Experimental and theoretical investigation of tunable picosecond pulse generation in longitudinally pumped dye laser generators and amplifiers

Abstract: Picosecond pulse generation in longitudinally pumped dye laser generators and amplifiers is studied experimentally and theoretically. Frequency-tunable pulses between 720 and 940 nm are generated with a picosecond ruby laser pump source. The amplification of spontaneous emission and of seeding pulses in the generator and amplifier cells is investigated. Stimulated emission cross-sections and excited-state absorption cross-sections are determined by computer simulations. The coherence properties of the generate… Show more

“…The use of eosin Y in methanol as a laser medium may be restricted to short pump pulse excitation (ps to ns) and subpicosecond to subnanosecond laser pulse generation [35] like travelling-wave amplified spontaneous emission lasers [33,[35][36][37][38][39][40], distributed feedback lasers [41,42], quenched cavity lasers [43,44], spectro-temporal selection lasers [45,46], or short cavity lasers [46][47][48][49][50], because of the large quantum yield of triplet state formation [32].…”

Singlet excited-state absorption of eosin Y

“…The use of eosin Y in methanol as a laser medium may be restricted to short pump pulse excitation (ps to ns) and subpicosecond to subnanosecond laser pulse generation [35] like travelling-wave amplified spontaneous emission lasers [33,[35][36][37][38][39][40], distributed feedback lasers [41,42], quenched cavity lasers [43,44], spectro-temporal selection lasers [45,46], or short cavity lasers [46][47][48][49][50], because of the large quantum yield of triplet state formation [32].…”

Singlet excited-state absorption of eosin Y

“…In this paper thermodynamic and spectroscopic parameters of the styryl dyes taneous emission [25,26] maybe possible by femtosecond pulse excitation [27 ].…”

Absorption and emission spectroscopic investigation of cyanovinyldiethylaniline dye vapors

“…For organic dye molecules, which may serve as the gain medium, the typical value of parameter  is 14 s 10    . 48 Background permittivity of the gain medium is set to 0 4   and its emission frequency is tuned to the narrow propagation band of SDC. The radii of core-shell NP are 1 Following the same procedure as in Section 3, we find the dispersion law of guided modes in the tight-binding approximation:…”

Magneto-optics enhancement with gain-assisted plasmonic subdiffraction chains