مقاصد الإسلام في تحقيق السلام

This research focused on highlighting the purposes of Islam in achieving peace. This paper explains how Islam is the religion of peace and security for the worlds. Its provisions, legislations and purposes ensured all mankind the right to security and security of all kinds: Psychological security, financial security, social security and other types of security which ensure that humanity can live in peace. This is without any kind of these securities being subjected to any slight aggression, sabotage, deprivation or injustice, and if any of that happens then it would be a manifestation of violence and terrorism that is neither accepted nor recognized by Islam which is the religion of peace. The research has shown that Islam has preceded all international laws and norms with respect to the legalization of human rights in peace and war times alike and the sanctioning of those who violate them in this world and in the Hereafter. This is done with supporting evidence from the Quran, the Sunnah, the work of the leaders of Muslim Ummah throughout the Islamic centuries, and the testimonies of non-Muslims who have lived the mercy of Islam and come to know the observance of Islam of human rights. The aims of the research are: To demonstrate the legitimate purposes that Islam has brought to preserve human dignity and security. To show the precedence and superiority of Islamic law in the field of human rights care. To highlight the rich Islamic heritage of human values and civilization through the rules of humanitarian dealing in Islamic jurisprudence in war and peace, and the contributions of the purposes of the Sharia in the development of rules for the preservation of rights and freedoms.

Ion Implantation and Doping of Rare Earth Metals to Tailor the Multiferroic Properties of Bifeo3

Multiferroic Bismuth ferrite BiFeO3(BFO) is one of the rare compounds which gained huge attention of researchers in last few years due to the coexistence of magnetism and ferroelectricity at room temperature. Its both antiferromagnetic and ferroelectric transition temperatures at well above the room temperature which makes it a more potential candidate for device applications. In device applications, both bulk and thin films studies have great importance. In current research work, BFO materials have been investigated in both forms (bulk and thin films). The work has been divided into three parts: The first part which is very important is based on the successful synthesis of pure BFO phase and rare earth (Ho and Dy) doped BFO ceramic by solid state reaction method; The second part is the fabrication of Ho doped thin films using the pulsed laser deposition technique; In the third and the last part, different types of ions (heavy, paramagnetic, ferromagnetic and diamagnetic) are implanted on pure and Dy doped BFO ceramic. Pure and rare-earth doped (Ho and Dy) BiFeO3 have been prepared by conventional solid state reaction method using Bi2O3, Fe2O3, Ho2O3 and Dy2O3 powders as starting precursor. All oxides have been mixed with an appropriate stoichiometric ratio and then grounded well in acetone medium and calcined. The calcined powder was pressed into pellets of 2.54 cm diameter and 3-4 mm thickness using PVA as a binder with the help of a hydraulic pelletizer at an applied pressure of 98 kPa. Finally, the pellets were sintered at 850 °C for 2 hours. These pellets have been used for the thin films fabrication and are used as a target for ion implantation. The thin films of Bi1-xHoxFeO3 (with x=0, 0.05, 0.10, 0.15 and 0.20) have been successfully grown on Si (100) substrates using pulsed laser deposition and the effect of Ho doping on the crystal structure, dielectric and magnetic properties are studied by X-ray diffraction, field emission scanning electron microscopy (FE-SEM), atomic force microscopy (AFM), X-ray photoemission spectroscopy (XPS), impedance analyzer and Vibrating sample magnetometer (VSM). The structural change and enhanced magnetic properties have been observed after Ho doping in BFO thin films. Ho doped thin films have also shown good dielectric behavior as compared to un-doped BiFeO3. The enhancement of these properties due to Ho doping is discussed along with their relevance in designing multiferroic materials based on Bi1 xHoxFeO3 films for magnetic field sensors, multiple-state memories and spintronic elements. Implantation of diamagnetic (Au+, As+, Ge+), paramagnetic (Y+) and ferromagnetic (Co+) ions induced modification in structural and multiferroic properties of pure phase BiFeO3 (BFO) ceramics. BFO samples are implanted by 500 keV ions of Au+, As+, Ge+, Y+ and Co+ at constant ion fluence 3×1012 ions/cm2. The nuclear and electronic energy losses at 500 keV Au+, As+, Ge+, Y+ and Co+ ions on target BFO have been calculated by software STOPPING RANGE OF IONS IN MATTER (SRIM). Effect of different ions implantation is explained in terms of structural change coupled with amorphization/ recrystallization due to ion implantation probed through XRD, SEM, EDX and XPS. XRD patterns show broad diffuse contributions due to amorphization in implanted samples. The Rietveld refinement results indicate the phase distortion in irradiated samples and phase transition from space group R3c to R3m by the As+ ions implantation, which is revealed by Rietveld refinement. X-ray photoemission spectroscopy was used to identify the chemical bonding, valence band and core levels of implanted BFO samples. The ferroelectric behavior of BFO ceramics varies with different implanted ions which might be understood in terms of oxygen vacancy, the displacement of Fe3+ ions, lattice distortion and lattice phase transition. Room temperature M–H hysteresis measurements reveal that magnetization varied due to the structural distortion and partial destruction of a spin cycloid, which is caused by ion implantation in BiFeO3 ceramics. Furthermore, Y+ ions beam of 500 keV energy irradiated on Bi1-xDyxFeO3 xxi (xDBFO) where (x= 0.00, 0.05, 0.10, 0.15 and 0.20) at a constant fluence 3×1012 ions/cm2 have been investigated. Study of basic crystal parameters using the X-ray diffraction technique of the irradiated samples suggests that all the materials are polycrystalline and indexed in the distorted-perovskite (rhombohedral) structure which was supplemented and supported by Rietveld refinement.The scanning electron micrograph of the compounds showed (i) the uniform distribution of grains on the sample surface with high density and (ii) reduction in grain size on increasing Dy3+ content and Y+ ions irradiation in BiFeO3 (BFO). Ferroelectric and ferromagnetic loops have been observed in the Y+ implanted xDBFO (x=0.00, 0.05, 0.10, 0.15 and 0.20) samples at room temperature which indicate that ferroelectric and ferromagnetic ordering coexist in the ceramics at room temperature. The polarization Ps is increased up to 10.50 μC/cm2 by increasing Dy contents at x=0.15. The Ms value is also enhanced up to 2.329 emu/g by 15% doping of Dy in BFO.