Motivated by the achieved high intensities of novel extreme ultraviolet(XUV)radiation sources,such as free electron lasers and laser-driven high harmonic generation beamlines,we elaborate on their perspective in induc...Motivated by the achieved high intensities of novel extreme ultraviolet(XUV)radiation sources,such as free electron lasers and laser-driven high harmonic generation beamlines,we elaborate on their perspective in inducing observable strong field effects.The feasibility of extending such effects from the infrared and visible spectral regimes in the XUV domain is supported through numerically calculated models of near-future experiments.We highlight the advancement of performing studies in the time domain,using ultra-short XUV pulses,which allows for the temporal evolution of such effects to be followed.Experimental and theoretical obstacles and limitations are further discussed.展开更多
基金the support of this work by‘HELLAS-CH’(MIS grant number 5002735),which is implemented under the‘Action for Strengthening Research and Innovation Infrastructures,’funded by the Operational Program‘Competitiveness,Entrepreneurship and Innovation’(NSRF 2014–2020)+7 种基金co-financed by Greece and the European Union(European Regional Development Fund)the European Union’s Horizon 2020 research ELI-ALPS is supported by the European Unioncofinanced by the European Regional Development Fund(GINOP grant number 2.3.6-15-201500001)LASERLAB-EUROPE(EC’s Seventh Framework Programme grant number 284464)the Hellenic Foundation for Research and Innovation(HFRI)the General Secretariat for Research and Technology(GSRT)under grant agreements GAICPEU(grant number 645)the HFRI Ph D Fellowship grant(grant number 4816)the support of the Irish Research Council under the Govt PG Scholarship(GOIPG/2018/1070)。
文摘Motivated by the achieved high intensities of novel extreme ultraviolet(XUV)radiation sources,such as free electron lasers and laser-driven high harmonic generation beamlines,we elaborate on their perspective in inducing observable strong field effects.The feasibility of extending such effects from the infrared and visible spectral regimes in the XUV domain is supported through numerically calculated models of near-future experiments.We highlight the advancement of performing studies in the time domain,using ultra-short XUV pulses,which allows for the temporal evolution of such effects to be followed.Experimental and theoretical obstacles and limitations are further discussed.
