Trans. Nonferrous Met. Soc. China 23(2013) 128133 Low temperature synthesis and thermal properties of AgCu alloy nanoparticles W. BHAGATHSINGH 1 , A. SAMSON NESARAJ 2 1. School of Nanosciences and Technology, Karunya University, Coimbatore-641 114, Tamil Nadu, India; 2. Department of Chemistry, Karunya University, Coimbatore-641 114, Tamil Nadu, India Received 24 February 2012; accepted 4 September 2012 Abstract: AgCu alloy nanoparticles were synthesized by simple low temperature chemical reduction method using metal salts (acetate/sulphates) in aqueous solution with sodium borohydride as reducing agent. The chemical reduction was carried out in the presence of nitrogen gas in order to prevent the oxidation of copper during the reaction process. The alloy nanoparticles were characterized by XRD, UV-Vis, particle size analysis, EDS, TG-DTA and SEM analysis. From the XRD analysis, the crystallite sizes of the prepared samples were calculated using Scherrer formula and the values were found to be in the range of 15 nm. UV-Vis studies conform the formation of alloy nanoparticles. EDS analysis shows the presence of silver and copper in the samples. The SEM observation reveals that the samples consist of grains with average grain size up to 40 nm, and the particle size dependant melting point was studied by TG-DTA. Key words: AgCu alloy nanoparticles; chemical reduction method; characterization 1 Introduction The fabrication of materials with well defined, controllable properties and structures on the nanometer scale coupled with the flexibility paid by intermetallic materials, which is referred as nanoalloys [1]. Metallic alloys in the nanoregime reveal unique optical, catalytic, electric, and magnetic properties that are widely different from those of the corresponding bulk materials [2]. When two or more kinds of metals are melted together, the melting point, rigidity, conductivity, and extensibility change considerably. And when it comes to nanoalloy materials, new and interesting properties show up [3,4]. Electronic packaging is a manufacturing technology used for electronic products. Packaging provides a medium for electronic interconnections and mechanical support, and solder alloys provide the electrical and mechanical connections between the die (chip) and the bonding pads. The selection of materials for solder alloys is critical and plays an important role in solder joint reliability [4]. A solder is a fusible metal alloy, which is melted to join metallic surfaces, especially in the fields of electronics and plumbing, in a process called soldering [5]. SnPb alloy is a traditional material which has been used for interconnect materials for a long history. However, due to the inbuilt toxicity and the harm to human health and environment, SnPb alloy is gradually being taken out of the electronic industry in many countries. As a result, electronics manufacturers need to be aware of the solder alloy choices available to them. Due to the toxicity of lead, the studies were directed towards the lead-free solders. Nowadays, attention has been directed to lower the eutectic temperature or melting point of lead-free alloys for soldering purposes. The utilization of metals such as tin, copper, silver, and sometimes bismuth, indium, zinc, antimony, and other metals has been investigated [68]. As a result, many lead-free solder alloys have been proposed. The melting point of most lead-free solders is higher than that of electric SnPb solder (melting point: 221 °C). This higher melting point, in turn, pushes the solder reflow (i.e., spreading of molten alloy on the contact surface) temperature to over 260 °C and severely limits the applicability of this metal alloy to temperature sensitive components and/or low cost organic printed circuit boards. Corresponding author: A. SAMSON NESARAJ; Tel: +91-422-2614301; E-mail: drsamson@karunya.edu DOI: 10.1016/S1003-6326(13)62438-3