HELENA project: Driving innovation in high energy density Li-metal halide solid-state batteries for electric vehicles and aircrafts

Pedro López-Aranguren; Pierre  Lannelongue; Javier Carrasco; Andrey  Golov; Adrian Robles-Fernandez; Elena Gonzalo; Artur Tron; Thomas  Marchandier; Anna-Katharina Hatz; Reza Fathi; Qi  Xu; Diana Chaykina; Cerun Alex Varkey; Claudio Gavagnin; Matteo Kaminski; Alaa Almousli; Gebrekidan Gebresilassie  Eshetu; Niloofar Hamzelui; Fabian  Diaz; Emanuel  Drude; Sara Abada; Nicolas  Guy; Akshayan  Sudharshan; Massimo  Brunetti; Stefan  Beschnitt

doi:10.1016/j.csbj.2025.03.013

HELENA project: Driving innovation in high energy density Li-metal halide solid-state batteries for electric vehicles and aircrafts

Pedro López-Aranguren
, Pierre Lannelongue
, Javier Carrasco
, Andrey Golov
, Adrian Robles-Fernandez
, Elena Gonzalo
, Artur Tron
, Thomas Marchandier
, Anna-Katharina Hatz
, Reza Fathi
, Qi Xu
, Diana Chaykina
, Cerun Alex Varkey
, Claudio Gavagnin
, Matteo Kaminski
, Alaa Almousli
, Gebrekidan Gebresilassie Eshetu
, Niloofar Hamzelui
, Fabian Diaz
, Emanuel Drude

Sara Abada, Nicolas Guy, Akshayan Sudharshan, Massimo Brunetti, Stefan Beschnitt

Battery Technologies

CIC energiGUNE
Saint-Gobain Research Paris
Umicore
LionVolt
Netherlands Organisation for Applied Scientific Research (TNO)
Fraunhofer-Gesellschaft
Institut für Partikeltechnik, Technische Universitat Braunschweig
CustomCells Holding GmbH
RWTH Aachen University
MIMITech GmbH
IFP Énergies nouvelles
Pipistrel Vertical Solutions
Leonardo S.p.A.
FEV Group

Research output: Contribution to journal › Article › peer-review

Abstract

The development of sustainable, high-efficiency and reliable batteries is critical to support climate neutrality goals, particularly in the electromobility sector. The European-funded HELENA project (Halide Solid State Batteries for Electric Vehicles and Aircraft) addresses these challenges by focusing on the manufacturing of next-generation lithium-metal solid-state batteries. The project tackles key hurdles in raw material sourcing, battery production, sustainability and cost-effectiveness. A multidisciplinary partnership brings the innovation from the lab to the industrial scale, covering the whole value chain, including industrial material producers, R&D centres, battery manufacturers, and automotive and aerospace end-users. The cell design features a high-voltage nickel-rich cathode coupled with a high-energy lithium metal anode and a lithium-ion superionic halide solid electrolyte. This configuration enhances energy and power density, thus being suitable for electric vehicles and aircrafts. HELENA aims to reshape the solid-state battery landscape by advancing technology readiness levels through the manufacturing of 10 Ah pre-industrial prototypes. This report highlights mid-way results of the project, discussing the major advancements in battery specifications and safety standards from end-users, processing of materials into battery component, battery modelling and recycling strategies to ensure long-term sustainability.

Original language	English
Pages (from-to)	72-84
Number of pages	13
Journal	Computational and Structural Biotechnology Journal
Volume	29
DOIs	https://doi.org/10.1016/j.csbj.2025.03.013
Publication status	Published - 19 Mar 2025

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure
SDG 13 Climate Action

Research Field

Solid State Battery

Keywords

Halides
Solid-state batteries
Electric vehicles
Electric aviation
Climate neutrality
Battery roadmap
solid electrolyte

Access to Document

10.1016/j.csbj.2025.03.013Licence: CC BY

Cite this

López-Aranguren, P., Lannelongue, P., Carrasco, J., Golov, A., Robles-Fernandez, A., Gonzalo, E., Tron, A., Marchandier, T., Hatz, A.-K., Fathi, R., Xu, Q., Chaykina, D., Varkey, C. A., Gavagnin, C., Kaminski, M., Almousli, A., Eshetu, G. G., Hamzelui, N., Diaz, F., ... Beschnitt, S. (2025). HELENA project: Driving innovation in high energy density Li-metal halide solid-state batteries for electric vehicles and aircrafts. Computational and Structural Biotechnology Journal, 29, 72-84. https://doi.org/10.1016/j.csbj.2025.03.013

@article{7e68bee29a404088b8bf05438bd547d8,

title = "HELENA project: Driving innovation in high energy density Li-metal halide solid-state batteries for electric vehicles and aircrafts",

abstract = "The development of sustainable, high-efficiency and reliable batteries is critical to support climate neutrality goals, particularly in the electromobility sector. The European-funded HELENA project (Halide Solid State Batteries for Electric Vehicles and Aircraft) addresses these challenges by focusing on the manufacturing of next-generation lithium-metal solid-state batteries. The project tackles key hurdles in raw material sourcing, battery production, sustainability and cost-effectiveness. A multidisciplinary partnership brings the innovation from the lab to the industrial scale, covering the whole value chain, including industrial material producers, R\&D centres, battery manufacturers, and automotive and aerospace end-users. The cell design features a high-voltage nickel-rich cathode coupled with a high-energy lithium metal anode and a lithium-ion superionic halide solid electrolyte. This configuration enhances energy and power density, thus being suitable for electric vehicles and aircrafts. HELENA aims to reshape the solid-state battery landscape by advancing technology readiness levels through the manufacturing of 10 Ah pre-industrial prototypes. This report highlights mid-way results of the project, discussing the major advancements in battery specifications and safety standards from end-users, processing of materials into battery component, battery modelling and recycling strategies to ensure long-term sustainability.",

keywords = "Halides, Solid-state batteries, Electric vehicles, Electric aviation, Climate neutrality, Battery roadmap, solid electrolyte",

author = "Pedro L{\'o}pez-Aranguren and Pierre Lannelongue and Javier Carrasco and Andrey Golov and Adrian Robles-Fernandez and Elena Gonzalo and Artur Tron and Thomas Marchandier and Anna-Katharina Hatz and Reza Fathi and Qi Xu and Diana Chaykina and Varkey, \{Cerun Alex\} and Claudio Gavagnin and Matteo Kaminski and Alaa Almousli and Eshetu, \{Gebrekidan Gebresilassie\} and Niloofar Hamzelui and Fabian Diaz and Emanuel Drude and Sara Abada and Nicolas Guy and Akshayan Sudharshan and Massimo Brunetti and Stefan Beschnitt",

year = "2025",

month = mar,

day = "19",

doi = "10.1016/j.csbj.2025.03.013",

language = "English",

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López-Aranguren, P, Lannelongue, P, Carrasco, J, Golov, A, Robles-Fernandez, A, Gonzalo, E, Tron, A, Marchandier, T, Hatz, A-K, Fathi, R, Xu, Q, Chaykina, D, Varkey, CA, Gavagnin, C, Kaminski, M, Almousli, A, Eshetu, GG, Hamzelui, N, Diaz, F, Drude, E, Abada, S, Guy, N, Sudharshan, A, Brunetti, M & Beschnitt, S 2025, 'HELENA project: Driving innovation in high energy density Li-metal halide solid-state batteries for electric vehicles and aircrafts', Computational and Structural Biotechnology Journal, vol. 29, pp. 72-84. https://doi.org/10.1016/j.csbj.2025.03.013

TY - JOUR

T1 - HELENA project: Driving innovation in high energy density Li-metal halide solid-state batteries for electric vehicles and aircrafts

AU - López-Aranguren, Pedro

AU - Lannelongue, Pierre

AU - Carrasco, Javier

AU - Golov, Andrey

AU - Robles-Fernandez, Adrian

AU - Gonzalo, Elena

AU - Tron, Artur

AU - Marchandier, Thomas

AU - Hatz, Anna-Katharina

AU - Fathi, Reza

AU - Xu, Qi

AU - Chaykina, Diana

AU - Varkey, Cerun Alex

AU - Gavagnin, Claudio

AU - Kaminski, Matteo

AU - Almousli, Alaa

AU - Eshetu, Gebrekidan Gebresilassie

AU - Hamzelui, Niloofar

AU - Diaz, Fabian

AU - Drude, Emanuel

AU - Abada, Sara

AU - Guy, Nicolas

AU - Sudharshan, Akshayan

AU - Brunetti, Massimo

AU - Beschnitt, Stefan

PY - 2025/3/19

Y1 - 2025/3/19

N2 - The development of sustainable, high-efficiency and reliable batteries is critical to support climate neutrality goals, particularly in the electromobility sector. The European-funded HELENA project (Halide Solid State Batteries for Electric Vehicles and Aircraft) addresses these challenges by focusing on the manufacturing of next-generation lithium-metal solid-state batteries. The project tackles key hurdles in raw material sourcing, battery production, sustainability and cost-effectiveness. A multidisciplinary partnership brings the innovation from the lab to the industrial scale, covering the whole value chain, including industrial material producers, R&D centres, battery manufacturers, and automotive and aerospace end-users. The cell design features a high-voltage nickel-rich cathode coupled with a high-energy lithium metal anode and a lithium-ion superionic halide solid electrolyte. This configuration enhances energy and power density, thus being suitable for electric vehicles and aircrafts. HELENA aims to reshape the solid-state battery landscape by advancing technology readiness levels through the manufacturing of 10 Ah pre-industrial prototypes. This report highlights mid-way results of the project, discussing the major advancements in battery specifications and safety standards from end-users, processing of materials into battery component, battery modelling and recycling strategies to ensure long-term sustainability.

AB - The development of sustainable, high-efficiency and reliable batteries is critical to support climate neutrality goals, particularly in the electromobility sector. The European-funded HELENA project (Halide Solid State Batteries for Electric Vehicles and Aircraft) addresses these challenges by focusing on the manufacturing of next-generation lithium-metal solid-state batteries. The project tackles key hurdles in raw material sourcing, battery production, sustainability and cost-effectiveness. A multidisciplinary partnership brings the innovation from the lab to the industrial scale, covering the whole value chain, including industrial material producers, R&D centres, battery manufacturers, and automotive and aerospace end-users. The cell design features a high-voltage nickel-rich cathode coupled with a high-energy lithium metal anode and a lithium-ion superionic halide solid electrolyte. This configuration enhances energy and power density, thus being suitable for electric vehicles and aircrafts. HELENA aims to reshape the solid-state battery landscape by advancing technology readiness levels through the manufacturing of 10 Ah pre-industrial prototypes. This report highlights mid-way results of the project, discussing the major advancements in battery specifications and safety standards from end-users, processing of materials into battery component, battery modelling and recycling strategies to ensure long-term sustainability.

KW - Halides

KW - Solid-state batteries

KW - Electric vehicles

KW - Electric aviation

KW - Climate neutrality

KW - Battery roadmap

KW - solid electrolyte

UR - https://www.sciencedirect.com/science/article/pii/S2001037025000819

U2 - 10.1016/j.csbj.2025.03.013

DO - 10.1016/j.csbj.2025.03.013

M3 - Article

SN - 2001-0370

VL - 29

SP - 72

EP - 84

JO - Computational and Structural Biotechnology Journal

JF - Computational and Structural Biotechnology Journal

ER -

HELENA project: Driving innovation in high energy density Li-metal halide solid-state batteries for electric vehicles and aircrafts

Abstract

UN SDGs

Research Field

Keywords

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