Atomistic modeling to predict and improve the strength of doped Sn-Cu solder interfaces

Michael Woodcox, Manuel Smeu
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引用次数: 1

Abstract

The reliability of solder joints depends upon the strength of the interface where two materials are joined. The strengthening of solder joints has been routinely achieved via doping with other elements, though this is not yet well understood at a fundamental level, and typically accomplished by trial and error. In the present work, we have used atomistic modeling based on density functional theory (DFT) and ab initio molecular dynamics (AIMD) to study the mechanical strength of the Sn-Cu interface under various conditions. We have investigated the cleavage energy (CE) of the Sn-Cu interface, and how it changes with various dopants (Ag, Au, Bi, Cu, Ni, Zn) to determine the benefit (or detriment) to the strength of this simulated solder joint. We have also tested multiple faces of Sn ([001], [100] and [110]) as potential interfaces with Cu. Our simulations show that each of the dopants considered, except for Bi, increases the strength of the interface. In all our constructed Sn-Bi interfaces, a single atomic layer of Sn atoms deposits on the Cu and binds strongly to it. The weakest point of the interface is located between the deposited Sn layer and the remaining bulk Sn. For the undoped [001] Sn-Cu system, the cleavage energy between the Sn and Cu layers is 1.63 J/m2, whereas the cleavage energy between the deposited layer of Sn and the remaining Sn bulk is considerably lower: 0.54 J/m2; this is likely the location of joint failure, and the focus of our investigation. We observed this trend in each interface that we studied. As expected, the strength of the Sn-Cu interface can be modified with dopants; the CE of the weakest point can be increased (strengthening it) by 0.1–0.2 J/m2 when doping it with Ag, Au, Cu, Ni and Zn, though Bi results in a decrease (weakening it) by 0.15 J/m2. As a complementary method for investigating this interface, we have used AIMD to simulate a mechanically controlled break junction (MCBJ) of the solder interface by gradually increasing the separation between the two ends of the simulated junction. The process is continued until the junction completely breaks, yielding an energy vs. distance curve, which provides information about the strength of the solder joint that is similar to a stress-strain curve. We observe that, as the Sn is moved away from the Cu, there is a relatively steady increase in energy until the system begins to separate. From this separation point, the energy curve plateaus as the interaction between the two halves of the system vanishes. The location of the breaking point is in excellent accordance with our CE calculations; there is also a correlation between the CE and the amount of distance that the system must be stretched before reaching the breaking point. Furthermore, we have adapted the MCBJ method in AIMD to simulate shearing of the Sn-Cu interface. In these simulations, as opposed to moving Sn atoms away from the Cu atoms perpendicularly to the interface, we are sliding the Sn atoms laterally across the interface relative to the Cu atoms. The deposited Sn layer remains strongly bonded to the Cu surface, with most of the shearing occurring inside the bulk Sn region. The first principles nature of the methods employed makes them highly transferable and applicable to any chemical composition. These atomistic simulations provide valuable insights that can be used to design stronger solder joints based on physical understanding.
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原子模型预测和提高掺杂锡铜焊料界面的强度
焊点的可靠性取决于两种材料连接界面的强度。焊点的强化通常是通过掺杂其他元素来实现的,尽管这在基本层面上还没有得到很好的理解,并且通常是通过反复试验来完成的。在本工作中,我们采用基于密度泛函理论(DFT)和从头算分子动力学(AIMD)的原子模型研究了不同条件下Sn-Cu界面的机械强度。我们研究了Sn-Cu界面的解理能(CE),以及它随不同掺杂剂(Ag, Au, Bi, Cu, Ni, Zn)的变化,以确定对模拟焊点强度的好处(或损害)。我们还测试了Sn([001],[100]和[110])的多个面作为与Cu的潜在界面。我们的模拟表明,除了Bi之外,所考虑的每一种掺杂剂都增加了界面的强度。在我们构建的所有锡铋界面中,锡原子的单原子层沉积在Cu上并与Cu强结合。界面的最薄弱点位于沉积锡层和残余锡体之间。对于未掺杂的[001]Sn-Cu体系,Sn层与Cu层之间的解理能为1.63 J/m2,而Sn沉积层与剩余Sn块体之间的解理能较低,为0.54 J/m2;这可能是关节故障的位置,也是我们调查的重点。我们在研究的每个界面中都观察到了这种趋势。正如预期的那样,掺杂剂可以改变Sn-Cu界面的强度;掺入Ag、Au、Cu、Ni和Zn可使最薄点的CE提高(增强)0.1 ~ 0.2 J/m2,而掺入Bi则使最薄点的CE降低(减弱)0.15 J/m2。作为研究该界面的补充方法,我们使用AIMD通过逐渐增加模拟界面两端之间的距离来模拟焊接界面的机械控制断开结(MCBJ)。这个过程一直持续到连接点完全断裂,产生能量与距离曲线,该曲线提供了类似于应力-应变曲线的焊点强度信息。我们观察到,当Sn远离Cu时,能量会相对稳定地增加,直到系统开始分离。从这个分离点开始,随着系统两半之间的相互作用消失,能量曲线趋于平稳。断点的位置与我们的CE计算非常吻合;在达到断裂点之前,CE和系统必须拉伸的距离之间也存在相关性。此外,我们还采用了AIMD中的MCBJ方法来模拟Sn-Cu界面的剪切。在这些模拟中,与将Sn原子从Cu原子垂直移动到界面相反,我们将Sn原子相对于Cu原子横向滑动穿过界面。沉积的锡层与Cu表面保持强烈的结合,大部分剪切发生在大块锡区域内。所采用的方法的第一原则性质使它们高度可转移并适用于任何化学成分。这些原子模拟提供了有价值的见解,可用于基于物理理解设计更强的焊点。
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