Nanostage Alloying of Metals in Liquid Phase

Advances in Chemical Engineering and Science Pub Date : 2021-01-29 DOI:10.4236/ACES.2021.111008

D. Roy, T. Pal

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Abstract

Alloying of metals is known from antiquity. Alloy making i.e., homogenizing metals started in a “hit-or-miss” way. The 1st alloy from copper (Cu) and tin (Sn) was produced around 2500 BC and from then Bronze Age began. Subsequently iron (Fe) age started after the Bronze Age. Aluminium (Al) alloying was discovered much later because pure Al could not be recovered easily even though Al is the most abundant metal in the earth’s crust. Refining of Al is a very difficult job because of its strong affinity towards oxygen. To ease alloying, melting points (mp) of the individual constituents and reactivity of metal towards oxygen were the hurdles. Now understanding the thermodynamics of metal mixing has paved alloying. Periodic properties of elements concerning size, electronegativity, crystal structure, valency, lattice spacing, etc. are considered for alloying. In this feature article, more emphasis is given to Hume-Rothery rules in which the necessary parameters for alloying have been illustrated. Importantly standard electrode potential (E0) values, eutectic, phase diagram, size-related strain in metals, etc. have been looked into in the present discussion. One elegant example is Sn-Pb alloy, known as soft solder. Soft solder was in use for many years to connect metals and in electric circuitry. Low melting, flowability, and conductivity of soft solder had placed Sn-Pb alloy a unique position in industries, laboratories and even in cottage industries. However, toxic Pb volatilizes during soldering and hence soft solder is banned almost in all countries. We felt the need for a viable alternative to obtain soldering material and then silver (Ag) based highly conducting, an eco-friendly alloy of Sn resulted in from a high boiling liquid. The discovery engenders not only a new conducting soldering alloy but also a new concept of melting metals together. Furthermore, new ideas of alloying have been generalized at their nanostages from a suitable high boiling solvent.

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金属液相纳米级合金化

金属的合金化从古代就为人所知。合金制造，即均质化金属开始于一种“偶然”的方式。第一种由铜(Cu)和锡(Sn)制成的合金是在公元前2500年左右生产的，从那时起青铜时代开始了。随后，铁(Fe)时代开始于青铜时代之后。铝(Al)合金的发现要晚得多，因为纯铝不容易回收，尽管铝是地壳中最丰富的金属。由于铝对氧有很强的亲和力，精炼铝是一项非常困难的工作。为了减轻合金化，单个成分的熔点(mp)和金属对氧的反应性是障碍。现在对金属混合热力学的理解为合金化铺平了道路。元素在尺寸、电负性、晶体结构、价电子、晶格间距等方面的周期性特性在合金化中被考虑。在这篇专题文章中，更多地强调休谟-罗瑟里规则，其中说明了合金化的必要参数。重要的是，本文讨论了标准电极电位(E0)值、共晶、相图、金属中与尺寸相关的应变等。一个典型的例子是被称为软焊料的锡铅合金。软焊料用于连接金属和电路已经很多年了。软焊料的低熔点、流动性和导电性使锡铅合金在工业、实验室甚至家庭手工业中占有独特的地位。然而，有毒的铅在焊接过程中挥发，因此软焊料几乎在所有国家都被禁止。我们觉得需要一种可行的替代方案来获得焊接材料，然后是银(Ag)基高导电性，这是一种由高沸点液体产生的环保锡合金。这一发现不仅产生了一种新的导电焊接合金，而且还产生了将金属熔合在一起的新概念。此外，还从合适的高沸点溶剂中推广了纳米级合金化的新思路。

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Advances in Chemical Engineering and Science

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