Battery Knowledge Base

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=== Career ===
=== Career ===
After graduating from  {{Template:Viewer/Link|page=Item:OSWf1fcf1be81cc4a6eb653a90fed1d7a60|url=|label=Georgia Tech}} in 2009, Clark first worked as a design simulation engineer in the German spaceflight industry from 2010-2013. He contributed to the design of laser communication hardware on Earth observation satellites like {{Template:Viewer/Link|page=|url=https://www.esa.int/Applications/Observing_the_Earth/Copernicus/Sentinel-1|label=Sentinel 1}} and {{Template:Viewer/Link|page=|url=https://www.esa.int/Applications/Observing_the_Earth/Copernicus/Sentinel-2|label=Sentinel 2}}. He also designed the mirror hardware for one of the telescopes on {{Template:Viewer/Link|page=|url=https://www.esa.int/Science_Exploration/Space_Science/Solar_Orbiter|label=Solar Orbiter}}.  
After graduating from  {{Template:Viewer/Link|page=Item:OSWf1fcf1be81cc4a6eb653a90fed1d7a60|url=|label=Georgia Tech}} in 2009, Clark first worked as a design simulation engineer in the German spaceflight industry from 2010-2013. He contributed to the design of laser communication hardware on Earth observation satellites like {{Template:Viewer/Link|page=|url=https://www.esa.int/Applications/Observing_the_Earth/Copernicus/Sentinel-1|label=Sentinel 1}} and {{Template:Viewer/Link|page=|url=https://www.esa.int/Applications/Observing_the_Earth/Copernicus/Sentinel-2|label=Sentinel 2}}. He also designed the mirror hardware for one of the telescopes on {{Template:Viewer/Link|page=|url=https://www.youtube.com/watch?v=-X-p5C4SLVo|label=Solar Orbiter}}.  


In 2018, he joined {{Template:Viewer/Link|page=Item:OSWc6aa8b354453443aad6679c194a506f7|url=|label=SINTEF}} in Trondheim, Norway to work on battery digitalization topics. He has a leading role in EU-funded research projects like {{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}, {{Template:Viewer/Link|page=Item:OSWa447d5f341294108879be0aac68cb1a4|url=|label=BIG-MAP}}, {{Template:Viewer/Link|page=Item:OSWd364682b4d274585b8ab6fb6d237d890|url=|label=DigiBatt}}, {{Template:Viewer/Link|page=Item:OSWb4132e89309a4a16a1c292598ae9ef29|url=|label=IntelLiGent}}, {{Template:Viewer/Link|page=Item:OSWbdaefbf2beb045c3912dcf136a804834|url=|label=HYDRA}}, and more. His current activities focus on bringing battery data into the Semantic Web and enabling fast physics-based design simulations. He is a core developer of the Battery Interface Ontology (BattINFO) and the {{Template:Viewer/Link|page=Item:OSW09ea8864ce8f4d559b6fa60300faa976|url=|label=Battery Modelling Toolbox (BattMo)}}
In 2018, he joined {{Template:Viewer/Link|page=Item:OSWc6aa8b354453443aad6679c194a506f7|url=|label=SINTEF}} in Trondheim, Norway to work on battery digitalization topics. He has a leading role in EU-funded research projects like {{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}, {{Template:Viewer/Link|page=Item:OSWa447d5f341294108879be0aac68cb1a4|url=|label=BIG-MAP}}, {{Template:Viewer/Link|page=Item:OSWd364682b4d274585b8ab6fb6d237d890|url=|label=DigiBatt}}, {{Template:Viewer/Link|page=Item:OSWb4132e89309a4a16a1c292598ae9ef29|url=|label=IntelLiGent}}, {{Template:Viewer/Link|page=Item:OSWbdaefbf2beb045c3912dcf136a804834|url=|label=HYDRA}}, and more. His current activities focus on bringing battery data into the Semantic Web and enabling fast physics-based design simulations. He is a core developer of the Battery Interface Ontology (BattINFO) and the {{Template:Viewer/Link|page=Item:OSW09ea8864ce8f4d559b6fa60300faa976|url=|label=Battery Modelling Toolbox (BattMo)}}
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| mode = slideshow
| mode = slideshow
| textdata = File:OSWf22cc6403053449d91f692cb16931bb9.jpg{{!}}Simon Clark speaking at the Road Transport Research Conference in 2025;
| textdata = File:OSWf22cc6403053449d91f692cb16931bb9.jpg{{!}}Simon Clark speaking at the Road Transport Research Conference in 2025;
File:OSW6e881ed7d7d74b55bc92f610ab9941f9.jpg{{!}}Generation 3b speaker panel at the Road Transport Research Conference 2025;
File:OSW82004dc3a2cd43b3ae8c87cf3081e696.png{{!}}Dr. Simon Clark speaking at the Future of Energy is Green and Digital conference in Oslo, Norway in January 2025.;
File:OSW840f35e7f43f4894b570525ee52d5fde.jpg{{!}}Generation 3b speaker panel at the Road Transport Research Conference 2025;
File:OSW7de87991182a4e1bbb52617a15ab98b9.jpg{{!}}Dr. Simon Clark presenting at the HYDRA / Battery2030+ joint workshop in Oslo, Norway 2024;
File:OSW7de87991182a4e1bbb52617a15ab98b9.jpg{{!}}Dr. Simon Clark presenting at the HYDRA / Battery2030+ joint workshop in Oslo, Norway 2024;
File:OSW82004dc3a2cd43b3ae8c87cf3081e696.png{{!}}Dr. Simon Clark speaking at the Future of Energy is Green and Digital conference in Oslo, Norway in January 2025.;
}}
}}
== Publications ==
== Publications ==


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!DOI
!DOI
|-
|-
|Autonomous Battery Optimization by Deploying Distributed Experiments and Simulations
|'''Autonomous Battery Optimization by Deploying Distributed Experiments and Simulations'''
|Advanced Energy Materials
|Advanced Energy Materials
|2024
|2024
|https://doi.org/10.1002/aenm.202403263
|https://doi.org/10.1002/aenm.202403263
|-
|-
|Materials acceleration platforms (MAPs): accelerating materials research and development to meet urgent societal challenges
|'''Materials acceleration platforms (MAPs): accelerating materials research and development to meet urgent societal challenges'''
|Advanced Materials
|Advanced Materials
|2024
|2024
|https://doi.org/10.1002/adma.202407791
|https://doi.org/10.1002/adma.202407791
|-
|-
|Surface, Structural, and Electrochemical Analysis of High-Voltage Spinel Cathode LiNi0. 5Mn1. 5O4 Evolution Upon Ambient Storage Conditions
|'''Surface, Structural, and Electrochemical Analysis of High-Voltage Spinel Cathode LiNi0. 5Mn1. 5O4 Evolution Upon Ambient Storage Conditions'''
|Journal of the Electrochemical Society
|Journal of the Electrochemical Society
|2023
|2023
|{{Template:Viewer/Link|page=|url=https://doi.org/10.1149/1945-7111/ad0263|label=https://doi.org/10.1149/1945-7111/ad0263}}
|{{Template:Viewer/Link|page=|url=https://doi.org/10.1149/1945-7111/ad0263|label=https://doi.org/10.1149/1945-7111/ad0263}}
|-
|-
|Brokering between tenants for an international materials acceleration platform
|'''Brokering between tenants for an international materials acceleration platform'''
|Matter
|Matter
|2023
|2023
|https://doi.org/10.1016/j.matt.2023.07.016
|https://doi.org/10.1016/j.matt.2023.07.016
|-
|-
|Principles of the Battery Data Genome
|'''Principles of the Battery Data Genome'''
|Joule
|Joule
|2022
|2022
|https://doi.org/10.1016/j.joule.2022.08.008
|https://doi.org/10.1016/j.joule.2022.08.008
|-
|-
|A roadmap for transforming research to invent the batteries of the future designed within the european large scale research initiative battery 2030+
|'''A roadmap for transforming research to invent the batteries of the future designed within the european large scale research initiative battery 2030+'''
|Advanced Energy Materials
|Advanced Energy Materials
|2022
|2022
|https://doi.org/10.1002/aenm.202102785
|https://doi.org/10.1002/aenm.202102785
|-
|-
|Rechargeable batteries of the future—the state of the art from a BATTERY 2030+ perspective
|'''Rechargeable batteries of the future—the state of the art from a BATTERY 2030+ perspective'''
|Advanced Energy Materials
|Advanced Energy Materials
|2022
|2022
|https://doi.org/10.1002/aenm.202102904
|https://doi.org/10.1002/aenm.202102904
|-
|-
|Digitalization of battery manufacturing: current status, challenges, and opportunities
|'''Digitalization of battery manufacturing: current status, challenges, and opportunities'''
|Advanced Energy Materials
|Advanced Energy Materials
|2022
|2022
|https://doi.org/10.1002/aenm.202102696
|https://doi.org/10.1002/aenm.202102696
|-
|-
|Toward a unified description of battery data
|'''Toward a unified description of battery data'''
|Advanced Energy Materials
|Advanced Energy Materials
|2022
|2022
|https://doi.org/10.1002/aenm.202102702
|https://doi.org/10.1002/aenm.202102702
|-
|-
|Innovative zinc-based batteries
|'''Innovative zinc-based batteries'''
|Journal of Power Sources
|Journal of Power Sources
|2021
|2021
|https://doi.org/10.1016/j.jpowsour.2020.229309
|https://doi.org/10.1016/j.jpowsour.2020.229309
|-
|-
|Data Management Plans: the Importance of Data Management in the BIG‐MAP Project
|'''Data Management Plans: the Importance of Data Management in the BIG‐MAP Project'''
|Batteries & Supercaps
|Batteries & Supercaps
|2021
|2021
|https://doi.org/10.1002/batt.202100117
|https://doi.org/10.1002/batt.202100117
|-
|-
|Cold sintering as a cost-effective process to manufacture porous zinc electrodes for rechargeable zinc-air batteries
|'''Cold sintering as a cost-effective process to manufacture porous zinc electrodes for rechargeable zinc-air batteries'''
|Processes
|Processes
|2020
|2020
|https://doi.org/10.3390/pr8050592
|https://doi.org/10.3390/pr8050592
|-
|-
|Designing aqueous organic electrolytes for zinc–air batteries: method, simulation, and validation
|'''Designing aqueous organic electrolytes for zinc–air batteries: method, simulation, and validation'''
|Advanced Energy Materials
|Advanced Energy Materials
|2020
|2020
|https://doi.org/10.1002/aenm.201903470
|https://doi.org/10.1002/aenm.201903470
|-
|-
|Towards Rechargeable Zinc-Air Batteries with Aqueous Chloride Electrolytes
|'''Towards Rechargeable Zinc-Air Batteries with Aqueous Chloride Electrolytes'''
|Journal of Materials Chemistry A
|Journal of Materials Chemistry A
|2019
|2019
|https://doi.org/10.1039/C9TA01190K
|https://doi.org/10.1039/C9TA01190K
|-
|-
|A review of model-based design tools for metal-air batteries
|'''A review of model-based design tools for metal-air batteries'''
|Batteries
|Batteries
|2018
|2018
|https://doi.org/10.3390/batteries4010005
|https://doi.org/10.3390/batteries4010005
|-
|-
|Rational development of neutral aqueous electrolytes for zinc–air batteries
|'''Rational development of neutral aqueous electrolytes for zinc–air batteries'''
|ChemSusChem
|ChemSusChem
|2017
|2017
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|-
|-
|2025
|2025
|How Semantic Technology Accelerates Battery Research
|{{Template:Viewer/Link|page=File:OSWe27032521f0b4d669eaa6e6f585ace46.pdf|url=|label=Putting the AI in FAIR: How Ontologies Unlock Battery Knowledge for the Agentic Era}}
|Battery2030+ Excellence Seminar
|{{Template:Viewer/Link|page=Item:OSW3dc790110508459489f954080a7bcb65|url=|label=POLiS Seminar}}
|-
|2025
|{{Template:Viewer/Link|page=Item:OSW380cbebbc6b441948ce5fde34679b504|url=|label=How Semantic Technology Accelerates Battery Research}}
|{{Template:Viewer/Link|page=Item:OSW380cbebbc6b441948ce5fde34679b504|url=|label=Battery2030+ Excellence Seminar}}
|-
|-
|2024
|2024
Line 183: Line 186:
|{{Template:Viewer/Link|page=|url=https://shows.acast.com/60b75c5b8c26f80013d5ebce/episodes/66c6c8aaf308cd1af3289a44?|label=The next generation of electric car batteries}}
|{{Template:Viewer/Link|page=|url=https://shows.acast.com/60b75c5b8c26f80013d5ebce/episodes/66c6c8aaf308cd1af3289a44?|label=The next generation of electric car batteries}}
|2025-08-22
|2025-08-22
|}
=== In the News ===
{| class="wikitable"
|+
!Year
!Outlet
!Link
|-
|2024
|Teknisk Ukeblad
|https://www.tu.no/artikler/de-som-venter-pa-faststoff-batterier-ma-vente-lenge-br/550330
|-
|2021
|Gemini.no
|https://gemini.no/2021/12/europeisk-batteriveikart-med-tydelig-norsk-avtrykk/
|-
|2020
|Teknisk Ukeblad
|https://www.tu.no/artikler/norge-far=sentral-rolle-i-eus-batteriprosjekt-skal-redusere-behovet-for-kritiske-ramaterialer-med-85-prosent-br/501116
|-
|2017
|DLR Magazine
|https://elib.dlr.de/117283/1/DLRmagazine_154-155_EN.pdf
|}
|}


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==== Battery Test Data ====
==== Battery Test Data ====
{| class="wikitable"
{| class="wikitable"
!Year
!Title  
!Title  
!Descrption
!Descrption
!DOI  
!DOI  
|-
|-
|2025
|[https://doi.org/10.5281/zenodo.15422338 EIS data of 54 21700 cells]
|This dataset contains electrochemical impedance spectroscopy (EIS) data collected from a batch of 21700 cylindrical NMC811 lithium-ion cells at a state of charge (SoC) of 30%. The measurement was performed using a Keysight SL1007A Scienlab Battery Test System in galvanostatic mode.
|https://doi.org/10.5281/zenodo.15422338
|-
|2025
|{{Template:Viewer/Link|page=Item:OSW81ec515cf7ed48488563e2f997b84d22|url=|label=Discharging Time Series of a CR2032 Battery at 11 mA}}
|{{Template:Viewer/Link|page=Item:OSW81ec515cf7ed48488563e2f997b84d22|url=|label=Discharging Time Series of a CR2032 Battery at 11 mA}}
|This dataset contains time series data collected during constant-current discharge of a VARTA CR2032 lithium coin cell at 11 mA using a BioLogic battery cycler.
|This dataset contains time series data collected during constant-current discharge of a VARTA CR2032 lithium coin cell at 11 mA using a BioLogic battery cycler.
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|An application ontology for the Linux Foundation Energy resource on battery data formats
|An application ontology for the Linux Foundation Energy resource on battery data formats
|
|
|}
== Community Service ==
=== Advisory Board ===
{| class="wikitable"
|+
!Year
!Role
!Organization
!Link
|-
|2025 - Present
|Steering Group Member
|Battery Parameter Exchange (BPX)
|https://bpxstandard.com/
|-
|2025 - Present
|Advisory Board Member
|{{Template:Viewer/Link|page=Item:OSWfe1fc1b42a054dc3ad168fa76c6ea179|url=|label=InnoBMS}}
|https://cordis.europa.eu/project/id/101137975
|-
|2024 - Present
|Associate Member
|{{Template:Viewer/Link|page=Item:OSW477fba7373e04e81acfd724d33743768|url=|label=Battery Data Alliance}}
|https://lfenergy.org/projects/battery-data-alliance/
|}
=== Examination Committee ===
{| class="wikitable"
!Year
!Degree
!Student
!University
!Thesis
|-
|2023
|PhD
|Alma Mathew
|{{Template:Viewer/Link|page=Item:OSW78e5fc5c6a524755a1685fe4315f3d93|url=|label=Uppsala University}}
|[https://www.uu.se/en/events/defences/2023-05-11-alma-mathew-lini0.5mn1.5o4-cathodes-for-lithium-ion-batteries-exploring-strategies-for-a-stable-electrode-electrolyte-interphase LiNi0.5Mn1.5O4 cathodes for lithium-ion batteries: Exploring strategies for a stable electrode-electrolyte interphase]
|-
|2021
|MSc
|Jonas Jensen
|{{Template:Viewer/Link|page=Item:OSW02ab1b78340040efaf16d2700b6f3aaf|url=|label=University of Oslo}}
|{{Template:Viewer/Link|page=|url=https://www.duo.uio.no/handle/10852/87510|label=Proton Exchange Membrane Water Electrolyzer Modeling}}
|}
== Conferences and Meetings ==
{| class="wikitable"
|+
!Year
!Conference
!Location
!Title
!Invited
!Contribution
!Project
|-
|2025
|{{Template:Viewer/Link|page=|url=https://semanticmaterials.com/|label=Semantic Materials Workshop 2025}}
|Cambridge, UK
|{{Template:Viewer/Link|page=File:OSW29439f0580eb4e0ab897f1892aa70aed.pdf|url=|label=A semantic approach to battery digital twins}}
|Invited
|Talk
|Matchmaker, {{Template:Viewer/Link|page=Item:OSWd364682b4d274585b8ab6fb6d237d890|url=|label=DigiBatt}}
|-
|2025
|{{Template:Viewer/Link|page=Item:OSW236091fec06f4604885bc84824e402b5|url=|label=Summer Academy for Modelling Batteries (SAMBA) 2025}}
|Copenhagen, Denmark
|{{Template:Viewer/Link|page=File:OSW4a526722638c4648bad2fa0f34b1d286.pdf|url=|label=How to Make Your Battery Data Work for You: A Practical Guide for Lasting Impact}}
|Inivted
|Talk
|{{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2025
|{{Template:Viewer/Link|page=Item:OSW0f4c09e4030841edbf472bd365921585|url=|label=STRIKE 2025}}
|Swansea, UK
|Digital Twin Solutions for Sodium-Ion Batteries
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSW619ef9c079964493888b72d639c3f58c|url=|label=SOSOBA}}
|-
|2025
|Connect to Power Up!
|Online
|National R&D Priorities and Trends in Norway
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2025
|BMFTR Battery Advisory Board Meeting
|Frankfurt, Germany
|How Battery 2030+ Fosters Collaboration and Standardization in European Battery Research
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2025
|{{Template:Viewer/Link|page=Item:OSW090b84a3ef3840ff96b0176c2995cd56|url=|label=Road Transport Research 2025}}
|Brussels, Belgium
|
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWbdaefbf2beb045c3912dcf136a804834|url=|label=HYDRA}}
|-
|2025
|{{Template:Viewer/Link|page=Item:OSWca6fcc5c25e64d2496e25e199ba43e90|url=|label=The Future of Energy is Green and Digital}}
|Oslo, Norway
|Digital Twin Solutions for a Greener, Smarter Grid
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWd364682b4d274585b8ab6fb6d237d890|url=|label=DigiBatt}}
|-
|2024
|{{Template:Viewer/Link|page=Item:OSW0f66e8aba73d4485b714b42dc39b4893|url=|label=ElectRoBatt 2024}}
|Bucharest, Romania
|{{Template:Viewer/Link|page=File:OSWe41f45561af94dd89ddbc371095c0db0.pdf|url=|label=The Digital Edge: How Data Drives Battery Breakthroughs}}
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWd364682b4d274585b8ab6fb6d237d890|url=|label=DigiBatt}}, {{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2024
|{{Template:Viewer/Link|page=Item:OSW63c92e057309431db7cd0bc5b09420b8|url=|label=BATTERY 2030+ Annual Conference}}
|Grenoble, France
|
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2024
|MRS Spring Meeting
|Online
|
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWa447d5f341294108879be0aac68cb1a4|url=|label=BIG-MAP}}, {{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2024
|EUnified Battery Data Space Workshop
|Grindelwald, Switzerland
|
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWa447d5f341294108879be0aac68cb1a4|url=|label=BIG-MAP}}, {{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2023
|Smart sensor batteries and the future battery generation
|San Sebastien, Spain
|Enhancing battery sensor data with semantic mappings
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWbdaefbf2beb045c3912dcf136a804834|url=|label=HYDRA}}, {{Template:Viewer/Link|page=Item:OSWa447d5f341294108879be0aac68cb1a4|url=|label=BIG-MAP}}
|-
|2023
|Oxford Battery Modelliong Symposium 2023
|Oxford, UK
|
|
|Poster
|{{Template:Viewer/Link|page=Item:OSWbdaefbf2beb045c3912dcf136a804834|url=|label=HYDRA}}
|-
|2023
|Road Transport Research 2023
|Brussels, Belgium
|
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWbdaefbf2beb045c3912dcf136a804834|url=|label=HYDRA}}
|-
|2022
|Teknologiutvikling av fremtidens hurtigbåter og ferger
|Oslo, Norway
|
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWbdaefbf2beb045c3912dcf136a804834|url=|label=HYDRA}}, {{Template:Viewer/Link|page=Item:OSWa447d5f341294108879be0aac68cb1a4|url=|label=BIG-MAP}}
|-
|2022
|NordBatt
|Gothenburg, Sweden
|
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWa447d5f341294108879be0aac68cb1a4|url=|label=BIG-MAP}}, {{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2022
|ECS Fall Meeting 2022
|Atlanta, GA USA
|
|
|Poster
|{{Template:Viewer/Link|page=Item:OSWa447d5f341294108879be0aac68cb1a4|url=|label=BIG-MAP}}, {{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2022
|Helt Grønn
|Trondheim, Norway
|
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWbdaefbf2beb045c3912dcf136a804834|url=|label=HYDRA}}
|-
|2022
|ONS 2022
|Stavanger, Norway
|
|Invited
|Talk
|{{Template:Viewer/Link|page=Item:OSWa447d5f341294108879be0aac68cb1a4|url=|label=BIG-MAP}}, {{Template:Viewer/Link|page=Item:OSW6499d04ced9649f8bbc50f1e940a50c8|url=|label=Battery2030+}}
|-
|2022
|ModVal 2022
|Germany
|
|
|Talk
|{{Template:Viewer/Link|page=Item:OSWbdaefbf2beb045c3912dcf136a804834|url=|label=HYDRA}}
|}
|}
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