Scalable Method for Synthesis of multifunctional colloidal INKs for Superconductors, (SMS-INKS) [dataset]; DIGITAL.CSIC;

One of the pathways to overcome the global warming is to find and use a more efficient supply of electrical energy. High temperature superconductor materials are one of the best candidates due to their ability to transport electricity with minimum to no losses and to their application in nuclear fusion. Also, superconducting nanocomposites are very useful in application at high magnetic fields which makes them very interesting for different fields like transport or medicine. The large-scale applications however are limited by the cost/performance ratio. The novel technology that we have developed, TLAG-CSD, can lower substantially the cost/performance ratio because it combines the CSD methodology with very high growth rates and it is compatible with nanocomposite growth. The TLAG-CSD approach uses multifunctional colloidal inks (MFCI) to control the nanoscale landscape and therefore the final properties of the superconducting nanocomposite layers. To demonstrate the scalability of the TLAG-CDS process the first step was to demonstrate the scalability of the MFCI. This implies the scale-up of all the salts and nanoparticle colloidal solutions that are involved in the preparation of the MFCI and their validation. During this project the scalability of the MFCI used in the TLAG-CSD methodology was demonstrated step by step as mentioned before. The provided data set includes the most relevant results of this project in the form of both raw and processed data. The data set is organized in 3 folders corresponding to the scale-up results of nanopatical colloidal solution, the propionaye salts and MFCI TLAG-CSD inks. Another folder comprises the read me files that give information on how to open and read the data set.