High Energy Physics Seminar
2006/2007 | 2007/2008 | 2008/2009 | 2009/2010 | 2010/2011 | 2011/2012 | 2012/2013 | 2013/2014 | 2014/2015 | 2015/2016 | 2016/2017 | 2017/2018 | 2018/2019 | 2019/2020 | 2020/2021 | 2021/2022 | 2022/2023 | 2023/2024 | 2024/2025
2025-04-04 (Friday)
room B2.38, Pasteura 5 at 11:30 
Prof. Masayuki Wada (Astrocent CAMK PAN)Developments towards light Dark Matter Detection and Medical Applications
Dark matter candidates with masses below 10 GeV/c² hold promise, and a new detector, DarkSide-LowMass, is proposed based on the DarkSide-50 detector and progress towards the DarkSide-20k. DarkSide-LowMass is optimized for low-threshold electron-counting measurements, and sensitivity to light dark matter is explored for various potential energy thresholds and background rates. I will present the developments towards low mass dark matter searches with a new detector as well as sensitivity with DarkSide-20k, which is under construction.I also discuss the activity for the medical application, Positron Emission Tomography (PET) scanner, using the same technologies as dark matter searches.
2025-03-28 (Friday)
room B2.38, Pasteura 5 at 11:30
André Filipe Cortez (AstroCeNT)Enhanced optical amplification structures for Dark Matter searches
The development of radiation detectors has seen significant advancements over the past decades, particularly in those relying on electroluminescence. Optical time projection chambers (OTPCs) have become the preferred choice in the field of direct dark matter searches (more specifically in WIMP searches), having also been considered for neutrino experiments. Dark matter experiments examples include XENON, LZ, DarkSide, and CYGNO where directional information is expected to be explored. Moreover, these detectors have found applications in nuclear physics, such as in the study of ββ0ν decay (NEXT) and 2p-decay and related processes (Warsaw-TPC).Even though significant progress has been observed in the development of these detectors since the first works in the 1960s, the optimization of the light collection efficiency remains an important concern. Historically, these structures were mostly made up of meshes or conventional micro-pattern gas detectors (MPGDs) designed for avalanche mode and working mainly in quenched gases.Given the expected scalability of most of the aforementioned detectors, light production and collection pose unique challenges. Dealing with alignment, and the use of meshes or wires spanning large areas presents practical limitations. In most cases, relying on scintillation originated in charge avalanches will affect not only the energy resolution but also impact the attainable spatial resolution. In addition, the use of lenses, while enabling the reduction of the number of optical sensors required to read large areas and improvement of the optical gain, may limit the spatial resolution attainable, introducing undesirable optical effects (e.g. aberrations). Nevertheless, it is important to consider techniques that can mitigate potential adverse effects associated with the current amplification structures and readout.In this talk, the challenges for improving the light collection as well as the minimization of the background in dual-phase TPCs resulting from spurious emission will be discussed. We will start with a brief overview of the evolution of electroluminescence studies, along with strategies to address some of the main challenges faced in the development of such detectors for Dark matter searches. Alternative structures, GEM-based, capable of providing higher optical gains without relying on avalanche multiplication, thus enhancing energy resolution and detector stability (while eliminating ion back-flow), will be presented.
2025-03-21 (Friday)
room B2.38, Pasteura 5 at 11:30
dr hab. Marcin Stolarski (NCBJ)Spin Structure of the Nucleon: From CERN SPS to EIC
I will present over 40 years of involvement by Warsaw groups in studying the (spin) structure of the nucleon through CERN SPS muon experiments—including EMC, NMC, SMC, and COMPASS. While these experiments have led to many intriguing physics insights, precise answers to key questions remain elusive due to the kinematic limitations of fixed-target setups. This is set to change with the upcoming Electron-Ion Collider (EIC), the world’s first polarized electron-proton collider, which promises unprecedented access to the nucleon’s spin structure.
2025-03-14 (Friday)
room B2.38, Pasteura 5 at 11:30
dr hab. inż. Martyna Grodzicka-Kobyłka (NCBJ)Silicon Photomultipliers in Gamma and Neutron Radiation Detection – Principles and Applications
Gamma-ray spectrometry using scintillation detectors is one of the most important measurement techniques employed in various fields of nuclear physics and related research. This method finds applications in fundamental nuclear physics studies, environmental monitoring, nuclear medicine, and modern border security systems.Scintillation detectors consist of a scintillating material, which absorbs gamma quanta and subsequently emits light, and a photodetector responsible for registering this signal. The most commonly used photodetectors include PIN diodes, avalanche photodiodes (APDs), vacuum photomultiplier tubes (PMTs), and modern silicon photomultipliers (SiPMs).This presentation will cover the operating principles of silicon photomultipliers, their advantages and limitations, as well as their potential applications in detecting light emitted by scintillators in gamma-ray spectrometry and neutron detection. Special emphasis will be placed on their use in physics, medicine, and security systems.
2025-03-07 (Friday)
room B2.38, Pasteura 5 at 11:30
dr hab. Paweł Bruckman de Renstrom (IFJ PAN)The scalar sector - story so far - from the ATLAS perspective
The long-awaited discovery of the Higgs boson has fundamentally changed the paradigm of experimental particle physics. The BEH mechanism turned from an attractive hypothesis into a physical reality. The detailed study of the properties of the only known fundamental scalar, as well as the direct search for an extended scalar sector, became the main focus of the LHC physics program. Based on ATLAS results, the talk will briefly review the current experimental status of the 125 GeV Higgs boson and focus on the searches for BSM phenomena in the scalar sector.
2025-02-28 (Friday)
room B2.38, Pasteura 5 at 11:30
Dr. Oleksandr TomalakUnderstanding Quark and Neutrino Mixing: Theory and Experiments
The behavior of fundamental particles, such as quarks and neutrinos, is key to understanding the Standard Model of particle physics. Their mixing patterns are described by two mathematicalobjects: the Cabibbo-Kobayashi-Maskawa (CKM) matrix for quarks and the Pontecorvo-Maki-Nakagawa-Sakata (PMNS) matrix for neutrinos. In this talk, I will explain how recent advances in theory and experiments are helping to improve the precision of these matrices.For quarks, I will discuss how precise measurements of the neutron lifetime allow us to determine the largest CKM matrix element, Vud. I will present a modern theoretical framework that accounts for subtle effects, like radiative corrections, in low-energy processes with nucleons. These corrections are essential for achieving high precision in extracting Vud.For neutrinos, future experiments such as Hyper-Kamiokande in Japan and LBNF/DUNE in the USA aim to answer fundamental questions, such as whether neutrinos preserve charge-parity (CP) violation and the ordering of their masses. These experiments depend on accurate predictions of how neutrinos interact with matter. I will review recent theoretical progress on radiative corrections, the structure of hadrons, and neutrino-nucleus interactions, and discuss their role in determining the elements of the PMNS matrix.
2025-01-24 (Friday)
room B2.38, Pasteura 5 at 11:30
dr Małgorzata Kazana (NCBJ)Highlights on BSM searches at CMS
The searches for the Beyond the Standard Model physics with the CMS experiment at LHC will be presented
2025-01-17 (Friday)
room B2.38, Pasteura 5 at 11:30
prof. dr hab. Aleksander Filip Żarnecki (IFD UW)Linear Collider Vision for the update of the European Particle Physics Strategy
LCVision idea was born in spring 2024. The main goal was to make a strong case for Linear Colliders in general, based on physics arguments. With mature designs for the first stage and attractive upgrade options Linear Collider Facility (LCF) is being proposed as an alternative option for the future project at CERN. Last week Linear Collider Vision Community Event took place at CERN with about 250 registered participants. Selected results from the meeting will be presented.
2025-01-10 (Friday)
room B2.38, Pasteura 5 at 11:30
dr Joanna Kiryluk (Stony Brook University)High Energy Neutrinos: Recent results from IceCube
IceCube neutrino observatory is 1km3 detector located at the South Pole in Antarctica. It’s been continuously taking data, since its completion in 2010. In 2012, IceCube detected first PeV neutrino events, the highest energy neutrinos ever observed, and measured an unexpectedly large astrophysical diffuse neutrino flux. Since then, we characterized this flux utilizing different detection selections with: all-flavor neutrino events starting in the detector, muon neutrino induced tracks, and cascades events, dominated by electron and tau neutrino flavors. The diffuse flux was found to be well described by a single power law with a spectral index of 2.5, softer than expected. Its origin remains largely unknown. In 2017, an IceCube neutrino alert from a direction of TXS 0506+056 triggered a multi-wavelength campaign of followup observations, and identified TXS 0506+056 as a cosmic rays accelerator and a common source of high energy neutrinos and gamma rays: a breakthrough in multi-messenger astronomy. Since then, IceCube found evidence that astrophysical neutrinos are correlated with NG1068, PKS1424+240 and TXS0506+056 active galaxies. In this talk we will review IceCube results on astrophysical neutrino diffuse flux and sources, as well as plans for the future.
2024-12-06 (Friday)
room B2.38, Pasteura 5 at 11:30
Leah Wolf (Royal Holloway University of London)Latest Results and Status of the LUX-ZEPLIN Dark Matter Experiment
The LUX-ZEPLIN (LZ) experiment is a dark matter direct detectionexperiment located 4,850 feet underground at the Sanford UndergroundResearch Facility (SURF) in South Dakota. The detector is a dual-phaseTime Projection Chamber (TPC) that whose target consists of 7 tonnesliquid xenon target aimed at detecting dark matter interactions,primarily from the highly-motivated candidate - Weakly InteractingMassive Particles (WIMPs), as well as some other phenomena beyond thestandard model. LZ continues to constrain parameter-space for WIMP-likedark matter as it acquires more data towards its goal of 1,000 days oflive time. This talk will present LZ’s new results from the combined2022-2024 exposure and the status of the detector.
2024-11-29 (Friday)
room B2.38, Pasteura 5 at 11:30
prof. dr hab. Aleksander Filip Żarnecki (IFD UW)ECFA Workshops on e+e- Higgs/Electroweak/Top Factories
Third ECFA Workshop on physics and detectors for future e+e- Higgs/Electroweak/Top Factories took place in October in Paris.This was the last of the workshop series which should conclude with the ECFA report on the physics at future Higgs factories. I will report on ECFA study in general, selected results presented at the last workshop and on the status of the final report being prepared as an input for the European Strategy for Particle Physics update.
2024-11-22 (Friday)
room B2.38, Pasteura 5 at 11:30
dr Rudolph Nchodu (deputy director of the iThemba LABS, Cape Town)iThemba Laboratory for Accelerator-Based Sciences (LABS)
iThemba LABS is the hub to a vibrant research, human capital development, and collaboration network for nuclear science that includes the South African universities, research institutions and international counterparts. The iThemba LABS K=200 separated sector cyclotron (SSC), one of the accelerator complex comprising 3 accelerators, has been used for nuclear physics research, particle (neutron and proton) therapy, and radioisotope production since its commissioning in 1986. In the first 30 years of the SSC’s operation, the beam time has been equally divided between the three programs, which severely limited the competitiveness of the nuclear physics research program. iThemba LABS acquired a new 70 MeV cyclotron that will be dedicated to isotope production, which will free up the SSC for research.Nuclear Physics research at iThemba LABS serves as the backbone of research at iThemba LABS and the research programs in the next 5 to 10 years will be focused on niche areas where the laboratory’s research program will complement the research carried out at cognate laboratories around the world. The Long Range Plan initiated in 2017 aiming for increasing the nuclear physics research capacity as well as the technical R&D and the required human capacity development, will be presented as well as the status of its implementation. The prominent global position that iThemba LABS Facility enjoys and its critical role in coordinating the continental contribution to collaborative initiatives with international nuclear Physics institutions will be discussed.
2024-11-15 (Friday)
room B2.38, Pasteura 5 at 11:30
prof. dr hab. Krzysztof Doroba (IFD UW)CMS measurement of the W boson mass in proton-proton collisions at √s =13 TeV
Precision tests of Standard Model (SM) are very important part of LHC scientific program. Since Higgs discovery and determination of its mass by ATLAS and CMS all the parameters of electroweak (EW) sector of the SM are now constrained by experimental measurements. Established disagreement between W boson mass measurement and SM prediction could be a tip towards physics beyond the SM (BSM). In the seminar the recent W boson mass measurement by Compact Muon Collaboration will be presented (m_W=80 360.2±9.6 MeV) with the special emphasis on its accuracy and the way to achieve it.
2024-11-08 (Friday)
room B2.38, Pasteura 5 at 11:30
prof. Krzysztof Piotrzkowski (AGH, Kraków)An experiment for electron-hadron scattering at the LHC
The proposed LHeC facility will provide electron-proton (nucleus)collisions with (per nucleon) instantaneous luminosities around 10^34(10^33) cm^-2s^-1 by colliding a 50 GeV electron beam from a highlyinnovative energy-recovery linac system with the LHC hadron beams,concurrently with other experiments for hadron-hadron collisions. TheLHeC scientific programme is very complementary to the HL-LHC one andwould also significantly enhance it. In this talk, I will summarize theLHeC research scope and present the status of accelerator and detectordesigns, and discuss future developments as well as an exciting path forthe LHeC realization.
2024-10-25 (Friday)
room B2.38, Pasteura 5 at 11:30
dr Washington Rodrigues De Carvalho jr. (IFD UW)Dependence of the radio emission of air showers on the cosmic ray primary particle composition
We will start with brief introductions to Cosmic Rays (CR),extensive air showers and their radio emission. We will explore the originsof the dependence of the air shower development on the primary CR composition and how it affects the radio emission. We will then proceed todescribe in more detail our newest work regarding a strong composition dependence on the measured radio signal amplitudes at ground level. Thissimple, yet historically overlooked dependence can be explained in terms of two competing scalings of the measured electric field that depend on theposition of the shower maximum (Xmax) in the atmosphere. This dependence can be used to directly infer the CR primary composition, even on a non-standard event-by-event basis.
2024-10-18 (Friday)
room B2.38, Pasteura 5 at 11:30
prof. dr hab. Barbara Badełek (IFD UW)Overview of the spin programme of COMPASS
The purpose of the COMPASS facility is a study of hadron structure and spectroscopy with high energy hadron and (polarised) muon beams.In the spin programme polarised proton and deuteron targets were used in inclusive and semi-inclusive deep-inelastic reactions as well as in the Drell-Yan process. Deeply virtual Compton scattering and hard exclusive meson muoproduction were studied using an unpolarised proton target.A panorama of COMPASS results on 1D and 3D nucleon structure, based on the invited talk delivered at the "Diffraction and Low-x 2024" conference in Trabia (Italy), will be presented.
2024-10-11 (Friday)
room B2.38, Pasteura 5 at 11:30
Magdalena Posiadała-Zezula (IFD UW)Report from the NEUTRINO24: XXXI International Conference on Neutrino Physics and Astrophysics
An overview of the most interesting results presented at the NEUTRINO24 conference will be presented.
2024-10-04 (Friday)
room B2.38, Pasteura 5 at 10:15
dr hab. Grzegorz Grzelak (IFD UW)Report from the ICHEP-2024:42nd International Conference on High Energy Physics
A subjective overview of most interesting results brought to the ICHEP-2024 conference will be presented.