BATTERY 2030+

At the heart of a green and connected society

A Large-Scale Research Initiative on Future Battery Technologies

Coordinator: Prof. Kristina Edström, Uppsala University, Sweden

Deputy coordinator: Dr. Simon Perraud, CEA, France

2019 THE YEAR OF THE BATTERY NOBEL PRIZE

Nobel Laureate Says “Better Batteries Can

Cement Electric-Car Era”Stan Whittingham

THE PURPOSE OF THIS MEETING

To discuss the BATTERY 2030+ research roadmap for a large-scale and long-term initative

To support Europe to reach sustainabilitygoals

To develop European research excellence to the benefit of European battery industry, along the full battery value chain

To suggest new R&I actions

WHY EUROPE SHOULD ACT NOW?

HOW BATTERY 2030+ CAN CONTRIBUTE

KEY TECHNOLOGY TO SUPPORT A FOSSIL-FREE SOCIETY

Global supply and demand of Li-ion batteries and the European shareinmanufacturing. Source: JRC April 2019

EXECUTIVE SUMMARY

The BATTERY 2030+ initiative at a glance

A LONG-TERM RESEARCH INITIATIVE

• Inventing the batteries of the future

• Providing breakthrough technologies to the European battery industry across the full value chain

• Enabling long-term European leadership in both existing markets (road transport, stationary energy storage) and future emerging applications (robotics, aerospace, medical devices, internet of things, …)

Ultrahigh performances

Environmental sustainability

Smart functionalities

NOVEL CONCEPTS ALONG THE FULL VALUE CHAIN

Raw materials

Cellproduction

Smart sensing and self-healing functionalities

Establish the computational “Battery

Interface Genome”:

Accelerated materials discovery (MAP)

Energy & power densities approaching theoretical limits

Chemistry neutral approach

Manufacturabilityand recyclabilityare cross-cutting topics for battery technologies to be developed

IN RELATION TO THE SET PLAN

BATTERY 2030+ TRANSFORMATIONAL CHEMISTRY-NEUTRAL RESEARCH:• Accelerated battery material discovery & interface engineering• Smart sensing & self-healing functionalities• Cell design & manufacturability (cross-cutting)• Recyclability (cross-cutting)

FUTURE BATTERY CHEMISTRIES

POST-LITHIUM BATTERY CHEMISTRIESSodium-ion, multivalent metal-ion, metal-air, redox flow, etc.

LITHIUM BATTERY CHEMISTRIES (SET Plan)Generation 5 (lithium-air, lithium-sulfur)Generation 4 (all-solid-state lithium-ion or lithium-metal)Generation 3 (advanced lithium-ion)

Game changesinstead ofincremental

TARGETS?

Within 10 years of BATTERY 2030+ research efforts the impact on battery technology (compared to the current state of art) will be the following:

• Reducing the gap, by at least a factor of 2, between accessible and theoretical battery performances (energy density and power density);

• Improving, by at least a factor of 3, the battery durability and reliability;

• Cutting down, by at least a factor of 5, the life-cycle carbon footprint of batteries (for a given electricity mix);

• Reaching a battery recycling rate of at least 75%, and a critical raw material recycling rate close to 100%.

THE BATTERY ECO-SYSTEM

How does BATTERY 2030+ relate to other European battery initiatives?

How does BATTERY 2030+ relate to other international battery roadmaps?

TRL 1 TRL 2 TRL 3 TRL 4 TRL 5 TRL 6 TRL 7 TRL 8 TRL 9

The European Battery Community

Long-term research Short-to-medium term research Industrialization

A long-term research roadmap

SET-Plan Industrial roadmaps

Actors

Roadmap

Scope

THE EUROPEAN BATTERY R&I LANDSCAPE

March 2019 June 2019 October 2017

S3 battery materials

January 2019

BATTERY R&I NETWORKS ARE FORMED IN EUROPE

We have visitedand we are visiting

Europe has importantresearch infrastructures:

Synchrotrons – LEAPSNeutron facilities – LENS

HPC computing - EuroHPC

So far 1300 endorsements

Almost 1000 followers on twitter: 2030battery

WE ALREADY HAVE IMPACT

LC-BAT-12-2020: Novel methodologies for autonomous discovery of

advanced battery chemistries

LC-BAT-13-2020: Sensing functionalities for smart battery cell chemistries

LC-BAT-14-2020: Self-healing functionalities for long lasting battery cell

chemistries

LC-BAT-15-2020: Coordinate and support the large scale research initiative

on Future Battery Technologies

20 MEU for one project

10 MEU for 2-5 projects

10 MEU for 2-5 projects

2 MEU for 1 project

Closes the 16th of January 2020

WHAT DO WE EXPECT FROM HORIZON EUROPE

• A large scale and long term perspective on research for future green batteries is essential for Europe to take the lead in this growing market

• The ambitions are high and dedicated funds are needed

• Ensure a coordinated approach across Europe

• BATTERY 2030+ with a dedicated budget takes the lead for the long term research

RELATION TO OTHER ROADMAPS

Professor Hong Li. Presentation at ABAA 12 in Ulm 2019

NOBEL PRIZE

the day before

Prof. Stan Whittingham at ABAA 12 conference in Ulm

the day after

Dr. Akiro Yoshino

NOBEL PRIZE

1978 – Prof John B. Goodenough is 56 years

Lithium cobalt oxide58 years

Lithium manganesespinel 61 years

Lithium iron phosphate70 years

Anglo-Danish battery projectFrom Oxford

THANK YOU

The roadmap and manifesto is available online. Endorse now!

http://battery2030.eu

Prof. Kristina Edström

Department of Chemistry – Ångström LaboratoryUppsala University

Kristina .edstrom@kemi.uu.se

Twitter: 2030batteryLinkedin: batteryinitiative