Process Recipes for Additively Printed Copper-Ink Flexible Circuits using Direct Write Methods

In this paper, the process-recipes and process-performance relationships for additive-printing of copper circuits using direct-write methods have been studied. The process has been implemented on the direct write platform. Interest in the use of additive printing methods for the manufacture of micro-circuits has grown immensely in recent times. Direct write methods have been shown to have the ability to create circuits in a limited manner. However, the process recipes and the effect of process parameters on the manufactured properties are not well understood. Copper ink is a good and cost-effective alternative to silver ink but its use has lagged owing to an increased propensity for oxidation. In this paper, photonic curing has been used to sinter copper ink to make the traces conductive. The method flashes high energy light that sinter metal particles instantaneously and the temperature of the substrate remains low. The effect of the different photonic sintering profiles on the mechanical and electrical properties of the printed traces has been studied in this paper. The print process parameters also play an important role in the line width and height that has been studied to print with the desired line profile for the end application. An LC filter circuit is been printed with SMD components been attached using an electrically conductive adhesive (ECA). The manufactured flexible LC filter is been tested for its frequency sweep to compare with the commercially available LC filer with the help of the Bode plot.

[1]  Dominik P. J. Barz,et al.  Direct writing of liquids by micro dispensing: Stability and shape of laminar jets with high Froude numbers , 2020, Chemical Engineering Journal.

[2]  Benjamin J. Leever,et al.  Effect of Sintering Temperature on the Fatigue Life of Additively Printed Electronics During Cyclic Bending , 2019, 2019 18th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm).

[3]  Caroline Sunyong Lee,et al.  Application of flash-light sintering method to flexible inkjet printing using anti-oxidant copper nanoparticles , 2018, Thin Solid Films.

[4]  Xuyuan Tao,et al.  How to Make Reliable, Washable, and Wearable Textronic Devices , 2017, Sensors.

[5]  B. B. Narakathu,et al.  Screen Printing of Multilayered Hybrid Printed Circuit Boards on Different Substrates , 2015, IEEE Transactions on Components, Packaging and Manufacturing Technology.

[6]  Hyun-Jun Hwang,et al.  Highly conductive copper nano/microparticles ink via flash light sintering for printed electronics , 2014, Nanotechnology.

[7]  Hyun-Jun Hwang,et al.  In situ monitoring of flash-light sintering of copper nanoparticle ink for printed electronics , 2012, Nanotechnology.

[8]  Ajeet Rohatgi,et al.  Improved front side metallization for silicon solar cells by direct printing , 2011, 2011 37th IEEE Photovoltaic Specialists Conference.

[9]  Young‐Chang Joo,et al.  Improvement of Electrical and Mechanical Properties of Ag Nanoparticulate Films by Controlling the Oxygen Pressure , 2010 .

[10]  C. Grigoropoulos,et al.  All-inkjet-printed flexible electronics fabrication on a polymer substrate by low-temperature high-resolution selective laser sintering of metal nanoparticles , 2007 .

[11]  Seong-Gu Baek,et al.  Thermal behavior of direct-printed lines of silver nanoparticles , 2006 .

[12]  K. Chou,et al.  Fabrication and sintering effect on the morphologies and conductivity of nano-Ag particle films by the spin coating method , 2005 .

[13]  R. Rumpf,et al.  HIGH-FREQUENCY FILTERS MANUFACTURED USING HYBRID 3D PRINTING METHOD , 2019, Progress In Electromagnetics Research M.

[14]  Xudong Chen,et al.  Advanced Printing for Microelectronic Packaging , 2014 .

[15]  Hak-Sung Kim,et al.  Flash light sintering of nickel nanoparticles for printed electronics , 2014 .

[16]  Eugenio Cantatore,et al.  Applications of Organic and Printed Electronics , 2013 .

[17]  Eugenio Cantatore,et al.  Applications of organic and printed electronics : a technology-enabled revolution , 2013 .