物理化学学报
物理化學學報
물이화학학보
ACTA PHYSICO-CHIMICA SINICA
2015年
2期
253-260
,共8页
第一性原理%钛硅化合物%化学键%韧/脆性%电子结构
第一性原理%鈦硅化閤物%化學鍵%韌/脆性%電子結構
제일성원리%태규화합물%화학건%인/취성%전자결구
First-principles%Titanium-silicon compound%Chemical bond%Ductile/brittle behavior%Electronic structure
采用基于密度泛函理论(DFT)的第一性原理赝势平面波方法,计算了不同数量的Al原子代位六方D88结构的Ti5Si3晶体中的Si原子后的形成能(ΔHf)、结合能(ΔEcoh)、体模量(B)、剪切模量(G)、泊松比(ν)、Cauchy压力参数(C12―C66,C13―C44)、金属性(fm)和派-纳力(τP-N)等参数,表征了Al合金化对D88-Ti5Si3的结构稳定性和力学性质的影响。结合态密度、差分电荷密度图和Mul iken布居等电子结构分析,揭示了Al原子的添加量对D88-Ti5Si3的韧/脆性变化的影响机制。研究表明, D88-Ti5Si3晶体中强的Ti6g―Si6g方向共价键是导致其室温脆性的主要原因。当1个和2个Al原子占据D88-Ti5Si3晶体中Si6g位置时,形成了键强较弱的Al6g―Si6g键、Ti6g―Al6g键和Ti4d―Al6g键,同时降低了D88-Ti5Si3中Ti6g―Si6g键的强度和数量,从而提高了D88-Ti5Si3的韧性。当D88-Ti5Si3晶体中Si6g位置被3个Al原子所占时, Al6g―Si6g键消失,而Ti6g―Si6g键的强度增加,导致Ti5(Si1-xAlx)3的脆性增加。
採用基于密度汎函理論(DFT)的第一性原理贗勢平麵波方法,計算瞭不同數量的Al原子代位六方D88結構的Ti5Si3晶體中的Si原子後的形成能(ΔHf)、結閤能(ΔEcoh)、體模量(B)、剪切模量(G)、泊鬆比(ν)、Cauchy壓力參數(C12―C66,C13―C44)、金屬性(fm)和派-納力(τP-N)等參數,錶徵瞭Al閤金化對D88-Ti5Si3的結構穩定性和力學性質的影響。結閤態密度、差分電荷密度圖和Mul iken佈居等電子結構分析,揭示瞭Al原子的添加量對D88-Ti5Si3的韌/脆性變化的影響機製。研究錶明, D88-Ti5Si3晶體中彊的Ti6g―Si6g方嚮共價鍵是導緻其室溫脆性的主要原因。噹1箇和2箇Al原子佔據D88-Ti5Si3晶體中Si6g位置時,形成瞭鍵彊較弱的Al6g―Si6g鍵、Ti6g―Al6g鍵和Ti4d―Al6g鍵,同時降低瞭D88-Ti5Si3中Ti6g―Si6g鍵的彊度和數量,從而提高瞭D88-Ti5Si3的韌性。噹D88-Ti5Si3晶體中Si6g位置被3箇Al原子所佔時, Al6g―Si6g鍵消失,而Ti6g―Si6g鍵的彊度增加,導緻Ti5(Si1-xAlx)3的脆性增加。
채용기우밀도범함이론(DFT)적제일성원리안세평면파방법,계산료불동수량적Al원자대위륙방D88결구적Ti5Si3정체중적Si원자후적형성능(ΔHf)、결합능(ΔEcoh)、체모량(B)、전절모량(G)、박송비(ν)、Cauchy압력삼수(C12―C66,C13―C44)、금속성(fm)화파-납력(τP-N)등삼수,표정료Al합금화대D88-Ti5Si3적결구은정성화역학성질적영향。결합태밀도、차분전하밀도도화Mul iken포거등전자결구분석,게시료Al원자적첨가량대D88-Ti5Si3적인/취성변화적영향궤제。연구표명, D88-Ti5Si3정체중강적Ti6g―Si6g방향공개건시도치기실온취성적주요원인。당1개화2개Al원자점거D88-Ti5Si3정체중Si6g위치시,형성료건강교약적Al6g―Si6g건、Ti6g―Al6g건화Ti4d―Al6g건,동시강저료D88-Ti5Si3중Ti6g―Si6g건적강도화수량,종이제고료D88-Ti5Si3적인성。당D88-Ti5Si3정체중Si6g위치피3개Al원자소점시, Al6g―Si6g건소실,이Ti6g―Si6g건적강도증가,도치Ti5(Si1-xAlx)3적취성증가。
The influence of the substitution of Al for Si on the structural stability and mechanical properties of D88-Ti5Si3 was determined using first-principles pseudopotential plane-wave methods based on density functional theory. Several parameters including formation enthalpies ((ΔHf), cohesive energies (ΔEcoh), bulk modulus (B), shear modulus (G), Poisson′s ratio (ν), Cauchy′s pressure (C12-C66,C13-C44), metal icity (fm), and Peierls stress (τP-N) were calculated. To develop a better understanding of the effects of substitutional Al al oying on the toughness/brittleness of D88-Ti5Si3 from an electronic structure point of view the density of states, charge density differences and Mul iken population were determined. The results show that the intrinsic brittleness of D88-Ti5Si3 comes from strong covalent bonding between Ti6g and Si6g. When one or two Ti atoms occupy Si sites in the D88-Ti5Si3 crystal the intensity of covalent bonding between Ti6g and Si6g is reduced and the metal icity increases. This is accompanied by the presence of low intensity Al6g―Si6g, Ti6g―Al6g, and Ti4d―Al6g bonds. However, when three Ti atoms occupy Si sites in the D88-Ti5Si3 crystal the Al6g―Si6g bonds disappear and the intensity of covalent bonding between Ti6g and Si6g increases leading to an increase in brittleness.
