first-principles seperti density functional theory (DFT) menjadi pilihan populer. Namun, terdapat tantangan yang besar untuk menggunakan pendekatan tersebut untuk menghitung dengan benar efek yang ditimbulkan akibat korelasi kuat antar elektron. Saat ini, telah diperkenalkan sebuah pendekatan yang menggabungkan DFT dengan apa yang disebut dengan GW+BSE untuk menghitung efek interaksi elektron-elektron dan elektron-hole. Dalam tesis ini, kami mempelajari sifat-sifat optik 1H- dan distorted 1T'-MoS2 dengan mengikutsertakan dalam perhitungan interaksi antar elektron dalam kerangka GW dan elektron-hole dengan menyelesaikan persamaan Bethe-Salpeter (BSE).

---

Molybdenum disulfide (MoS2), which belongs to transition metal dichalcogenides, has attracted great attention mainly due to their unique physical properties. A single layer of this material undergoes indirect to direct band gap transition, which enables a wide range of optoelectronic applications. To explore the details of the band structure of this material. a first-principles approach such as density functional theory (DFT) has become a popular choice. However, apart from its well-established formulation, it remains a big challenge to use such an approach to capture effects arising from correlations among the electrons correctly. Nowadays, an approach to combine DFT with a so-called GW+BSE to address the effects of electron-electron and electron-hole interactions, has been introduced. In this thesis, we study the optical properties of 1H- and distorted 1T-MoS2 taking into account electron-electron interaction within GW approximation and electron-hole interaction by solving Bethe-Salpeter equation (BSE)."

"Molybdenum is an emerging pollutant worldwide. The objective of this study is to isolate molybdenum-reducing bacterium with the ability to grow on phenolic compounds (phenol and catechol). The screening process was carried out on a microplate. The bacterium reduced molybdenum in the form of sodium molybdate to molybdenum blue (Mo-blue). The bacterium required a narrow pH range for optimal reduction of molybdenum, i.e. between  pH 6.3 and 6.8, with temperature between 34 and 37 oC. Molybdate reduction to Mo-blue was best supported by glucose as the carbon source. However, both phenol and catechol could not support molybdate reduction. Other requirements for molybdate reduction included sodium molybdate concentrations between 15 and 30 mM, and phosphate concentration of 5.0 mM. The bacterium exhibited a Mo-blue absorption spectrum with a shoulder at 700 nm and a maximum peak near the infrared region at 865 nm. The Mo-reducing bacterium was partially identified as Enterobacter sp. strain Saw-2. The capability of this bacterium to grow on toxic phenolic compounds and to detoxify molybdenum made it a significant agent for bioremediation."

"Molibdenum disulfida merupakan aditif gemuk yang terkenal karena memiliki sifat ketahanan aus yang sangat baik. Ukuran partikel memengaruhi kinerja aditif, dimana semakin kecil ukuran partikel akan memberikan sifat ketahanan aus yang semakin baik. Namun diperlukan biaya yang semakin besar untuk memperoleh partikel berukuran kecil. Oleh karena itu, dibutuhkan penelitian terkait kombinasi ukuran partikel aditif molibdenum disulfida terhadap efektivitas kerja pelumasan gemuk untuk memaksimalkan efisiensi biaya yang diperlukan. Pembuatan gemuk dilakukan melalui reaksi saponifikasi minyak sawit sebagai bahan dasar dengan asam 12-hidroksi stearat, kalsium hidroksida, dan asam asetat sebagai pengental. Hasil bio-gemuk kalsium kompleks NLGI 2 selanjutnya dicampur dengan bubuk aditif molibdenum disulfida 1% b/b. Ukuran partikel aditif divariasikan menjadi 5 μm (Mb), 2 μm (Mk), dan 100 nm (N). Selain itu, dilakukan variasi kombinasi dua ukuran meliputi Mb+Mk, Mb+N, Mk+N, serta kombinasi tiga ukuran dengan komposisi berbeda. Partikel dikarakterisasi ukurannya menggunakan TEM dan PSA. Sedangkan gemuk dikaraktersasi menggunakan uji penetrasi, dropping point, dan four-ball. Hasil penelitian menunjukkan bahwa penambahan aditif molibdenum disulfida dapat mencegah keausan. Selanjutnya, kombinasi tiga ukuran terbukti efektif dalam meningkatkan performa anti-wear, diikuti dengan kombinasi dua dan satu ukuran, dimana hasil paling optimum yaitu dengan komposisi 1:1:1. Namun, penambahan aditif tidak memengaruhi tingkat penetrasi dan dropping point.

---

Molybdenum disulfide is a grease additive known for its excellent anti-wear properties. Its performance is affected by particle size, where the smaller the particle will provide better anti-wear performance. In consequence, higher costs are needed. Therefore, research is needed on the particle size combination of molybdenum disulfide particles on tribological performance to achieve cost efficient grease. The grease is made through the saponification reaction of palm oil as base material with 12-hydroxystearic acid, calcium hydroxide, and acetic acid as thickener. The resulting NLGI 2 calcium complex bio-grease was then mixed with 1% w/w molybdenum disulfide powder. The additive particle size was varied into 5 μm (Mb), 2 μm (Mk), and 100 nm (N). Various combinations of two sizes were also carried out, while three sizes were varied by its compositions. Particles were characterized using TEM and PSA, meanwhile bio-grease using penetration, drop point, and four ball tests. The results showed that the addition of molybdenum disulfide could prevent wear. Furthermore, combination of three sizes was proven to be effective in increasing anti-wear performance, followed by combination of two and one size, with optimal results of 1:1:1. However, the addition of additives did not affect the penetration rate and drop point."