<h4 align="center"></h4>
<h2 align="center">PREDRAG RANITOVIC</h2>
<p align="center">(Lawrence Berkeley National Laboratory, Berkeley, USA, vendéglátó: Dombi Péter)</p>
<h2 align="center">"Control of atomic and molecular XUV absorption processes using intense IR fields"</h2>
<p align="center">Időpont: 2014. november 11. (kedd) 10:00<br>
Hely: MTA Wigner FK SZFI, I. épület 1. emeleti Tanácsterem</p>
<h3>Összefoglaló:</h3>
1
<p><b>Részletes információ:</b>
<a href="<p>Recent breakthroughs in ultrafast lasers development have allowed for the opening of new horizons in the ultrafast experimental and theoretical AMO physics. Following these advances, table-top extreme ultraviolet (XUV) sources have provided novel ways to achieve real-time manipulation of electron dynamics through the use of attosecond XUV light coupled with strong laser fields in a time-resolved manner [1-6]. However, more than ten years upon the birth of attosecond physics, and after the Nobel Prize Award for femtochemistry, the concept of attosecond chemistry has not yet been fully realized. In this talk, I will show some recent advances in strong-field ionization done by mid-IR laser fields, and show how to use attosecond VUV and XUV light sources to coherently manipulate molecular dynamics by means of electron wave packet interferometry [7]. This novel approach of using attosecond vacuum ultraviolet pulse-trains to coherently excite and control the outcome of a simple chemical reaction in a deuterium molecule, in a non-Born Oppenheimer regime, presents intriguing new possibilities for bridging the gap in between the attosecond physics and attochemistry [8].</p>
<p>[1] E. Gagnon, P. Ranitovic, X. M. Tong et al. Science 317(5843), 1374-1378 (2007).<br /> [2] A. S. Sandhu, E. Gagnon, R. Santra, et al. Science 322 (5904), 1081-1085 (2008).<br /> [3] P. Ranitovic, X. M. Tong, B. Gramkow et al. New Journal of Physics 12, 013008 (2010).<br /> [4] D. Hickstain, P. Ranitoivc*, S. Witte et al. Phys. Rev. Lett. 109, 073004 (2012).<br /> [5] P. Ranitovic, X. M. Tong, C. W. Hogle et al. Phys. Rev. Lett. 106, 053002 (2011).<br /> [6] X. Zhou, P. Ranitovic, C. W. Hogle et al. Nature Physics 8, 232-237 (2012).<br /> [7] P. Ranitovic, X. M. Tong, C. W Hogle et al. Phys. Rev. Lett. 106, 193008 (2011).<br /> [8] P. Ranitovic et al. Proceedings of National Academy of Sciences, 111(3), pp. 912-917 (2014).</p>"><p>Recent breakthroughs in ultrafast lasers development have allowed for the opening of new horizons in the ultrafast experimental and theoretical AMO physics. Following these advances, table-top extreme ultraviolet (XUV) sources have provided novel ways to achieve real-time manipulation of electron dynamics through the use of attosecond XUV light coupled with strong laser fields in a time-resolved manner [1-6]. However, more than ten years upon the birth of attosecond physics, and after the Nobel Prize Award for femtochemistry, the concept of attosecond chemistry has not yet been fully realized. In this talk, I will show some recent advances in strong-field ionization done by mid-IR laser fields, and show how to use attosecond VUV and XUV light sources to coherently manipulate molecular dynamics by means of electron wave packet interferometry [7]. This novel approach of using attosecond vacuum ultraviolet pulse-trains to coherently excite and control the outcome of a simple chemical reaction in a deuterium molecule, in a non-Born Oppenheimer regime, presents intriguing new possibilities for bridging the gap in between the attosecond physics and attochemistry [8].</p>
<p>[1] E. Gagnon, P. Ranitovic, X. M. Tong et al. Science 317(5843), 1374-1378 (2007).<br /> [2] A. S. Sandhu, E. Gagnon, R. Santra, et al. Science 322 (5904), 1081-1085 (2008).<br /> [3] P. Ranitovic, X. M. Tong, B. Gramkow et al. New Journal of Physics 12, 013008 (2010).<br /> [4] D. Hickstain, P. Ranitoivc*, S. Witte et al. Phys. Rev. Lett. 109, 073004 (2012).<br /> [5] P. Ranitovic, X. M. Tong, C. W. Hogle et al. Phys. Rev. Lett. 106, 053002 (2011).<br /> [6] X. Zhou, P. Ranitovic, C. W. Hogle et al. Nature Physics 8, 232-237 (2012).<br /> [7] P. Ranitovic, X. M. Tong, C. W Hogle et al. Phys. Rev. Lett. 106, 193008 (2011).<br /> [8] P. Ranitovic et al. Proceedings of National Academy of Sciences, 111(3), pp. 912-917 (2014).</p></a></p><h4 align="center">Minden érdeklődőt szívesen látunk!</h4><p> </p>