Seminarium Optyczne
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 | Seminarium na YouTube
2023-11-16 (Czwartek)
Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 10:15 
dr Luca Tanzi (European Lab. for Non-Linear Spectroscopy)Exploring the supersolid phase of matter with dipolar quantum gases
2023-11-09 (Czwartek)
Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 10:15
Ms Bohnishikha Ghosh (IFD UW)Optical backflow in the interference of two beams
"A quantum particle prepared as a superposition of positive momentum states can have a negative probability current during local instances of time [1]. The phenomenon of probability flow in the ‘wrong’ direction is referred to as ‘backflow’ and is a manifestation of wave interference. Superoscillations refer to situations where the local oscillation of a superposition is faster than its fastest Fourier component [2]. M.V. Berry’s work [3] highlighted the correspondence between backflow in quantum mechanics and superoscillations in waves. This correspondence has been used to demonstrate backflow in transverse linear momentum for optical waves [4,5]. Following this, we examine the interference of classical light carrying only negative orbital angular momentum (OAM) and observe in the dark fringes of such an interference pattern, positive local OAM [6]. We refer to this as azimuthal backflow. The associated strong phase gradients within the dark fringes have implications for the studies of light-matter interaction.[1] A. J. Bracken and G. F. Melloy, “Probability backflow and a new dimensionless quantum number” J. Phys. A: Math. Gen. 27, 2197 (1994).[2] M. V. Berry and S. Popescu, “Evolution of quantum superoscillations and optical superresolution without evanescent waves” J. Phys. A: Math. Gen. 39, 6965(2006). [3] M. V. Berry, “Quantum backflow, negative kinetic energy and optical retro-propagation” J. Phys. A: Math. Theor. 43, 415302 (2010). [4] Y. Eliezer, T. Zacharias, and A. Bahabad, “Observation of optical backflow” Optica 7, 72 (2020). [5] A. Daniel, B. Ghosh, B. Gorzkowski, and R. Lapkiewicz, “Demonstrating backflow in classical two beams’ interference” New. J. Phys. 24, 123011(2022). [6] B. Ghosh, A. Daniel, B. Gorzkowski, and R. Lapkiewicz, “Azimuthal backflow in light carrying orbital angular momentum” Optica 10 (9), 2334-2536 (2023)."
2023-10-26 (Czwartek)
Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 10:15
prof. Felipe Herrera (Universidad de Santiago de Chile)How to chemical bonds break in ultrastrong coupling?
2023-10-19 (Czwartek)
Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 10:15
prof. Kazimierz Rzążewski (Centre for Theoretical Physics Polish Academy of Sciences)Fluctuations of Bose-Einstein condensate
Particle fluctuations of a number of condensed atoms is one of fundamental problems of quantum gases physics. In the last five years it is not only a theoretical, but also the experimental problem. I will review over a quarter of the century of our own efforts. I will explain our new method of the Fock states sampling in application to the condensate statistics.
2023-10-12 (Czwartek)
Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 10:15
dr Alex Davis (University of Bath)Photonic crystal fibre for quantum applications
2023-10-05 (Czwartek)
Zapraszamy do sali 0.06, ul. Pasteura 5 o godzinie 10:15
Professor Jianqiang Zhu (Shanghai Institute of Optics and Fine Mechanics)Laser Fusion Energy: a long term dream
Inertial Fusion Energy (IFE) is potentially a promising scheme for the energy sustainable development, and also a platform for the studies of high energy density physics. However, achieving pure fusion in the laboratory still faces difficult challenges. National Laboratory on High Power Laser and Physics (NLHPLP) in Shanghai Institute of Optics and Fine Mechanics (SIOM), Chinese Academy of Sciences (CAS) has built up a serious of successful user facilities named SG-II high power laser facilities, which provided a high degree of experimental flexibility at one site with a diverse set of a lasers, to push forward researches on pathways to Inertial Fusion Energy.SG-II high power laser facility, with a picosecond and a femtosecond PW lasers and 16 beams nanosecond laser, has extraordinary output performance for ICF research and high energy density science (HEDS). Experimental shots for different kinds of researches are provided to domestic and international users since 1990s.Also, some key technologies have been developed to improve the performance to the facility. Some efforts on increasing the small gain coefficient were made to increase the energy of 1\omega output. The other efforts such as raising the load ability of 3\omega, enhancing beam quality, and improving the beam focusing ability and beam direction of ps pulse were also conducted.
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