🔬 Postdoc in Computational Chemistry at DTU - Technical University of Denmark 🌍⚛️
Ready to advance molten salt reactor technology? Join DTU Chemistry in a cross-disciplinary project shaping the future of sustainable nuclear energy!
👉 Position: Postdoc in Chemistry
👉 Focus: Atomistic & thermodynamic modeling of molten salts
👉 Start: January 2026
👉 Duration: 2 years
👉 Your mission:
✅ Model molten salts and their complex behavior
✅ Explore solvation of fission, activation & corrosion products
✅ Apply ab initio and classical MD simulations (cp2k, LAMMPS, VASP, MetalWalls)
✅ Use CALPHAD thermodynamics (FactSage, Thermochimica, Thermo-Calc) for multicomponent systems
✅ Investigate machine-learning potentials for molten salt simulations
This is a unique collaboration between DTU Chemistry, DTU Physics, DTU Construct, and DTU Energy – combining theory, modeling, and innovation to tackle key challenges in MSR development.
📌 Requirements: PhD in physics, chemistry, or materials science + experience in computational chemistry and thermodynamics
📅 Apply by: 15 December 2025
🔗 Find details in the job advert at: https://lnkd.in/dyNinmpU
Ready to advance molten salt reactor technology? Join DTU Chemistry in a cross-disciplinary project shaping the future of sustainable nuclear energy!
👉 Position: Postdoc in Chemistry
👉 Focus: Atomistic & thermodynamic modeling of molten salts
👉 Start: January 2026
👉 Duration: 2 years
👉 Your mission:
✅ Model molten salts and their complex behavior
✅ Explore solvation of fission, activation & corrosion products
✅ Apply ab initio and classical MD simulations (cp2k, LAMMPS, VASP, MetalWalls)
✅ Use CALPHAD thermodynamics (FactSage, Thermochimica, Thermo-Calc) for multicomponent systems
✅ Investigate machine-learning potentials for molten salt simulations
This is a unique collaboration between DTU Chemistry, DTU Physics, DTU Construct, and DTU Energy – combining theory, modeling, and innovation to tackle key challenges in MSR development.
📌 Requirements: PhD in physics, chemistry, or materials science + experience in computational chemistry and thermodynamics
📅 Apply by: 15 December 2025
🔗 Find details in the job advert at: https://lnkd.in/dyNinmpU
lnkd.in
LinkedIn
This link will take you to a page that’s not on LinkedIn
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Unlock Advanced Insights: 🎦 SummerSchool Lectures Now on YouTube!
We’re thrilled to announce that the full lecture recordings from our 2025 Summer School on Spectroscopy and Electronic Structure of Transition Metal Complexes are now available on YouTube!
Held from September 7–12 at the Mülheim Chemistry Campus, this intensive program brought together emerging chemists to explore cutting-edge spectroscopic methods and computational tools, with a special focus on leveraging ORCA software for first-principles quantum chemical calculations.
Why watch these lectures?
Whether you’re a student diving into transition metal chemistry or a researcher refining your computational skills, these sessions offer:
Foundational & advanced knowledge: From ligand field theory to Mössbauer spectroscopy.
Expert insights: Lectures by leading scientists, including Frank Neese, Serena DeBeer, Dimitrios Pantazis, Daniel J SantaLucia, and more.
Featured topics:
🔹 Introduction to Computational Chemistry
🔹 Group Theory and Ligand Field Theory
🔹 Optical, X-ray, and Vibrational Spectroscopy
🔹 Spin Hamiltonians, Magnetochemistry, and EPR
🔹 MCD and Mössbauer Spectroscopy
Perfect for: Chemistry students passionate about both spectroscopic techniques and computational modeling, and how they combine to decode complex molecular behavior!
Find access to all lectures via the link in the comments!
Spread the word, share with peers, and revisit these invaluable resources anytime. Let’s keep the learning going!
Find all lectures here: https://youtube.com/playlist?list=PL4lkhPVEEMVijdazRAOmhQ7gGKBJ7aQby&si=QWeEIi3hV0ob-9H_
We’re thrilled to announce that the full lecture recordings from our 2025 Summer School on Spectroscopy and Electronic Structure of Transition Metal Complexes are now available on YouTube!
Held from September 7–12 at the Mülheim Chemistry Campus, this intensive program brought together emerging chemists to explore cutting-edge spectroscopic methods and computational tools, with a special focus on leveraging ORCA software for first-principles quantum chemical calculations.
Why watch these lectures?
Whether you’re a student diving into transition metal chemistry or a researcher refining your computational skills, these sessions offer:
Foundational & advanced knowledge: From ligand field theory to Mössbauer spectroscopy.
Expert insights: Lectures by leading scientists, including Frank Neese, Serena DeBeer, Dimitrios Pantazis, Daniel J SantaLucia, and more.
Featured topics:
🔹 Introduction to Computational Chemistry
🔹 Group Theory and Ligand Field Theory
🔹 Optical, X-ray, and Vibrational Spectroscopy
🔹 Spin Hamiltonians, Magnetochemistry, and EPR
🔹 MCD and Mössbauer Spectroscopy
Perfect for: Chemistry students passionate about both spectroscopic techniques and computational modeling, and how they combine to decode complex molecular behavior!
Find access to all lectures via the link in the comments!
Spread the word, share with peers, and revisit these invaluable resources anytime. Let’s keep the learning going!
Find all lectures here: https://youtube.com/playlist?list=PL4lkhPVEEMVijdazRAOmhQ7gGKBJ7aQby&si=QWeEIi3hV0ob-9H_
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8th International Mini-Symposium on Molecular Machine Learning
🔗Register here: https://lnkd.in/dPTaN7D2
🗓 Date: January 15th, 2026
🕒 Time: 3:00 PM (UTC+1)
💻 Location: Online | Free of charge | Limited number of Participants
👇 Meet this years amazing set of speakers:
🔹Marwin Segler (Microsoft Research AI for Science, UK)
"Deep Learning for Molecules: The First Decade & what’s next"
🔹Kjell Jorner (ETH Zürich, Switzerland)
"Towards generative models for catalyst discovery"
🔹Esther Heid (TU Vienna, Austria)
"Machine-Learned Chemical Reactivity"
🔹Robert Paton (Colorado State University, USA)
"Data-Driven Approaches for Computational Organic Chemistry"
Please share with your network! We look forward to seeing you there.
🔗Register here: https://lnkd.in/dPTaN7D2
🗓 Date: January 15th, 2026
🕒 Time: 3:00 PM (UTC+1)
💻 Location: Online | Free of charge | Limited number of Participants
👇 Meet this years amazing set of speakers:
🔹Marwin Segler (Microsoft Research AI for Science, UK)
"Deep Learning for Molecules: The First Decade & what’s next"
🔹Kjell Jorner (ETH Zürich, Switzerland)
"Towards generative models for catalyst discovery"
🔹Esther Heid (TU Vienna, Austria)
"Machine-Learned Chemical Reactivity"
🔹Robert Paton (Colorado State University, USA)
"Data-Driven Approaches for Computational Organic Chemistry"
Please share with your network! We look forward to seeing you there.
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Dear Computational and Quantum Chemistry followers ⚛️ :
During the last weeks, we have been receiving in the Comp Chem group a huge quantity of spam messages from fake accounts and bots with cryptocurrency scams and Not Safe for Work (NSFW) content. Clicking into those malicious links can lead to hacking, data stealing, identity theft and so on. In order to reduce the risk of dangerous content reaching this group, we've added two group manager bots which are constantly looking for any intrusion.
If you see a doubtful message, you can report it via Rose bot with the command
Let's keep ourselves safe on the internet and make the stay in the group the most pleasant to all members. Cheers and have a nice weekend.
During the last weeks, we have been receiving in the Comp Chem group a huge quantity of spam messages from fake accounts and bots with cryptocurrency scams and Not Safe for Work (NSFW) content. Clicking into those malicious links can lead to hacking, data stealing, identity theft and so on. In order to reduce the risk of dangerous content reaching this group, we've added two group manager bots which are constantly looking for any intrusion.
If you see a doubtful message, you can report it via Rose bot with the command
\report, or via tagging the admins @<admin>. Let's keep ourselves safe on the internet and make the stay in the group the most pleasant to all members. Cheers and have a nice weekend.
❤11
The other bot which is managing this group is Protectron. Protectron will ban automatically any user who sends cryptoscams or NSFW content.
UCSF ChimeraX version 1.11 has been released!
This will be the last release to support Red Hat Enterprise Linux 8 and
its derivatives.
ChimeraX includes user documentation and is free for noncommercial use.
Download for Windows, Linux, and MacOS from:
https://www.rbvi.ucsf.edu/chimerax/download.html
Updates since version 1.10.1 (July 2024) include:
- 2D Labels and Arrows GUI
- Boltz 2 structure prediction of proteins, nucleic acids, and
small-molecule ligands, with affinity prediction
- Boltz 2 batch ligand-binding predictions (many ligands to same receptor)
- General minimization (including ligands) with Minimize Structure tool
and "minimize" command
- new ViewDock interface (replacing previous ViewDockX)
- new types of trajectory plots: H-bonds, RMSD
- save trajectory plots to image file
- Thermal Ellipsoids GUI
- "chirality" command to report stereocenter chirality
- save/restore scenes including atomic, ribbon, and volume styles and
coloring; more to be added later
For details, please see the ChimeraX change log:
https://www.rbvi.ucsf.edu/trac/ChimeraX/wiki/ChangeLog
This will be the last release to support Red Hat Enterprise Linux 8 and
its derivatives.
ChimeraX includes user documentation and is free for noncommercial use.
Download for Windows, Linux, and MacOS from:
https://www.rbvi.ucsf.edu/chimerax/download.html
Updates since version 1.10.1 (July 2024) include:
- 2D Labels and Arrows GUI
- Boltz 2 structure prediction of proteins, nucleic acids, and
small-molecule ligands, with affinity prediction
- Boltz 2 batch ligand-binding predictions (many ligands to same receptor)
- General minimization (including ligands) with Minimize Structure tool
and "minimize" command
- new ViewDock interface (replacing previous ViewDockX)
- new types of trajectory plots: H-bonds, RMSD
- save trajectory plots to image file
- Thermal Ellipsoids GUI
- "chirality" command to report stereocenter chirality
- save/restore scenes including atomic, ribbon, and volume styles and
coloring; more to be added later
For details, please see the ChimeraX change log:
https://www.rbvi.ucsf.edu/trac/ChimeraX/wiki/ChangeLog
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Mol* (/'molstar/) is a modern web-based open-source toolkit for visualisation and analysis of large-scale molecular data
High-performance graphics and data handling of the Mol* Viewer allow users to simultaneously visualise up to hundreds of (superimposed) protein structures, play molecular dynamics trajectories, render cell-level models at atomic detail with tens of millions of atoms, or display huge models obtained by I/HM such as the Nuclear Pore Complex.
https://molstar.org
High-performance graphics and data handling of the Mol* Viewer allow users to simultaneously visualise up to hundreds of (superimposed) protein structures, play molecular dynamics trajectories, render cell-level models at atomic detail with tens of millions of atoms, or display huge models obtained by I/HM such as the Nuclear Pore Complex.
https://molstar.org
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⚛️ CELEBRATING 100 YEARS OF QUANTUM CHEMISTRY ⚛️
🎉 As we close 2025, we celebrate a full century since quantum mechanics revolutionized chemistry! From Heisenberg's matrix mechanics (1925) to today's computational chemistry, our field has been transformed.
🧪 I've created an interactive timeline featuring the quantum revolution in chemistry:
✨ 150+ pivotal discoveries
👨🔬 Schrödinger equation, molecular orbitals, valence bond theory
🔬 Hückel, Pauling, Mulliken, Roothaan, and many more
💻 From hand calculations to modern DFT
🎨 Beautiful, searchable interface
Explore milestones like:
- Schrödinger's wave equation (1926)
- Pauling's chemical bonding theory (1928)
- Molecular orbital theory (1927-1932)
- Born-Oppenheimer approximation (1927)
- And much more through contemporary quantum chemistry!
🔗 Access the Interactive Timeline https://claude.ai/public/artifacts/b043caba-d1fb-457a-a600-db0f6d689571
---
🎄 Happy Holidays, Quantum Chemists! 🎁
May your calculations converge, your basis sets be complete, and your holidays be filled with joy!
Wishing everyone peaceful celebrations and an inspiring 2026! ✨
_"Chemistry is quantum mechanics in action!"_
#QuantumChemistry #ComputationalChemistry #Quantum100 #HappyHolidays #MolecularOrbital
🎉 As we close 2025, we celebrate a full century since quantum mechanics revolutionized chemistry! From Heisenberg's matrix mechanics (1925) to today's computational chemistry, our field has been transformed.
🧪 I've created an interactive timeline featuring the quantum revolution in chemistry:
✨ 150+ pivotal discoveries
👨🔬 Schrödinger equation, molecular orbitals, valence bond theory
🔬 Hückel, Pauling, Mulliken, Roothaan, and many more
💻 From hand calculations to modern DFT
🎨 Beautiful, searchable interface
Explore milestones like:
- Schrödinger's wave equation (1926)
- Pauling's chemical bonding theory (1928)
- Molecular orbital theory (1927-1932)
- Born-Oppenheimer approximation (1927)
- And much more through contemporary quantum chemistry!
🔗 Access the Interactive Timeline https://claude.ai/public/artifacts/b043caba-d1fb-457a-a600-db0f6d689571
---
🎄 Happy Holidays, Quantum Chemists! 🎁
May your calculations converge, your basis sets be complete, and your holidays be filled with joy!
Wishing everyone peaceful celebrations and an inspiring 2026! ✨
_"Chemistry is quantum mechanics in action!"_
#QuantumChemistry #ComputationalChemistry #Quantum100 #HappyHolidays #MolecularOrbital
Claude
Timeline of Quantum Mechanics: 200+ Years of Discovery
Explore an interactive timeline of quantum mechanics from 1801-2015. Search events, filter by era, and discover 100+ scientists who revolutionized physics.
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BondCraft Core
Sketch Freely - Draw Precisely
BondCraft is an intuitive, browser-based chemical structure editor. Create complex molecules, mechanisms, and publishable figures without installing any software.
Key Features:
* Zero friction: It runs entirely in the browser with no login or download needed.
* Smart Chemistry: It automatically calculates implicit hydrogens (handling expanded octets for Sulfur/Phosphorus) and computes formal charges in real-time.
* Validation: The system highlights impossible atoms (like pentavalent carbons) with a "Red Wavy Halo" to warn you if you break the Octet Rule.
* Stereochemistry: Automatic assignment of (R)/(S) configurations based on full CIP Priority Rules.
* Export: You can copy canonical/isomeric SMILES strings directly or export high-quality SVG and PNG images. You can also save and load your projects.
* Multilingual: The interface is available in English, Spanish, French, German, and Italian.
https://www.bondcraft.net
Sketch Freely - Draw Precisely
BondCraft is an intuitive, browser-based chemical structure editor. Create complex molecules, mechanisms, and publishable figures without installing any software.
Key Features:
* Zero friction: It runs entirely in the browser with no login or download needed.
* Smart Chemistry: It automatically calculates implicit hydrogens (handling expanded octets for Sulfur/Phosphorus) and computes formal charges in real-time.
* Validation: The system highlights impossible atoms (like pentavalent carbons) with a "Red Wavy Halo" to warn you if you break the Octet Rule.
* Stereochemistry: Automatic assignment of (R)/(S) configurations based on full CIP Priority Rules.
* Export: You can copy canonical/isomeric SMILES strings directly or export high-quality SVG and PNG images. You can also save and load your projects.
* Multilingual: The interface is available in English, Spanish, French, German, and Italian.
https://www.bondcraft.net
BondCraft Core
Free chemistry drawing tool. Create molecular structures and export SVG/PNG figures directly from your browser.
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🌞 SO3LR v0.1.0 is out!
A major update to our open-source machine-learned force field for (bio)molecular simulations. This release adds a unified command-line interface (opt, eval, nve, nvt, npt), fine-tuning support, seamless restarts, and improved performance (2x faster npt). We also expanded the documentation with new examples, including a Colab notebook you can run directly in the browser. It's been great to see more people trying SO3LR and sharing feedback!
code: https://github.com/general-molecular-simulations/so3lr
paper: https://doi.org/10.1021/jacs.5c09558
A major update to our open-source machine-learned force field for (bio)molecular simulations. This release adds a unified command-line interface (opt, eval, nve, nvt, npt), fine-tuning support, seamless restarts, and improved performance (2x faster npt). We also expanded the documentation with new examples, including a Colab notebook you can run directly in the browser. It's been great to see more people trying SO3LR and sharing feedback!
code: https://github.com/general-molecular-simulations/so3lr
paper: https://doi.org/10.1021/jacs.5c09558
GitHub
GitHub - general-molecular-simulations/so3lr: SO3krates and Universal Pairwise Force Field for Molecular Simulation
SO3krates and Universal Pairwise Force Field for Molecular Simulation - general-molecular-simulations/so3lr
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#Postdoc (2Y) in Marseille:
Exciton transport in bioinspired DNA-templated light-harvesting networks. NEGF, exciton-vibration, decoherence; close link to experiments.
Deadline: 23/1
Start: 27/4
More info: fabienne.michelini @ univ-amu.fr
#QuantumTransport #CompChem
Exciton transport in bioinspired DNA-templated light-harvesting networks. NEGF, exciton-vibration, decoherence; close link to experiments.
Deadline: 23/1
Start: 27/4
More info: fabienne.michelini @ univ-amu.fr
#QuantumTransport #CompChem
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Berkeley Lab: Hybrid Simulation Reveals How Electrons Drive Chemical Reactions in Liquids
A team of researchers, including Berkeley Lab Alvarez Fellow Pinchen Xie, has develo - https://www.hpcwire.com/off-the-wire/berkeley-lab-hybrid-simulation-reveals-how-electrons-drive-chemical-reactions-in-liquids/
A team of researchers, including Berkeley Lab Alvarez Fellow Pinchen Xie, has develo - https://www.hpcwire.com/off-the-wire/berkeley-lab-hybrid-simulation-reveals-how-electrons-drive-chemical-reactions-in-liquids/
HPCwire
Berkeley Lab: Hybrid Simulation Reveals How Electrons Drive Chemical Reactions in Liquids - HPCwire
Jan. 8, 2026 — A team of researchers, including Berkeley Lab Alvarez Fellow Pinchen Xie, has developed a groundbreaking computer modeling technique that combines quantum physics with machine learning. This new approach allows scientists to accurately and…
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