UC3

Material solutions for low carbon energy

General description of use case

The European Union has prioritized materials as a Key Enabling Technology (KET) to enable the transition to a knowledge-based, low carbon, resource-efficient economy and has proposed a materials roadmap to address the technology agenda of the SET-Plan. With the imperative to change the energy technology mix to respond to the challenges of decarbonization and security of energy supply, the need for new materials and processing routes is overriding. New efficient and cost-competitive energy technologies are urgently needed. In this respect, materials research and control over materials resources are becoming increasingly important in the current global competition for industrial leadership in low carbon technologies. Two EERA Joint Programs (Nuclear Materials and AMPEA) are directly involved in materials research for energy applications and several other Joint Programs are interested in new materials to improve the efficiency of energy technologies. To speed-up the discovery of new materials for energy technologies, Innovation Challenge No. 6 of the Mission Innovation Initiative is devoted to the discovery of new materials. This Innovation Challenge aims at accelerating the innovation process for high performance, low-cost clean energy materials and automating the processes needed to integrate these materials into new technologies. The challenge is to combine advanced theoretical and applied physical chemistry/materials science data, as well as data on the life cycle of materials and material compounds with next-generation computing infrastructures, artificial intelligence, and robotics tools. The goal is to create a fully integrated approach.

Materials research is characterized by strong multidisciplinary research in which both, converging technologies and cooperation, should be exploited to speed up application-oriented research activities. This is not always the case due to the extremely different technological fields where materials are employed (in the energy sector and beyond). Indeed, each technological field has often developed its own terminology, experimental set-ups, research procedures, and, consequently, its own standards in data management. Therefore, it can be argued that in the field of materials for energy data the state of the art is the following: Openness is low to medium, re-usability is low to medium, and barriers are high. Finally, actions put in place are rare (low to medium). The availability of an open data infrastructure covering as many research fields as possible could increase opportunities to develop new research programs, defragment the materials for energy communities, avoid the duplication of research activities, speed-up the discovery of materials, and increase the understanding of how energy systems could better benefit from existing and new materials. Many databases are already available but a large amount of data is currently produced in laboratories, not organized to be shared. Moreover, databases do not follow common formats preventing inter-operability and re-usability. In view of the intended automatization, it is important that access to databases is machine-actionable. Finally, due to the strong connection with industries, questions of open data access need to be explored and new business models need to be developed.

Database of interest

List of databases related to WP6

• JRC: structural materials, raw materials and nanomaterials for health, https://data.jrc.ec.europa.eu/ , Contact point: Tim Austin
• NOMAD, European Centre of Excellence, https://nomad-coe.eu/ Contact point: Luca Ghiringhelli
• Urban Mine Platform (waste from electronics, vehicles, batteries etc) http://www.urbanmineplatform.eu/homepage
• ProQuest, https://www.proquest.com/
• MatWeb, http://www.matweb.com/
• AZOmaterials, https://www.azom.com/
• Crystallography Open Database, http://www.crystallography.net/cod/
• ChemSpider, http://www.chemspider.com/
• MaterialDistrict (match-making platform), https://materialdistrict.com/
• Open Materials Database, http://openmaterialsdb.se/
• phase diagrams http://www.crct.polymtl.ca/fact/documentation/
• xps https://srdata.nist.gov/xps/main_search_menu.aspx
• Automatic Flow for Materials Discovery (AFLOWLIB) http://www.aflowlib.org/
• Open Quantum Materials Database (OQMD), http://oqmd.org/
• Computational 2D Materials Database (C2DB) http://c2db.fysik.dtu.dk/
• MATDAT, https://www.matdat.com/
• Materials Connexion, https://www.materialconnexion.com/
• Materials web , https://www.materialsweb.org/

Networks

• EMIRI (The Energy Materials Industrial Research Initivative), Simon Perraud
• EUMAT (European Technology Platform for Advanced Materials), Amaya Igartua
• EMMC ASBL (European Materials Modeling Council), Nadja Adamovic & Gerhard Goldbeck
• MARVEL , Nicola Marzari or Giovanni Pizzi (GoFAIR)
• Materials Genome (USA), Stefano Curtarolo (Duke)
• NOMAD (GoFAIR)

• EERA JPs
  • AMPEA
  • Nuclear Materials
  • Photovoltaics
  • Energy Storage
  • Fuel Cells and Hydrogen
  • Wind

METADATA

• Findable: unique names, human-readable descriptions
• Accessible: URL, accessible via API
• Interoperable: typed, extensible schema → ontologies
• Reusable: hierarchical schema → data-analytics

An ontology is

List of selected databases

During the first workshop (see notes from Day 2), the following databases were selected to analyze and improve their compliance with FAIR and Open data principles:

Metadata assessments

Databases above were assessed with respect to their current meta practices. The table below summarizes the current state and issues identified during WS 1:

GOFAIR implementation projects

• NOMAD
• Materials Cloud

Conferences

Virtual Conference on A FAIR Data Infrastructure For Materials Genomics 3 - 5 June, 2020

• The focus of the conference is to describe the new horizons that can be reached by a FAIR data infrastructure for materials genomics. This conference is organized by the association FAIR-DI e.V.
• Notable groups participating we should link with: NOMAD Center of Excellence, BIG-DATA ANALYTICS FOR MATERIALS SCIENCE
• Existing metadata or other standards we should have in mind and link with: FAIR-DI e.V; OPTIMADE Consortium.

Literature

• Towards efficient data exchange and sharing for big-data driven materials science: metadata and data formats. Luca M. Ghiringhelli, Christian Carbogno, Sergey Levchenko, Fawzi Mohamed, Georg Huhs, Martin Lüders, Micael Oliveira & Matthias Scheffler. npj Computational Materials volume 3, Article number: 46 (2017).
• FAIR from GOFAIR website: GOFAIR
• FAIRification process from GOFAIR website: GOFAIR
• Wang, S. (2016) Green practices are gendered: Exploring gender inequality caused by sustainable consumption policies in Taiwan; Energy Research & Social Science, 18, 88-95. [[1]]. Abstract: In the context of climate change, governments and international organizations often promote a “sustainable lifestyle.” However, this approach has been criticized for underestimating the complexity of everyday life and therefore being inapplicable to households and consumers. In addition, procedures for promoting sustainable consumption seldom incorporate domestic workers’ opinions and often increase women’s housework loads. This article employs a practice-based approach to examine the “Energy-Saving, Carbon Reduction” movement, a series of sustainable consumption policies that have been advocated by the Taiwanese government since 2008. The goal of the movement is to encourage an eco-friendly lifestyle. On the basis of empirical data collected through ethnographic interviews, this article argues that existing policies unexpectedly increase women’s burdens and exacerbate gender inequality.
• Ly, L. T. et al. (2015) Compliance monitoring in business processes: Functionalities, application, and tool-support, Information Systems 54, 209-234, [2]. Abstract: In recent years, monitoring the compliance of business processes with relevant regulations, constraints, and rules during runtime has evolved as major concern in literature and practice. Monitoring not only refers to continuously observing possible compliance violations, but also includes the ability to provide fine-grained feedback and to predict possible compliance violations in the future. The body of literature on business process compliance is large and approaches specifically addressing process monitoring are hard to identify. Moreover, proper means for the systematic comparison of these approaches are missing. Hence, it is unclear which approaches are suitable for particular scenarios. The goal of this paper is to define a framework for Compliance Monitoring Functionalities (CMF) that enables the systematic comparison of existing and new approaches for monitoring compliance rules over business processes during runtime. To define the scope of the framework, at first, related areas are identified and discussed. The CMFs are harvested based on a systematic literature review and five selected case studies. The appropriateness of the selection of CMFs is demonstrated in two ways: (a) a systematic comparison with pattern-based compliance approaches and (b) a classification of existing compliance monitoring approaches using the CMFs. Moreover, the application of the CMFs is showcased using three existing tools that are applied to two realistic data sets. Overall, the CMF framework provides powerful means to position existing and future compliance monitoring approaches.