Sem Sælands vei 24
Adam Robertson from the Oslo University Hospital will be delivering a talk about:
Molecular Effects of the 5-hydroxymethylcytosine DNA Modification
Co-authors: Julia Robertson, Dorota Kororska, Anika Reifschneider, and Adam Robertson
Abram Michael Beauregard Krislock, FI
Go effectively models physics itself: The game has an enormous amount of complexity and is full of beautiful and mind-boggling phenomena. In spite of this, there are only a small number of rules to the game. A study of go can help one with pattern recognition, logical determinism, strategic planning, and concentration. As physicists are becoming more and more proficient in using sophisticated statistics and computer science for their studies, they may be inspired by an ultra recent advancement in computer learning: For the first time, a computer has beaten a professional player in go. Last but not least, go is a ton of fun.
(Slides will be available after the talk)
Steffi Burchardt (Associate Professor, Uppsala University) will give a talk about laccoliths:
Laccoliths are magmatic intrusions with an upward-curved roof and two end-member geometries: the so-called Christmas tree and the punched laccolith. In my talk, I will give an overview of laccolith emplacement with examples from the Henry Mountains, Utah, and Elba Island, Italy, before reporting on field work and first results of ongoing research on laccolith emplacement in the cougar-rich Chachahuén volcano. This research is part of the DIPS and MIMES projects.
Johan Storm (Institute of basic medical sciences, UiO) will talk about the work he does in the "brain signaling" group. His group is interested in signaling and information processing in the brain at multiple levels, from synapses, neurons and circuits, to control of behavior and mental processes, in particular consciousness and memory.
“Understanding consciousness has become the ultimate intellectual challenge of this new millennium” S. Dehaene & J.P. Changeux, 2004
“Consciousness is the major unsolved problem in biology” Francis Crick, 2004.
Ivica Picek, university of Zagreb
Besides being a first indication for the second scalar particle, a recent hint for the 750 GeV resonance at the LHC requires additional particles such as those employed in models of radiative neutrino mass generation. The scalar triplet realizations seem to be preferable with respect to the 2HDM benchmark and provide in the inert variant the dark matter candidates.
(The slides are now available)
Andrzej Hryczuk, FI
The thermal relic abundance of the dark matter is now determined observationally to a per cent level accuracy. It is also an increasingly useful tool to exclude, constrain or motivate models beyond the Standard Model of particle physics. It comes then with no surprise that in the recent years a considerable effort has been made to revise and improve some of the aspects of thermal relic density calculations. In this talk I will concentrate on the important physics concepts used in such calculations, highlighting some less commonly discussed details. Towards the end I will show some recent results, serving as examples of the relevance of the effects studied.
(The slides are now available)
Viktoriya Yarushina (IFE) will give a talk on "Fluid flow in shales from experimental and theoretical perspective"
Chad Finley, Oskar Klein Centre (Stockholm)
The IceCube Neutrino Observatory lies two kilometers deep within the ice at the South Pole, Antarctica. With one cubic kilometer of instrumented volume, IceCube enables the study of a wide range of phenomena: neutrino astronomy, dark matter searches, neutrino oscillations, and cosmic ray physics. Recently IceCube has announced the long-awaited discovery of high energy neutrinos from deep space. These neutrino energies are approximately 100 million times greater than the energies of neutrinos previously observed from the sun and supernovae. I will review IceCube's latest results with particular attention to this new flux. I will also discuss what we hope to measure in the near future with IceCube and the next generation of neutrino telescopes.
(The Slides are now available)
Yuri Galperin (Professor emeritus, Condensed matter physics, AMKS, UiO) will give a seminar in order to help us on (tentative plan) 1. How to write a referee report on a submission? 2. How to respond to referee's remarks (sometimes stupid)? 3. How to evaluate a grant application?
Thi Thuy Luu (UiO, PGP) will talk about HBV (Buskerud and Vestfold University CollegeTønsberg, Norway) lab facilities. She will also talk about her PhD work that she did there about "Solid liquid interdiffusion (SLID) wafer-level bonding for MEMS packaging".
This wine seminar reports on a field expedition/worskhop in the northern Patagonian Andes that involved 8 PGP people. The menu of the presentation is: volcanoes, amazing geology, stunning landscape, condors, gauchos and… Asado!!! The presenters are, so far and not in order: - Olivier - Maya (to confirm) - Alban - Frank - Håvard.
Stefan Hofmann, LMU Munich
A relativistic framework for describing black-hole interiors as bound states of a large number of quantum constituents will be presented. The macroscopic and microscopic description can be linked via a simple scaling law relating the black-hole mass to the number of black-hole constituents.
(The slides will be available after the talk).
Trial lecture: Directional Solidification of Metallic Alloys: From Dendrites and Seaweeds, to Casts and Turbine Plates (10:15)
Dissertation: Non-equilibrium pattern formation in reactive channel flow (13:15)
Felix Ritort (Facultat de Física, Universitat de Barcelona, Spain and Ciber-BBN of Biomaterials and Nanomedicine, ISCIII, Madrid, Spain) will talk about his research on statisical physics tools applied to single molecule experiments in biophysics.
Piero Ullio, SISSA (Trieste)
The dark matter puzzle is one of deepest and longest-standing problems in Science. While there is overwhelming evidence that dark matter is the building block of all structures in the Universe, its nature remains unknown.
There are several theoretical frameworks predicting that dark matter halos - including the halo of our own galaxy - are made of particles which can annihilate in pairs or decay into ordinary Standard Model states, giving rise to exotic astrophysical signals.
The focus in recent years has been in particular on the search for exotic components with gamma- and cosmic-ray observatories, with a dramatic improvement in quality and coverage of the available data.
Unfortunately, for none of the originally proposed targets a dark matter signal stands clearly above backgrounds from standard astrophysical sources: it is then apparent that to keep exploiting these channels as efficient tools to either discover dark matter or set constraints on dark matter candidates, a closer addressing of signals and backgrounds are needed.
We illustrate this point for two targets, the Galactic center and dwarfs satellites which most recently have been highlighted, respectively, as most promising for a tentative detection and most constraining on particle dark matter models.
Björn Herrmann, LAPTh (Annecy)
A powerful tool to constrain a new physics model is to predict the relic density of dark matter and compare it to the recent limits published by Planck in order to identify (dis)favoured regions of parameter space. After reviewing the standard calculation of the dark matter relic density in the freeze-out picture, I will discuss several uncertainties entering this calculation. Focusing then on the particle physics aspects, I will consider the case of the Minimal Supersymmetric Standard Model and present the project DM@NLO, which aims at improving the preciction of the neutralino relic density by including radiative corrections to the (co)annihilation cross-section of the dark matter candidate. In particular, I will show that the impact of these corrections can be numerically larger than the current experimental uncertainty on cosmological data.
(The slides are now available).
Bjarte Aarseth (The viking ship museum, Museum of Cultural History, UiO) will present us his work on 3D scanning and digital visualisation of Vikingship and Norwegian icons.
Joachim Kopp, University of Mainz
We consider two scenarios in which the first experimental hint for the particle physics nature of dark matter (DM) comes from highly boosted DM particles. The first scenario interprets the high energy events observed in IceCube as a signal of PeV DM decaying to a much lighter state, which in turn is detected in IceCube. The model explains the event rate and spectrum observed in IceCube, it shows a preference for shower-like events at the highest energies, and it features a small dip in the spectrum at few hundred TeV. The second scenario is a very generic dark photon model. We point out that DM production at the LHC can be accompanied by final state radiation in the form of "dark photons", which decay back to SM particles. We discuss this process analytically and numerically in analogy to collinear particle showers in QED and QCD. The smoking gun signal of this "radiating DM" scenario are collimated jets or lepton jets with unusual properties.
(The slides are now available.)
Are you also curious to know what research is brewing on the other side of the hall in PGP-AMKS group? Please join us to listen to short talks by our new colleagues, and to look at some posters!
Fei Liu (Physics of Complex Fluids, Dept. Science and Technology University of Twente, The Netherlands) has applied for a PostDoc funded by an ERC (Bjørn Jamtveit) to work at PGP on measuring surface forces between minerals and fluids using AFM and SFA.
Bryan Webber, University of Cambridge
Tests of the Standard Model and searches for new phenomena at the Large Hadron Collider depend heavily on computer simulations of signal and background processes. Monte Carlo event generators aim to simulate the final states of high-energy collisions in full detail, down to the level of individual stable particles. The talk will review the physics behind these programs, their main ingredients and theoretical status, with emphasis on recent work to improve their precision. Comparisons with the latest LHC data will illustrate these developments, and the places where further improvements are needed.
(The Slides are now available)
Sam Poppe, PhD student at the Vrije Universiteit Brussel, will present his work on "X-raying an unusual patient : imaging analogue experiments of volcanic intrusions using X-ray Computed Tomography".
Andreas Carlson (Dept of Mathematics, UiO) will present us his work.