The influence of annealing in strongly reducing atmosphere on the magnetic properties of hexagonal BaTiO3 + 0.04 BaO + x/2 Co2O3 (0.0025 aecurrency sign x aecurrency sign 0.10) ceramics was investigated. The samples air-sintered at 1673 K were subsequently tempered at 1473 K in H-2/Ar stream. While the as-sintered samples exclusively exhibit paramagnetic behavior, the annealed samples show distinct saturation in the field dependence of the magnetization at 300 K measured in the range between -90 and 90 kOe. Besides, the field dependence of the magnetization is hysteretic with coercive fields in the order of 100 Oe. Both properties point to ferromagnetic regions which were identified as precipitations of metallic cobalt by TEM and EDX. The cobalt precipitations were exclusively found in tetragonal grains which were completely Co-free outside the precipitations. Obviously, these tetragonal grains were formed during the annealing process when the Co content of the formerly hexagonal grains was concentrated into metallic Co particles by diffusion processes. Hence, the Co-free matrix of the grains transformed into the cubic phase which is the equilibrium phase of undoped BaTiO3 at the annealing temperature 1473 K and during cooling to room temperature into tetragonal phase. The size of the metallic precipitations ranges from about 20 to 100 nm. A reduction both of the annealing temperature to 1373 K and of the annealing time from 120 to 30 min did not change the minimum particle size, but now, the very rare precipitations only occurred at triple points or grain boundaries. EPR measurements confirmed the occurrence of the ferromagnetic precipitations. While at 300 K, the as-sintered samples did not show any Co EPR signal, the annealing in strongly reducing atmosphere caused a strong and broad line which is attributed to the ferromagnetic resonance signal of the Co precipitations. The investigations were extended for the dopants, iron or nickel, with a nominal sample composition of BaTiO3 + 0.04 BaO + 0.01 Fe2O3 or 0.02 NiO, respectively. The field dependence of the magnetization as well as the EPR spectra showed similar results compared to the case of Co-doped samples. Hence, also in Fe- or Ni-doped BaTiO3 ceramics, ferromagnetic properties are caused by annealing in strongly reducing atmosphere.
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机译:研究了在强还原性气氛中退火对六角形BaTiO3 + 0.04 BaO + x / 2 Co2O3(0.0025出现率x出现率0.10)陶瓷磁性能的影响。在1673 K空气烧结的样品随后在H-2 / Ar流中回火到1473K。烧结后的样品仅表现出顺磁性能,而退火后的样品在-90至90 kOe范围内测得的300 K时的磁化强度场依赖性表现出明显的饱和度。此外,磁化的场依赖性在矫顽场为100Oe量级时是滞后的。两种性质都指向铁磁区域,该区域被TEM和EDX鉴定为金属钴的沉淀。仅在四方晶中发现了钴沉淀物,这些沉淀物在沉淀物之外完全不含钴。显然,这些四方晶晶粒是在退火过程中形成的,当时原六方晶晶粒的Co含量通过扩散过程集中到金属Co颗粒中。因此,晶粒的无钴基体在退火温度1473 K以及冷却至室温的过程中转变为立方相,这是未掺杂BaTiO3的平衡相,并且在冷却至室温时变成四方相。金属沉淀物的尺寸为约20至100nm。将退火温度降低到1373 K和将退火时间从120降低到30分钟都没有改变最小粒径,但是现在,非常罕见的沉淀仅出现在三点或晶界处。 EPR测量结果证实了铁磁沉淀的发生。在300 K时,烧结后的样品未显示任何Co EPR信号,但在强还原性气氛中进行的退火产生了一条粗而粗的线,这归因于Co沉淀的铁磁共振信号。研究扩展到了掺杂剂,铁或镍,标称样品成分分别为BaTiO3 + 0.04 BaO + 0.01 Fe2O3或0.02 NiO。与共掺杂样品的情况相比,磁化强度的场依赖性以及EPR光谱显示出相似的结果。因此,在Fe或Ni掺杂的BaTiO 3陶瓷中,铁磁性质也是由在强还原性气氛中的退火引起的。
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