Sm-16.7wt%Co alloy powders were prepared by high energy ball milling under the conditions of various milling time and the content of process control agent (PCA), and their microstructure and magnetic properties were investigated to establish optimum processing conditions. The initial powders employed showed irregular shape and had a size ranging from 5 to . After milling for 5 h, the shape of powders changed to round shape and their mean powder size was approximately , which consisted of the agglomerated nano-sized particles with 15 nm in diameter. The coercivity was reduced with increasing the milling time, whereas the saturation magnetization increased. As the content of PCA increased, the powder size minutely decreased to approximately at the PCA content of 10 wt%. The XRD patterns showed that the main diffraction peaks disappeared apparently after milling, indicating the formation of amorphous structure. The measured values of coercivity were almost unchanged with increasing the content of PCA.

TiCuNiAl quaternary amorphous alloy was prepared by high-energy ball milling process. A complete amorphization was confirmed for the composition of TiCuNiAl after milling for 30hrs. Differential scanning calorimetry showed a large super-cooled liquid region (T = T T, T and T: glass transition and crystallization onset temperatures, respectively) of 80 K. Prepared amorphous powders of TiCuNiAl were consolidated by spark-plasma sintering. Densification behavior and microstructure changes were investigated. Samples sintered at higher temperature of 713 K had a nearly full density. With increasing the sintering temperature, the compressive strength increased to fracture strength of 756 MPa in the case of sintering at 733 K, which showed a 'transparticle' fracture. The samples sintered at above 693 K showed the elongation maximum above 2%.

doped (GDC) solid solutions have been considered as a promising materials for electrolytes in intermediate-temperature solid oxide fuel cells. In this study, the nano-sized GDC powder with average panicle size of 69nm was prepared by a high energy ball milling process and its sintering behavior was investigated. Heat-treatment at of nano-sized GDC powder mixture led to GDC solid-solution. The enhanced densification over 96% of relative density was obtained after sintering at for 2h. It was found that the sinterability of GDC powder could be significantly improved by the introduction of a high energy ball milling process

Study about the feasibility and effect of high-energy ball milling on a specific Mg alloy under protection medium of alcohol was presented via comparing with conventional vacuum milling. More fine particles with wider powder size distribution but more irregular shape were shown of the powder milled under alcohol. No obvious oxide was revealed from the two kinds of Mg alloy powders with limited milling time. And since slip induced in a preferential direction, the (002) texture was formed in the Mg alloy powders at the initial stage of alcohol milling. More O and Fe contaminants were introduced into the powders milled under alcohol according to the EDS analysis.

The present work studies the influence of high-energy milling (HEM) and sintering cycle of Ti and Al powders on the obtainment of TiAl. This study shows that HEM modifies the diffusion processes during the sintering stage. The samples were obtained by cold uniaxial and isostatic pressing, pre-sintered at different temperatures, and heated up to the sintering temperature. This study also shows the effect of powder additions processed by HEM on the sintering behavior of elemental Ti and Al powders.

The structural and magnetic properties of nanostructued alloy powders were investigated. Commercial alloy powders (Hoeganaes Co., USA) with purities were used to fabricate the nanostructure Fe-Si alloy powders through a high-energy ball milling process. The alloy powders were fabricated at 400 rpm for 50 h, resulting in an average grain size of 16 nm. The nanostructured powder was characterized by fcc and hcp phases and exhibited a minimum coercivity of approximately 50 Oe

Nanocrystalline powders of (x=0.45-0.6) have been synthesized by mechanochemical reaction at room temperature using high-energy ball milling from mixtures of Mn, Fe, P, and As Powders. It has been found that a mechanically induced self-propagating reaction (MSR) occurs within 2 hours of milling and it produces very fine polycrystalline powder having a hexagonal structure. Further milling up to 24 hours did not change the crystalline and average particle sizes or the phase composition of the milling product. When x is 0.65, no reaction among the reactants has been observed even after 24 hours of milling. As the P content decreases in , the incubation time for the MSR has increased and the lattice constants in both a and c axes have changed

Elemental powders are used in high energy milling processes for the synthesis of new compounds. The low temperature solid state reactions during milling in inert gas atmosphere may result in intermetallic phases, carbides, nitrides or silicides with a nanocrystalline structure. To obtain dense materials from the powders a pressure assisted densification is necessary. On the other side the defect-rich microstructure can be used for activated sintering of elemental powder mixtures to obtain dense bodies by pressureless sintering. Results are discussed for nanocrystalline cermet systems and for the sintering of aluminides and silicides

활석은 T-O-T 구조의 함수 마그네슘 층상규산염 광물로서, 화학적 안정성과 흡착성 등의 특성을 가지고 있어 다양한 산업분야에서 첨가제, 코팅제 등으로 활용되어 왔다. 최근 나노 복합체의 안정성 향상을 위한 첨가제로서 활석 나노입자가 각광받고 있다. 본 연구에서는 고에너지 볼 밀을 이용하여 기계적인 방법으로 활석 나노입자를 형성하고, 분쇄시간에 따른 입자크기 및 결정도의 변화를 알아보고자 하였다. X-선 회절 분석 결과, 분쇄가 진행됨에 따라 활석의 피크 폭이 점진적으로 증가하여720분 분쇄 후, 활석은 비정질에 가까운 X-선 회절패턴을 보여준다. 레이저회절 입도 분석 결과, 약12 μm이었던 활석의 입도는 분쇄가 진행됨에 따라 약 0.45 μm까지 감소하였으나, 120분 이상 분쇄를진행하여도 뚜렷한 입도의 감소가 관찰되지 않았다. 반면, BET 비표면적은 분쇄 720분까지 꾸준히 증가하여, 분쇄에 따른 입도 또는 형태의 변화가 지속적으로 일어남을 지시한다. 주사전자현미경 및 투과전자현미경 관찰 결과, 720분 분쇄 후 약 100~300 nm 내외의 층상형 입자들이 마이크로 스케일의응집체로 존재함을 확인하였다. 이와 같은 결과는 분쇄시간이 증가함에 따라 활석의 입자크기 및 형태는 지속적으로 변화하지만, 나노입자의 특성상 재응집이 일어나 마이크로 크기의 응집체를 형성하고 있음을 지시한다. 또한 활석의 분쇄에서 판의 크기, 즉 a축, b축 방향의 길이는 감소 한계가 존재하며, 분쇄가 진행될수록 판의 두께, 즉 c축 방향의 길이 감소가 주된 분쇄 메커니즘으로 생각된다. 본연구의 결과는 나노 활석의 형성 메커니즘에 대한 이해를 고양할 수 있을 것으로 기대된다.