REusable MAsk Patterning

This report is drafted according to the Horizon Europe reference document template The report includes information about the reuse of existing data by the project the findability accessibility interoperability and reusability FAIR of the data generated by the project the allocation of resources needed to ensure FAIR principles the provision implemented to ensure the data is securely stored the ethical and legal issues associated with data sharing any additional data procedures followed by the participating organizations

This report provides the first update of the data management plan.

A modern project website with linked YouTube channel and social media Linkedin Twitter acting as a repository for communication and dissemination activities demonstrations research news and public job advertisement The aim is to provide updated relevant information to all targeted audience

This deliverable is a summary of the communication actions undertaken during the first campaign of Science Festival. It includes evidence of the demonstrations in the form of YouTube videos linked to the project website.

These are LMS-based MRE formulations selected among the trials undertaken in T1.3 that display the following characteristics: ≥95% plating efficiency; ≥5% weight load, ≥70% split @B=2.0T/m.The LMS-based MRE formulations (SOLVIONIC, UNIGE, CNRS) are (Cu,In,Se)-based LMS candidates sharing anion (e.g. [Tf2N]-). For these formulations electrochemical window and plating efficiency are determined. These formulations contain micro-nano-based magnetic particles dispersed in a wide range of MNPs:MMPs mole fractions(0.01÷1). The interphase M/E is optimised for dispersion and purpose via appropriate surface charge and functionalisation. The formulations are tested magnetorheologically vs. MNPs/MMPs ratio/load to attain target phase M Yield stress on the order of 10 kPa at B=0.01 T, excluding convective flows in phase E. The characteristics of the formulations are assessed for societal impact beyond REMAP e.g. smart fluid for robotic space applications (TRL1-2).

This is a device consisting of an array of 10×10 µm2 current lines or multiple array stackings obtained by traditional photolithography with intermediate planarization steps if needed, or other components but having equivalent end characteristics. The device also includes the functional circuitry arrangement and a control unit. The controller is responsible to drive each of the array lines up to 100mA. To this end, a programmable current source is designed and fabricated in CMOS technology providing enough current driving for each of the array lines (this depends on the FEA simulations and its resistance). The CAD software used to design (layout) masks generates a geometry file with information that needs to be converted by software into commands (a set of bits) that control the current flow in each of the array lines. A current flowing through each line can be switched ON and OFF as a memory address. The controller will also carry a serial digital interface that will allow those programming bits to be transferred from CAD software to the matrix device. The current intensity can also be programmed in order to evaluate the performance of the whole system and also compensate for temperature variations. It follows that the CMOS current driver needs to be integrated (connected) to the matrix of current lines (fabricated at INL) driving individual column and row lines. This embodiment is integrated as a System-in-Package hardware with CMOS driver dies and a silicon matrix of current lines assembled in a single substrate, properly packaged, interconnected and protected for operation during the poc. 2D and 3D packaging (stacking of dies) strategies are considered providing the proper alignment between the matrix of current lines and the substrate to be plated. For future scalability, a single CMOS die may be considered integrating the matrix of current lines and the addressable current sources necessary to drive the current lines.The demonstration includes the magnetic and electrical characterization of the device, including 2-dimensional mapping of generated micro-structured magnetic field under variable pattern configurations, such that the deviation of the experimentally determined maps is ≤ 10% with respect to the finite element analysis described in D2.1.

"The data in this deliverable provides evidence of REMAP's fundamental hypothesis, i.e. that MRE/∇B coupling entails a decrease (or not) of the ion diffusivity through phase M compared to the uncoupled MRE. Such a feature is quantified by establishing REMAP's key performance indicator (KPI) called ""masking efficiency"" and defined as [1-(J_E^M)⁄(J_E^E )]. The KPI enables screening the various MRE formulations generated in WP1, until a masking efficiency ≥95% is demonstrated."