Iron oxide/titania composites for radar absorbing material (RAM) applications

Fisli, Adel; Winatapura, Didin S.; Sukirman, Engkir; Mustofa, Salim; Adi, Wisnu Ari; Taryana, Yana

doi:10.1590/0366-69132019653752728

Cited by 8 publications

(5 citation statements)

References 28 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Radiation absorption and energy dissipation in the form of heat by a material occur via dielectric and/or magnetic loss [138][139][140][141][142]. Therefore, so called "Radar Absorbing Materials" (RAMs) should have large permittivity and permeability for an efficient absorber [143][144][145].…”

Section: Applications In Electromagnetic Radiation Protection and Catalytic Radar Absorption Materialsmentioning

confidence: 99%

Plasma Generating—Chemical Looping Catalyst Synthesis by Microwave Plasma Shock for Nitrogen Fixation from Air and Hydrogen Production from Water for Agriculture and Energy Technologies in Global Warming Prevention

Akay

2020

Catalysts

View full text Add to dashboard Cite

Simultaneous generation of plasma by microwave irradiation of perovskite or the spinel type of silica supported porous catalyst oxides and their reduction by nitrogen in the presence of oxygen is demonstrated. As a result of plasma generation in air, NOx generation is accompanied by the development of highly heterogeneous regions in terms of chemical and morphological variations within the catalyst. Regions of almost completely reduced catalyst are dispersed within the catalyst oxide, across micron-scale domains. The quantification of the catalyst heterogeneity and evaluation of catalyst structure are studied using Scanning Electron Microscopy, Energy Dispersive X-ray Spectroscopy and XRD. Plasma generating supported spinel catalysts are synthesized using the technique developed by the author (Catalysts; 2016; 6; 80) and BaTiO3 is used to exemplify perovskites. Silica supported catalyst systems are represented as M/Si = X (single catalysts) or as M(1)/M(2)/Si = X/Y/Z (binary catalysts) where M; M(1) M(2) = Cr; Mn; Fe; Co; Cu and X, Y, Z are the molar ratio of the catalysts and SiO2 support. Composite porous catalysts are synthesized using a mixture of Co and BaTiO3. In all the catalysts, structural heterogeneity manifests itself through defects, phase separation and increased porosity resulting in the creation of the high activity sites. The chemical heterogeneity results in reduced and oxidized domains and in very large changes in catalyst/support ratio. High electrical potential activity within BaTiO3 particles is observed through the formation of electrical treeing. Plasma generation starts as soon as the supported catalyst is synthesized. Two conditions for plasma generation are observed: Metal/Silica molar ratio should be > 1/2 and the resulting oxide should be spinel type; represented as MaOb (a = 3; b = 4 for single catalyst). Composite catalysts are represented as {M/Si = X}/BaTiO3 and obtained from the catalyst/silica precursor fluid with BaTiO3 particles which undergo fragmentation during microwave irradiation. Further irradiation causes plasma generation, NOx formation and lattice oxygen depletion. Partially reduced spinels are represented as MaOb–c. These reactions occur through a chemical looping process in micron-scale domains on the porous catalyst surface. Therefore; it is possible to scale-up this process to obtain NOx from MaOb for nitric acid production and H2 generation from MaOb–c by catalyst re-oxidized by water. Re-oxidation by CO2 delivers CO as fuel. These findings explain the mechanism of conversion of combustion gases (CO2 + N2) to CO and NOx via a chemical looping process. Mechanism of catalyst generation is proposed and the resulting structural inhomogeneity is characterized. Plasma generating catalysts also represent a new form of Radar Absorbing Material (RAM) for stealth and protection from radiation in which electromagnetic energy is dissipated by plasma generation and catalytic reactions. These catalytic RAMs can be expected to be more efficient in frequency independent microwave absorption.

show abstract

Section: Applications In Electromagnetic Radiation Protection and Catalytic Radar Absorption Materialsmentioning

confidence: 99%

Plasma Generating—Chemical Looping Catalyst Synthesis by Microwave Plasma Shock for Nitrogen Fixation from Air and Hydrogen Production from Water for Agriculture and Energy Technologies in Global Warming Prevention

Akay

2020

Catalysts

View full text Add to dashboard Cite

show abstract

“…Material jenis ini memiliki karakteristik nilai permeabilitas dan permitivitas yang baik sehingga dapat berinteraksi dengan gelombang elektromagnetik yang kompleks. Bahan smart-magnetik ini biasanya terdiri dari gabungan unsur logam tanah jarang dan logam transisi yang menghasilkan sifat magnetik yang dapat berfungsi sebagai bahan penyerap gelombang elektromagnetik (Winatapura et al 2020;Nimbore et al, 2006;Fisli et al, 2019;Mashadi et al, 2018). Garnet merupakan salah satu kandidat bahan smart-magnetik yang memiliki potensi luas untuk dimanfaatkan dalam berbagai aplikasi di bidang teknologi seperti bahan penyerap gelombang elektromagnetik, bahan sensor, dll ( Winatapura et al, 2020) Yttrium Iron Garnet (YIG) atau dapat ditulis dengan Y 3 Fe 5 O 12 merupakan tipe material garnet yang paling banyak digunakan untuk berbagai aplikasi di bidang teknologi diantaranya sebagai bahan frekuensi tinggi dan bahan penyerap gelombang elektromagnetik.…”

Section: Pendahuluanunclassified

Analisis Mikrostruktur Dan Sifat Magnetik Terhadap Pengaruh Suhu Sintering Pada Yttrium Iron Garnet Disintesis Menggunakan Metode Solgel

et al. 2021

View full text Add to dashboard Cite

Yttrium Iron Garnet (YIG), dengan formula umum Y 3 Fe 5 O 12 , merupakan kandidat material yang dapat digunakan sebagai komponen utama pada perangkat berbasis gelombang mikro. Untuk tujuan yang lebih khusus, YIG dapat dijadikan komponen utama dalam pembuatan bahan cat anti radar untuk perangkat alutsista militer. YIG memiliki karakteristik bahan yang sangat menunjang untuk tujuan ini seperti sifat magnetik dan elektromagnetik yang baik, konduktivitas termal yang baik, resistivitas listrik yang tinggi, dan nilai permittivitas yang tinggi. Pada penelitian ini, telah dilakukan proses pembuatan YIG menggunakan metode sol-gel auto combustion dengan variasi suhu sintering 900 ˚C, 1100 ˚C dan 1300 ˚C. Berdasarkan hasil analisis data X-ray diffractometer (XRD) menggunakan metode Rietveld dengan program General Structure Analysis System (GSAS), dapat diketahui bahwa fasa tunggal Y 3 Fe 5 O 12 terbentuk pada suhu 1300 ˚C. Hasil ini sesuai dengan analisis Thermogravimetry Analyzer (TGA) yang menunjukan bahwa pembentukan kristalit fasa Y 3 Fe 5 O 12 terjadi pada suhu 1300-1400 ˚C. Hasil data Fourier Transform Infra-Red (FTIR) menunjukkan terdapat puncak sistem tetrahedral garnet pada bilangan gelombang 670-560 cm -1 . Struktur morfologi hasil observasi sampel menggunakan Scanning Electron Microscope (SEM) menunjukkan bahwa pada suhu sintering 1300 ˚C diperoleh tingkat homogenitas ukuran partikel yang paling tinggi dengan ukuran antara 1-2 μm. Sifat kemagnetan menunjukan bahwa nilai saturasi magenetik tertinggi pada Y 3 Fe 5 O 12 diperoleh pada sintering 1300 ˚C yaitu 20.75 emu/g. Kata kunci: fasa, metode sol-gel, struktur morfologi, yttrium iron garnet

show abstract

“…Dielectric materials are applied in radar-wave absorption through dielectric polarization and relaxation loss. Nowadays, studies on dielectric wave-absorbing materials focus on barium titanate perovskites, barium ferric acid, and ferroelectric ceramics [ 11 , 12 , 13 , 14 ]. Magnetic radar-absorbing materials rely on magnetic loss to absorb and dissipate radar electromagnetic waves, which is competent of matching impedance as implemented in composite materials mainly composed of dielectric rubber matrix and functional fillers such as ferrite, carbonyl iron, ultrafine metal powder [ 15 , 16 , 17 , 18 ].…”

Section: Introductionmentioning

confidence: 99%

Electrical Insulation and Radar-Wave Absorption Performances of Nanoferrite/Liquid-Silicone-Rubber Composites

Sun

2022

IJMS

View full text Add to dashboard Cite

Novel radar-wave absorption nanocomposites are developed by filling the nanoscaled ferrites of strontium ferroxide (SrFe12O19) and carbonyl iron (CIP) individually into the highly flexible liquid silicone rubber (LSR) considered as dielectric matrix. Nanofiller dispersivities in SrFe12O19/LSR and CIP/LSR nanocomposites are characterized by scanning electronic microscopy, and the mechanical properties, electric conductivity, and DC dielectric-breakdown strength are tested to evaluate electrical insulation performances. Radar-wave absorption performances of SrFe12O19/LSR and CIP/LSR nanocomposites are investigated by measuring electromagnetic response characteristics and radar-wave reflectivity, indicating the high radar-wave absorption is dominantly derived from magnetic losses. Compared with pure LSR, the SrFe12O19/LSR and CIP/LSR nanocomposites represent acceptable reductions in mechanical tensile and dielectric-breakdown strengths, while rendering a substantial nonlinearity of electric conductivity under high electric fields. SrFe12O19/LSR nanocomposites provide high radar-wave absorption in the frequency band of 11~18 GHz, achieving a minimum reflection loss of −33 dB at 11 GHz with an effective absorption bandwidth of 10 GHz. In comparison, CIP/LSR nanocomposites realize a minimum reflection loss of −22 dB at 7 GHz and a remarkably larger effective absorption bandwidth of 3.9 GHz in the lower frequency range of 2~8 GHz. Radar-wave transmissions through SrFe12O19/LSR and CIP/LSR nanocomposites in single- and double-layered structures are analyzed with CST electromagnetic-field simulation software to calculate radar reflectivity for various absorbing-layer thicknesses. Dual-layer absorbing structures are modeled by specifying SrFe12O19/LSR and CIP/LSR nanocomposites, respectively, as match and loss layers, which are predicted to acquire a significant improvement in radar-wave absorption when the thicknesses of match and loss layers approach 1.75 mm and 0.25 mm, respectively.

show abstract

Iron oxide/titania composites for radar absorbing material (RAM) applications

Cited by 8 publications

References 28 publications

Plasma Generating—Chemical Looping Catalyst Synthesis by Microwave Plasma Shock for Nitrogen Fixation from Air and Hydrogen Production from Water for Agriculture and Energy Technologies in Global Warming Prevention

Plasma Generating—Chemical Looping Catalyst Synthesis by Microwave Plasma Shock for Nitrogen Fixation from Air and Hydrogen Production from Water for Agriculture and Energy Technologies in Global Warming Prevention

Analisis Mikrostruktur Dan Sifat Magnetik Terhadap Pengaruh Suhu Sintering Pada Yttrium Iron Garnet Disintesis Menggunakan Metode Solgel

Electrical Insulation and Radar-Wave Absorption Performances of Nanoferrite/Liquid-Silicone-Rubber Composites

Contact Info

Product

Resources

About