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Self-absorption Mössbauer investigation of neutron activated solid krypton /Brown, John Barclay January 1973 (has links)
No description available.
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The Use of Mossbauer Effect for the Study of Recoilless Rayleigh Scattering of Low-Energy Gamma Rays from Sodium ChlorideFowler, Eugene Franklin 08 1900 (has links)
Evidence that recoilless emission and absorption exist may be shown by an experiment in which the source gamma rays are allowed to pass through a suitable absorber to a detector.
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Mössbauer-effect studies of gadolinium and disprosium nuclei /Rork, Eugene W. January 1971 (has links)
No description available.
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Mössbauer study of the hyperfine magnetic field and electric field gradient at Fe sites in synthetic diamond.Govender, Nadaraj. January 1992 (has links)
Mossbauer Spectroscopy has been used to investigate the
site of Fe inclusions in a suite of synthetic diamonds (de
Beers MDAS). Information on the hyperfine magnetic fields
and electric field gradients at Fe sites in the diamond
grains were obtained from Mossbauer Spectroscopy of diamond
grains ranging in size from 25 to 250 um. The Fe inclusions
in these samples resulted from the synthesis of the diamond
grains in which Fe was used as a catalytic solvent. The
Mossbauer measurements were carried at room temperature
with a constant acceleration spectrometer operating in
transmission geometry.
The samples with the largest grain size of 180-250 um gave
a well defined six component magnetically split spectrum,
similar to the Zeeman split sextet obtained for natural
iron. As the grain sizes decreased the intensity of
the magnetically split components became greatly reduced
and a strong paramagnetic component appeared. At grain
sizes 105-45 um the spectra are dominated by a central
single line with some evidence of an asymmetric doublet.
For the finest grain size 38-25 um, the reappearance of
the six magnetic hyperfine splitting components together
with the strong central single paramagnetic component was
observed.
The change in the Mossbauer patterns observed with decreasing
grain size suggest that a rapid phase transition of the
Fe inclusions from ferromagnetic to superparamagnetic
takes place.
The analysis of Mossbauer spectra yielded a value of the
hyperfine magnetic field of Bhf = -32.4(4) T and an
electric field gradient in the range of Vzz = 1.4(4) 1.8(
7) X 10'8 V.cm- 2 at the site of the probe s7Fe
nucleus. These values compare favourably with other
measurements. / Thesis (M.Sc.)-University of Durban-Westville, 1992.
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Synthesis and characterization of some tetradentate macrocyclic complexes of iron /Merrell, Philip Hayden,1944- January 1971 (has links)
No description available.
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A Mössbauer effect study of the high temperature oxidation of 302 stainless steel /Van Keuren, John Conrad January 1972 (has links)
No description available.
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The design and construction of a constant acceleration drive system for Mössbauer experimentsRussell, James Donald 01 January 1970 (has links)
An excited nucleus may undergo a transition to its ground state by the emission of a gamma ray. The nucleus, if free to do so, will recoil and take some of the transition energy as recoil energy leaving less energy for the emitted gamma ray. This gamma ray does not have enough energy to excite a similar nucleus and will, therefore, not by resonantly absorbed due to the fact that the natural linewidth of the gamma ray is so much smaller than the energy taken by the emitting atom and the similar energy needed by the absorbing atom.
In 1958 a new effort in the emission and absorption processes of low energy gamma rays was announced by Rudolph L. Mössbauer. His discovery was made while he was doing graduate work at Heidelberg, Germany. Since that time this effect, not known as the Mössbauer effect, has been studied and confirmed in many laboratories. By 1961 the significance and usefulness of this effect was so widely recognized that Rudolph Mössbauer was awarded the Nobel Prize.
The new effect involves recoil free emission and resonant absorption of low energy gamma rays by atoms tightly bound in a crystalline lattice. The characteristics of the Mössbauer effect have led to the feasibility of studies previously not possible in nuclear-. Solid taste-, and atomic physics; chemistry; and biology.
It is the purpose of this research project to design and build a Mössbauer effect apparatus.
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Mossbauer, Magnetization And Electrical Transport Studies On Iron Nanoparticles Embedded In The Carbon MatrixSajitha, E P 03 1900 (has links)
This thesis deals with the studies of magnetization and electrical transport properties of iron nanoparticles embedded in the carbon matrix. The synthesis and characteristics of the nanoparticle systems studied, are also presented.
Carbon-iron (C-Fe) based systems are of growing interest due to their improved magnetic properties as well as in their potential application as sensors, catalysts, and in various other applications. In particular, nanocomposites of iron carbide, such as the cementite phase Fe3C, are further suited to diverse technological exploitations due to their enhanced mechanical properties and importance in ferrous metallurgy. The recent interest in magnetic nanostructures lies in the emergence of novel magnetic and transport properties with the reduction of size. As the dimension approaches the nanometer length scale, interesting size-dependent properties like enhanced coercivity, enhanced magnetic moment, super paramagnetism etc. are seen. Thermal assisted chemical vapour deposition (CVD) is used to decompose and chemically react the introduced precursors, maleic anhydride and ferrocene. This method provides relative size control over the individual particles by varying C/Fe concentration in precursors and the pyrolysis temperature during the co-deposition process. Ferrocene has been used actively for the production of nanoparticle composites and in the production of nanostructured carbon. The temperature of preparation, reaction rate, and the time duration of annealing directly effects the nanoparticle compositions. The catalytic effect of transitional elements are well documented in literature. This thesis is an effort to understand the growth of ferromagnetic nanocrystallites in carbon matrix, which undergo partial graphitization due to the catalytic effect of transitional elements. The effect of transitional metal on the degree of graphitization of the carbon matrix, morphology of the nanoparticle and the carbon matrix are studied. The phase of the ferromagnetic iron nanoparticles and the structural investigation forms part of the study. Here X-Ray diffraction (XRD) is employed to study the presence of different phases of iron in the partially graphitized carbon matrix. The matrix morphology and the particle size distribution were studied using Transmission Electron Microscopy (TEM) and High-Resolution TEM (HRTEM). The ferromagnetic states of the iron nanoparticles are investigated using Mossbauer spectroscopy. The results from these studies, are used to correlated the macroscopic properties to the microscopic studies. The enhanced magnetization, coercivity and the temperature dependence of the magnetization value is understood within the frame work of ferromagnetic Bloch law and surrounding carbon spins. The logarithmic temperature dependence of conductivity of the nanoparticle composites is analyzed in the framework of interference models as well as the many-body Kondo interaction effect.
This thesis contains seven chapters:
In chapter 1, a brief introduction to mesoscopic physics and the size-dependent phenomenon are given. Special attention is paid to magnetic nanoparticle and its composites, and the various finite-size effects exhibited by them are discussed in detail. The relevance of carbon matrix and its importance on the growth of iron nanoparticles with high thermal stability is also discussed. The ballistic and diffusive transport phenomena observed in low-dimensional systems are briefly discussed. The interplay of localization and various interaction effects at nanoscale are examined. In disordered metals the low temperature conductivity is dominated by the interference effects. A brief discussion is made on the conductivity in disorder systems, with the presence of magnetic impurities and how the classic many-body Kondo problem, is effected by various interactions.
Chapter 2, mainly deals with the experimental techniques employed in the thesis. The thermal-assisted chemical vapour deposition setup used to decompose and chemically react the introduced organometallic precursors, for the preparation of C:Fe composites are discussed and its advantage over other preparation methods are emphasized. The method is optimized to provide relative size control over the nanoparticles composites and the phase compositions by varying C/Fe concentration in precursors and the pyrolysis temperature, during the co-deposition process. The various structural characterization tools used in the present study are summed up concisely in this chapter. The SQUID magnetometer system; its working principle and the various protocol used for the low temperature magnetization measurements are elaborated. Further, details regarding superconducting magnetic cryostat, utilized for the low temperature conductivity and magneto resistance measurements, are discussed. Films of C:Fe composites are grown on substrates to study the effect of disorder and sample size on the conductivity behaviour of the composites at low temperature.
Chapter 3, presents the outcome of the structural studies undertaken on the C:Fe composites using XRD, TEM, and HRTEM. X-ray diffraction measurements performed on the powder composites reveal that, in addition to the presence of sharp diffraction peak from nanographite, peaks corresponding to the different phases of Fe are also seen. The effect of preparation temperature on the matrix morphology is revealed from the estimation of degree of graphitization. Iron carbide is the predominant phase in all the prepared composites. For low concentration of iron, iron carbide alone is present but as the percentage of iron in the samples increased other phases of iron are also seen. The microscopic studies on the prepared compositions revealed the presence of nanosized iron particles well embedded in the partially graphitized matrix. Here again, with the increase in iron percentage, agglomeration of ferromagnetic nanoparticles are seen. The kinetics of the particle growth and the filamentous nature of the carbon matrix are also discussed.
Mossbauer investigation on C:Fe composites are presented in chapter 4. The measurements revealed the iron atom occupation in the crystal lattice. In the lower Fe concentration samples, the room temperature Mossbauer spectrum revealed the presence of sextet from Fe3C (cementite) phase. As the percentage of iron increased, sextet from α-Fe, Fe3O4 are also seen in some of the prepared compositions. Effect of carbon atoms on the structure and magnetic properties of the nanoparticle species are obvious from the isomer shift measurements.
Chapter 5 comprises of the various magnetic properties and interactions present in small particle system such as magnetic anisotropy, coercivity, enhanced magnetization, inter-and intra-particle interactions etc. Magnetization measurements carried out in SQUID magnetometer on the C:Fe composites and carbon flakes (prepared from organic precursor, maleic anhydride alone) are presented. The enhanced magnetic properties of the nanoparticle assembly is discussed in detail. The hysteresis loops trace, with a finite coercivity at room temperature, indicates the ferromagnetic nature of the samples. At room temperature the magnetization value saturates at high magnetic field, indicating negligible effect from super paramagnetic particles on the hysteresis loop. The squareness ratio, saturation magnetization, coercivity and remanence magnetization values are analyzed in detail. The temperature dependence of magnetization shows a combination of Bloch law and Curie-Weiss behaviour, consistent with the picture of ferromagnetic clusters embedded in a carbon matrix. The Bloch’s constant is found to be larger by an order of magnitude compared to the bulk value, implying stronger dependence of magnetization with temperature. Effort to understand the enhanced magnetic moment in the light of magnetism in carbon was taken up. The proximity effect of ferromagnetic metal on the carbon and the hydrogen bonding with the dangling bonds, both studied in detail in literature, in connection with the induced magnetic moments in carbon, are invoked.
In chapter 6, the different conductivity regimes are identified, to study the conduction mechanisms in composites and films. For the transport measurements pelletized samples are used for the resistivity and magneto resistance measurements. The conductivity data are analyzed based on the interplay of localization and Kondo effect in the ferromagnetic disordered system. In order to understand the effect of disorder and thickness on the Kondo problem, transport measurements are carried on thin films of C:Fe composites grown on quartz and alumina substrate. Disorder induced metal-insulator transition is observed in the prepared samples. The zero-field conductivity and magneto resistance data is fitted to variable range hopping (VRH) in strong localization regime.
Chapter 7 summarizes the thesis and presents some perspectives for the future.
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