Hasil Pencarian  ::  Simpan CSV :: Kembali

"ABSTRAKFeCoNi merupakan paduan ternari berbasis logam transisi merupakan bahan magnet lunak memiliki nilai magnetisasi total yang tinggi, ketahanan korosi dan kestabilan termal yang tinggi dan memiliki potensi aplikasi yang luas pada berbagai perangkat elektronik. Pada saat ini, perkembangan perangkat elektronik semakin maju, misalnya pada perangkat portable modern, menuntut bahan magnetik yang tidak hanya tipis namun juga fleksibel. Dalam penelitian ini, dikembangkan metoda sintesis paduan FeCoNi dalam bentuk lapisan nanostruktur dengan teknik elektrodeposisi pada substrat fleksibel yaitu polietilen PET yang dilapisi material konduktif indium tin oksida ITO . Pengaruh kondisi reaksi seperti tegangan ko-deposisi, komposisi elektrolit, dan penambahan bahan kimia aditif masing-masing cetyltrimethylammonium bromide CTAB dan sakarin dikaji peranannya dalam pembuatan lapisan tipis FeCoNi di atas substrat tersebut.Kajian elektrokimia yang telah dilakukan dalam sel tiga elektroda menunjukkan bahwa inisiasi ko-deposisi Fe, Co dan Ni dari elektrolit 1 0,005 M Fe2 , 0,0020 M, Co2 dan 0,170M Ni2 terjadi pada tegangan overpotential -0,95 V. Penambahan sakarin dalam sistem elektrolit tidak memberikan pengaruh besar terhadap kenaikan overpotential sistem. FeCoNi kemudian dideposisikan pada tegangan -1,00 s/d -2,00 V. Deposit FeCoNi yang dihasilkan membentuk lapisan tipis dengan ketebalan 155 nm dengan permukaan yang halus dan rata serta mengkilap. Hasil-hasil karakterisasi membuktikan bahwa fasa tunggal dari larutan padat FeCoNi telah berhasil disintesis dalam bentuk partikel-partikel halus berkuran 40-180 nm. Larutan padat berupa kristalit FeCoNi berukuran antara 10-22 nm, terbentuk dengan struktur kristal FCC. Kehadiran aditif sakarin dalam elektrolit berperan dalam mengontrol ukuran kristalit FeCoNi. Selain itu, penambahan sakarin juga telah merubah morfologi partikel dari bentuk spherical menjadi equi-axed, menghasilkan mikrostruktur deposit yang lebih kompak bebas retakan pada lapisan. Hasil analisis terhadap sifat magnetik menunjukkan bahwa lapisan tipis FeCoNi hasil sintesis memiliki karakteristik magnet lunak dengan koersivitas terkecil mencapai 0,2 Oe. Lapisan tipis FeCoNi yang diperoleh secara eksperimental memiliki nilai magnetisasi total pada rentang 81 - 121 emu/gram sesuai dengan kondisi reaksi yang digunakan. Perubahan sifat magnetik bahan dipengaruhi oleh kandungan Fe dan Ni dalam lapisan FeCoNi.

---

ABSTRACTFeCoNi is a transition metal based alloy possesses excellent soft magnetic characteristics with a high magnetic saturation value, a low coercivity, highly corrosion resistant and a very good thermal stability. Current growth of today rsquo s electronic devices demands alloys which are not just very thin magnetic films, but must also be flexible magnetic films. In this study, synthesis of magnetic thin film of FeCoNi alloy was carried out onto a flexible substrate of polyethylene PET coated with a conductive layer of indium tin oxide ITO using electrodeposition technique. The influence of reaction conditions like co deposition potentials, electrolyte compositions, and cetyltrimethylammonium bromide CTAB and saccharine additives on the growth and properties of the FeCoNi thin film were investigated.Electrochemical studies performed in a three electrode cell showed that initial co deposition of Fe, Co and Ni from electrolyte 1 0,005 M Fe2 , 0,0020 M, Co2 and 0,170M Ni2 take place at over potential of 0,95 V. The addition of additives and the increase of Fe2 concentration were found to slightly shift the initial co deposition to a more negative potential. The mirror like film of FeCoNi with a thickness of 155 nm was electrodeposited successfully at a co deposition potential range of 1.00 to 2.00 V. Microstructure analysis revealed that single phase of the FeCoNi solid solution was successfully grown on the substrate in the form of fine particles of 40 180 nm. The obtained solid solution was composed by nanocrystalline of face centered cubic FCC FeCoNi with the average of crystallite size of 10 22 nm. The presence of saccharine in the electrolyte was beneficial to control crystallite size and changed particles shape from spherical to to equi axed resulted in more compact film. These conditions were believed to impede crack that found on the film electrodeposited without saccharine. The synthesized FeCoNi thin film exhibited soft magnetic properties at which the low coercivity was 0.2 Oe. Magnetic saturation of the films varied between 81 to 121 emu gram, depending on the co deposition condition. The change of magnetic properties was attributed to Fe and Ni content."

"This book gives an overview of nanostructures and nanomaterials applied in the fields of energy and organic electronics. It combines the knowledge from advanced deposition and processing methods of nanomaterials such as laser-based growth and nanopatterning and state-of-the-art characterization techniques with special emphasis on the optical, electrical, morphological, surface and mechanical properties. Furthermore it contains theoretical and experimental aspects for different types of nanomaterials such as nanoparticles, nanotubes and thin films for organic electronics applications. "

"Latar Belakang: Sklerosis multipel (multiple sclerosis/MS) merupakan penyakit inflamasi-demyelinasi sistem saraf pusat yang mengakibatkan atrofi struktur otak penderita. Indeks korpus kalosum (IKK) merupakan salah satu metode pengukuran morfometrik korpus kalosum yang cepat serta dengan reliabilitas interrater yang tinggi. Tujuan: Mengetahui korelasi antara hasil pengukuran IKK dengan volume korpus kalosum, substansi grisea kortikal, substansi grisea subkortikal, dan substansi alba serebri melalui MRI volumetri otak pada penderita MS. Metode : Hasil MRI kepala dari 30 penderita MS dilakukan pengukuran IKK. Nilai IKK kemudian dilakukan analisis korelasional dengan volume korpus kalosum, substansi grisea kortikal, substansi grisea subkortikal, dan substansi alba serebri yang diperoleh menggunakan perangkat lunak FreeSurfer©. Hasil : Terdapat korelasi yang sangat kuat antara IKK dengan volume korpus kalosum (R = 0,797 ; p = 0,001) dan volume substansi alba serebri (R = 0,813 ; p = 0,001). IKK juga berkorelasi kuat dengan volume substansi grisea kortikal (R = 0,642 ; p = 0,001) dan volume substansi grisea subkortikal (R = 0,696 ; p = 0,001). Kesimpulan : Metode pengukuran IKK dapat menjadi parameter morfometrik cepat dan sederhana yang menggambarkan volume korpus kalosum, substansi grisea kortikal, substansi grisea subkortikal, dan substansi alba serebri pada penderita MS.

---

Background: Multiple sclerosis (MS) is an inflammatory-demyelinating disease of the central nervous system which results in atrophy of brain structure. Corpus callosum index (CCI) is a method of morphometric measurement of the corpus callosum using midsagittal slice from MRI which does not require additional sequences with fast processing time and high interrater reliability.

Objectives : To determine the correlation between the CCI measurements with corpus callosum, cortical gray matter, subcortical gray matter, and cerebral white matter volume through brain MRI volumetry in MS patients.

Methods : CCI measurements were obtained from head MRI from 30 MS patients according to the method conceived by Figueroa et al. Correlational analysis was carried out between CCI with corpus callosum, cortical gray matter, subcortical gray matter, and cerebral white matter volume obtained using FreeSurfer©.

Results : Very strong correlation was shown between CCI and corpus callosum volume (R = 0.797; p = 0.001) and cerebral white matter volume (R = 0.813; p = 0.001). CCI also shown strong correlation with cortical gray matter volume (R = 0.642; p = 0.001) and subcortical gray matter volume (R = 0.696; p = 0.001).

Conclusion : CCI can be a fast and simple morphometric parameter that describes the corpus callosum, cortical gray matter, subcortical gray matter, and cerebral white matter volume in MS patients."

"Physics of nanostructured solid state devices introduces readers to theories and concepts such as semi-classical and quantum mechanical descriptions of electron transport, methods for calculations of band structures in solids with applications in calculation of optical constants, and other advanced concepts. The information presented here will equip readers with the necessary tools to carry out cutting edge research in modern solid state nanodevices."