The next edition of the Tulip Summer School on Modern Developments in Spectroscopy will be held in Noordwijk, The Netherlands, on April 14-17, 2015. The Tulip School is organized under the auspices of the Holland Research School of Molecular Chemistry (HRSMC).
The Tulip VI School follows the format of the previous Schools organized in the spring of 2001, 2003, 2006, 2009, and 2012. Highly qualified scientists will present introductory and specialized lectures on various topics in the field of spectroscopic and dynamical studies of molecular systems. The topics range from attosecond physics and spectroscopy, chiroptical spectroscopies, spectroscopy and metrology, advanced nano-biophysical microscopy, teraherz spectroscopy, to kinetics and dynamics of elementary chemical/biophysical processes
Each lecturer will present a 4 hour course.
The courses in 2015 will be given by the following invited lecturers:
Prof. Paul Corkum, National Research Council-Canada, University of Ottawa, Canada Prof. John Doyle, Harvard University, USA Prof. Kjeld Eikema, VU University Amsterdam, The Netherlands Prof. Jorg Enderlein, Universität Göttingen, Germany Prof. Martina Havenith, Ruhr-Universität Bochum, Germany Prof. David Nesbitt, University of Colorado, Boulder, USA
Location: Noordwijk, The Netherlands
Date : 14-17 April 2012
Website : http://www.hrsmc.nl/upcoming-events
Audience: PhD students and Postdocs
The CECAM School on: “Theoretical Spectroscopy Lectures: theory and codes” reaches the 6th edition and takes place from 18th to 22th of May, 2015 at the CECAM-HQ-EPFL, Lausanne, Switzerland.
Electronic excitations are probed by experimental techniques such as optical absorption, EELS and photo-emission (direct or inverse). From the theory point of view, excitations and excited state properties are out of the reach of density-functional theory (DFT), which is a ground-state theory. In the last twenty years other ab-initio theories and frameworks, which are able to describe electronic excitations and spectroscopy, have become more and more used: time-dependent density-functional theory (TDDFT) and many-body perturbation theory (MBPT) or Green’s function theory (GW approximation and Bethe-Salpeter equation BSE). In fact, computational solutions and codes have been developed in order to implement these theories and to provide tools to calculate excited state properties.The present school focuses on these points, covering theoretical, practical, and also numerical aspects of TDDFT and MBPT, and codes implementing them (ABINIT, DP, EXC).
The presentation of the theory will be followed by practical classes and hands-on tutorials. At the end of the school, students will have sufficient working knowledge to pursue their projects at their home institution. The participants are expected to have a fair knowledge of DFT prior to the school (see Ref. 1, given in the school’s website) and to be familiar with one plane-wave pseudopotential based software.
Indeed, although at the beginning of the school, we will make sure that the DFT level of all participants is enough in this respect and provide the needed complementary information and training, the purpose of the school is to go beyond DFT, with hands-on exercices based on plane-wave implementations.
The deadline for application is on 15 April 2015, but giving the limited number of places (around 25) many applications will be considered even before the deadline. Especially student candidates coming from outside EU are encouraged to register soon: an answer to them will be given as soon as possible for VISA and traveling purposes.
In order to apply for the school, please go to: http://www.cecam.org/workshop-1136.html
A 10-days Hands-on Tutorial Workshop on Density-functional theory and beyond: First-principles simulations of molecules and materials will be held on July 13 to 23, 2015, at Harnack House Berlin (http://th.fhi-berlin.mpg.de/sitesub/meetings/dft-workshop-2015/)
This ten-day Hands-On Tutorial Workshop introduces the basic and current developments in electronic structure theory for an intended audience of researchers entering the field. Morning lectures on the most important topics will be given by a field of international experts, complemented by afternoon hands-on sessions – practical exercises with computers – to deepen selected topics. For example, we cover:
* Density-functional theory (DFT) and quantum chemical approaches
* The most important numerical implementations
* Advanced functionals (capabilities and limits!)
* Electronic structure theory “beyond traditional Kohn-Sham DFT” (including GW, TDDFT, many-body formalisms)
* Ab initio molecular dynamics and nuclear quantum effects
* Multiscale approaches and statistical learning based on first principles
… and a wide range of other topics.
The application and poster-abstract submission interfaces for the workshop are now open until March 31. For space reasons, the number of participants will be limited to approximately 70. Acceptance decisions will be made within 2 weeks after the deadline (April 15, 2015).
Limited funds for financial support are available.
See the web page for details:
1st MOLIM Training School (MTS1) “Molecular Potentials and Dynamics: The Starting Journey”, supported by the COST program Molecules in Motion (MOLIM) (http://cost-molim.eu), will be held from March 30 to April 3, 2016, in Curia, Portugal. The scientific program of MTS1 focuses both on experimental and theoretical studies of molecular interactions, collision dynamics, spectroscopy, and related fields. MTS1 involves 11 invited trainers from 8 countries, who were asked to summarize at an introductory post-graduate level the topics of their presentations, with the objective of revealing the basic knowledge for the trainees to understand the current thinking of leading research within their field. It is hoped that their authoritative contributions presented at MTS1 will also appeal to non-specialists through their clear and broad introductions to the field as well as references to the accessible literature. MTS1 will comprise contributions covering a wide range of topics, from electronic and ro-vibrational structure theory of molecules and clusters to dynamics of elastic, inelastic and reactive encounters between atoms, molecules, ions, clusters, and surfaces.
It will also have a section for the trainees to report their own ongoing work via presentation of posters at the end of every day during the TS.
The invited speakers include:
S. Adhikari (Calcutta – India)
J. L. Alonso (Valladolid – Spain)
A. G. Császár (Budapest – Hungary)
R. Fausto (Coimbra – Portugal)
M. Hochlaf (Paris – France)
D. Per Jensen (Wuppertal – Germany)
I. Kleiner (Paris – France)
T. J. Martinez (Stanford – CA, USA)
A. J. C. Varandas (Portugal)
W.-T. Yang (Durham – NC, USA)
G. Zerbi (Milano, Italy)
The number of trainees is limited to 74 according to the following distribution:
30 trainees (with full accommodation and local travelling support from COST)
16 trainees (with partial support from COST; 8 meals)
28 (at maximum) trainees not supported by COST.
Detailed information can be found at http://www.uc.pt/go/molim2016 with pre-registration open. Grant applications and poster submissions will open soon.
Looking forward to see you in Curia
A.J.C. Varandas and R. Fausto
The tutorial will be organized in 4 theoretical and 5 practical sessions, the latter taking place in the computer lab. The theoretical sessions will be of 4.5 hours and practical sessions will last 4 hours. The school will comprise 3 didactic blocks.
The first block will have an introductory character and will offer an overview of the field. The following block will focus on mono- and multi-configurational electronic structure methods for the description of excited states. The last block will cover dynamics methodologies. (see description below). The school will end with a comprehensive overview (2 hours) of state-of-the-art applications, limitations, suitabilities, future perspectives and challenges of the different static and dynamical approaches described in the school.
1st Block (6 hours): Overview of modern electronic and vibrational photochemistry. Born-Oppenheimer approximation. Ground and excited potential energy surfaces topology and light-matter interaction. Building bridges between experiment and theory: theoretical approaches to simulate steady state and transient absorption spectra. Excited state deactivation processes.
2nd Block (18 hours): Quantum Chemical Calculations of Excited States: Mono- and Multiconfigurational Methods. CASSCF and RASSCF methods. Choice of the active space. Single vs. state-average calculations. Basis sets considerations. Introducing dynamical correlation: the CASPT2 method. CASPT2 problems and solutions. DFT. Runge-Gross theorems. Linear response TDDFT. Propagation of the electronic density. Spectra calculation. Approximation of xc-functionals. This block includes 3 practical sessions of 4 hours each, comprising introductions to MOLCAS and OCTOPUS codes, simulation of absorption spectra and exploration of the topography of potential energy surfaces (location of stationary points and surface crossings).
3rd Block (14 hours): Wave Packet propagations and semiclassical dynamics. Time-evolution operator, propagation. Relaxation method, filtering method. Interaction with an electric field. Correlation functions, spectra and eigenfunctions. Pump-probe spectroscopy and control, including an introduction to optimal control theory and local control. Born-Oppenheimer and Ehrenfest dynamics. Nonadiabatic dynamics, Tully’s surface hopping. This block includes 2 practical sessions of 4 hours each, introducing quantum and semiclassical dynamics techniques.
The tutorial will cover the fundamentals and the practical use of state-of-the-art codes for the calculation of the electronic structure of bulk solids, surfaces, and defects and impurities in solids. This includes applications in thermodynamical properties, phase transitions, temperature and pressure effects, magnetic and spectroscopic properties, and surface properties including reactivity of and at surfaces. The influence of structural vacancies both in bulk and at surfaces will be addressed as an important topic influencing in a significant way the properties of different materials. The chemical reactivity of surfaces will be the subject of one of the lectures of the course, with a full discussion of different aspects of the modelling of the CO oxidation in a Y-doped TiO2 supported gold nanoparticles catalyst. That is, in summary, the content of the main theoretical and practical sessions, grouped into 8 and 4 subjects, respectively.
(Theo-1) Symmetry (Pablo García Fernández)
Summary of basic concepts. Space groups. Tensor quantities. Crystal strain. Bloch theorem. The symmetry of the wavefunction under periodic boundary conditions.
(Theo-2) Electronic structure. (Cristina Díaz)
Cluster and periodic models. Atomistic models. Kohn-Sham equations and DFT methodologies. Electronic structure calculations. Phonons and crystal searching.
(Theo-3) Thermodynamic properties. (Cristina Díaz)
Static models. Equation of state of solids. Phase transitions. Mechanisms and kinetics of phase transitions. Thermal effects.
(Theo-4) Chemical bonding and microscopic approach. (Julia Contreras)
Topologies of scalar fields in crystals. Electron density, electron localization function and reduced density gradient chemical functions. Chemical origin of compresibility. Chemical bonding reconstruction along a phase transition.
(Theo-5) Ab initio simulation of the structure, thermodynamic properties and reactivity in surfaces. (Antonio Márquez)
Computational models in Surface Science. Structure of surfaces: Tasker’s classification of ionic surfaces. Relaxation, rumpling, and reconstruction of surfaces. Surface energies. Surface defects: O vacancies in metal oxides. Adsorption at surfaces. Case studies: organic molecules and transition metal atoms at oxide surfaces. Reactivity at surfaces: organic molecules at simple surfaces. Role of point defects. Case study: CO oxidation on an oxide supported metal catalyst. Case study: highly correlated metal oxides: the case of ceria.
(Theo-6) Ab initio simulation of magnetic and optical properties, and structural instabilities of solids. (Miguel Moreno)
Introduction: Role of impurities in crystalline solids. Impurities in insulators. Localization. What are the calculations useful for? Substitutional Transition Metal Impurities in insulators: Description of states. Study of Model Systems: interatomic distances and colour. The colour of gemstones containing Cr3+. Static Jahn-Teller effect: description. Static Jahn-Teller effect: experimental evidence. Insight into the Jahn-Teller effect. Off centre motion of impurities: evidence and characteristics. Origin of the off centre distortion. Softening around impurities.
(Theo-7) Magnetic interactions in Molecules and Solids: Basic concepts and Spin Hamiltonians (Coen de Graaf)
Spin Hamiltonians. Effective Hamiltonian theory. Magnetism in condensed matter. Spin waves for ferromagnets. Antiferromagnetic lattices. Electron transport. Quantum Chemical approach to solid state magnetism. Four center interactions in cuprates.
(Theo-8) Magnetic anisotropy, Double exchange and spin wave theory (Coen de Graaf)
2nd MOLIM Training School: Advanced technics for molecular spectroscopy and dynamics
The 2nd MOLIM Training School focuses on the recent experimental developments occurred in the field of molecular spectroscopy and reaction dynamics. World-wide experts working in European country will be invited to present the most relevant state-of-the-art techniques and their applications. The trainees will benefit from visits of the brand new laser servers ATTOLAB and CILEX as well as of the synchrotron SOLEIL. By team of 2 to 3 trainees, the students will be involved in a laboratory project hosted in several laboratories of the Paris-Saclay University.
The registration is open to Master students, Ph.D students, post-docs and permanent scientist from all European countries. Affiliation to the COST MOLIM is not required to participate to this school. The school can welcome up to 40 Europeans trainees and 10 more students from Paris region.
The registration deadline is fixed at Feb 24th 2017. Booking of rooms by the Committee will be possible up to Jan. 31st 2017.
Knuth Asmis (Leipzig, D)
Valérie Blanchet (Bordeaux, FR)
Juraj Fedor (Prague, CZ)
Gustavo Garcia (Paris-Saclay, France)
Katharina Kohse-Höinghaus (Bielefeld, D)
Anne Lafosse (ISMO, F)
Franck Lépine (Lyon, FR)
Andrew Orr-Ewing (Bristol, UK)
Katharine Reid (Nothingham, UK)
Claire Vallance (Oxford, UK)
Katalin Varjú (Szeged, HU)
Roland Wester (Innsbruck, AU)
Organizing Comittee :
The International school on “The Frontiers of Attosecond and Ultrafast X-ray Science” will be held from 19th to 28th March 2017 in Erice, Sicily, Italy.
The primary objective of this new school is to educate the next generation of scientists who will impact the future of attosecond and ultrafast x-ray science. We anticipate that the school will meet on a regular basis every two years and become a foundation for the ultrafast community. Consequently, the main topics of the course are the following: (i) attosecond science and technology, devoted to the generation and application of attosecond pulses to the investigation of electronic dynamics in atoms, molecules, nanostructures and condensed phases; (ii) fundamentals, methods and applications of free electron lasers, synchrotron radiation, ion collisions in atomic and molecular science. Lectures will cover current developments in theory and experiments but are also intended to give the basics of the field.
Please note that, PhD students and post-docs willing to attend the school can apply for scholarships (deadline 30 January 2017). For more details see: http://www.erice-attosecond.it/registration
The school co-organised by XLIC COST Action and sponsored by Politecnico di Milano, Italian Ministry of Education and Scientific Research, Sicilian Regional Parliament, ELI-ALPS and Ettore Majorana Foundation and Centre for Scientific Culture.
Louis Di Mauro, Alicja Domaracka, Mauro Nisoli and Sergio Martellucci
Where: CECAM Headquarters, Lausanne, Switzerland
When: June 12-16, 2017
Application deadline: February 28, 2017
This is a singular opportunity for students and postdocs. The school will be very similar to the previous one at IPAM last year (http://www.ipam.ucla.edu/programs/summer-schools/putting-the-theory-back-in-density-functional-theory/) with a similar line-up of excellent lecturers. We also provide limited support for student accommodation.
Last year, at least 30,000 scientific papers reported the results of DFT calculations. Many workshops and schools teach how to run a specific code. The purpose of this school is to teach the theory behind DFT. Lectures will be pedagogical and range from fundamentals to the latest approximations. The school is primarily targeted at junior researchers (Ph.D. students and postdocs) who are currently running DFT calculations and/or developing DFT or are interested in learning more about DFT. Internationally renowned experts in DFT will provide a thorough training in the fundamental theory through lectures and pedagogical research talks that connect themes of the lectures to the lecturers’ own cutting-edge research.
Mel Levy (Tulane University), John Perdew (Temple University), Hardy Gross (Max Planck Institute of Microstructure Physics) Weitao Yang (Duke University) Kieron Burke (University of California, Irvine) Leeor Kronik (Weizmann Institute) Neepa Maitra (Hunter College, CUNY) Adrienn Ruzsinszky (Temple University) Adam Wasserman (Purdue University)
Fill out the application form on the school web site. Submit one letter of recommendation from your academic advisor (via email to email@example.com). Participants are strongly encouraged to present a poster. Applications arriving by February 28, 2017 will receive full consideration.
Attila Cangi (Sandia National Laboratories) Kieron Burke (University of California, Irvine) Hardy Gross (Max Planck Institute of Microstructure Physics)
The recent development of novel light sources like x-ray free-electron lasers and table-top lasers for high-harmonic generation, which are capable of delivering controllable sequences of intense sub-femtosecond ionizing pulses, has opened the way to monitor and control electron dynamics in atoms and molecules at its natural time scale, the attosecond (Chem. Rev. 2017, DOI: 10.1021/acs.chemrev.6b00453). The description of the coherent superposition of electronic continuum states that the interaction of such pulses with molecules generates goes beyond the capabilities of standard quantum-chemistry packages, which have been designed to describe the lowest bound states. Furthermore, stationary state-based pictures based on lowest-order perturbation theory are, in most cases, inapplicable. The purpose of this school is to introduce state-of-the-art ab-initio, hybrid and TDDFT numerical methods that can cope with ultra-fast dynamics in the electronic continuum of molecules, with an emphasis on unbound states in strong-fields and on the need to go beyond single-active-electron models to properly account for electron correlation. The course is directed to advanced master students, PhD students and young post-doctoral researchers in atomic and molecular physics, theoretical chemistry and applied mathematics, with an interest in developing new software for coherent control of electronic dynamics in systems of chemical interest.
The tutorial will be organized in 5 theoretical sessions and 4 practical sessions in the computer lab. Both theoretical and practical sessions will be of 4 hours. The school comprises four didactic blocks. The first block has an introductory character. It offers an overview of the field and a tutorial on strong field physics. The following three blocks focus on systems of increasing complexity and will be devoted to the description and use of new computational methods for fast time evolution in correlated systems in non-perturbative conditions (see description below). The school will end with a comprehensive overview of state-of-the-art results in attosecond pump-probe and strong field molecular science obtained with ab initio “exact” simulations in small systems, on the one side, and with TD-DFT effective-field simulations, capable of coping with larger systems, on the other side. The future perspectives, challenges and mutual interaction of these two complementary approaches will be discussed.
More information: https://www.cecam.org/workshop-1552.html