Welcome
Join us in York in April 2026 for this edition of the Faraday Discussion series. The Faraday Discussions are unique international discussion meetings that address current and emerging topics at the forefront of the physical sciences.Why attend?
Find out more about Faraday Discussions in the video and FAQs – see Useful links on the right.A unique conference format that prioritises discussion
At a Faraday Discussion, the primary research papers written by the speakers are distributed to all participants before the meeting – ensuring that most of the meeting is devoted to discussing the latest research.
This provides a genuinely collaborative environment, where discussion and debate are at the foreground. All delegates, not just speakers, are invited to make comments, ask questions, or present complementary or contradictory measurements and calculations.
An exciting programme of talks – and more
Take part in a well-balanced mix of talks, discussion, poster sessions and informal networking, delivered by our expert events team. You can explore the full programme in the downloadable files on the right – whether you’re attending in-person or online, every minute provides an opportunity.
The conference dinner, included in the registration fee, contains the Marlow Cup ceremony: a unique commemoration of past Faraday Discussion organisers that is sure to encourage further discussions over dinner.
In-depth discussion with leaders in the field
World-leading and established researchers connect with each other and early-career scientists and postgraduate students to discuss the latest research and drive science forwards. It’s a unique atmosphere – and challenging others to get to the heart of the problem is encouraged!
Your contributions, published and citable
A citable record of the discussion is published in the Faraday Discussions journal, alongside the research papers. Questions, comments and remarks become a valuable part of the published scientific conversation, and every delegate can make a major contribution.
Themes
Vibrational spectroscopy at interfaces gives unparalleled insights into areas as far reaching as the transport of energy and matter, adsorbate identity and orientation, bond formation and dissociation, lattice dynamics and surface stress. As a result, it has the potential to offer insights into fundamental aspects of nearly every branch of interface science with examples as diverse as cell wall changes in the presence of antibiotics, the identification of transient heterogeneous catalyst intermediates, and understanding the complexities of the electrode/solution interface. With the advent of several new tools for vibrational spectroscopy at interfaces there is a high level of current interest in exploring vibrations at surfaces and so this is the perfect time to take stock of the state of the art, discuss the newest discoveries, share solutions to common problems and forecast the most promising areas for investigation in the future.The conference will be organised into four linked themes:
Analysis of complex systems
Surfaces can be heterogeneous in chemical structure and composition. The heterogeneity can span length scales from molecules to millimetres and involve multiple components, especially in biological systems.
- How do we tackle this problem of complexity?
- What can be learned from successful approaches to complex systems?
- Are data from complex systems being over-interpreted or interpreted through confirmation bias? What advances are being made to ensure reliable data interpretation?
Spectroscopy of static systems brings limited information about processes and pathways and there have been many recent advances in studying changing systems.
- What approaches are there for studying interfaces away from equilibrium and undergoing dynamical change on sub-second timescales?
- How do the recent improvements in temporal and spatial resolution affect the spectroscopy of interfaces?
- What are the latest developments in in situ vibrational spectroscopy.
Vibrations are of fundamental importance in many surface phenomena including transport of energy, matter and charge. Understanding these phenomena requires very high-level theory.
- What progress has there been in ab initio calculations of surface vibrations and how they are benchmarked to experimental measurements.
- How do state of the art calculations match experiment? What are the limits on the size and time scales of systems that can be modelled.
- What is holding us back from getting more done in silico?
The list of surface vibrational spectroscopy techniques is long and ever-growing. Where are the most important advances being made and is more progress needed?
- What is the state-of-the-art for new techniques in the field?
- What techniques, if any are best for which questions?
- What questions remain that might require new approaches?
