GaSe:Er3+ crystals for SHG in the infrared spectral range

“…Therefore, the solubility of the following types of dopants is very limited and is difficult to measure accurately: f8 3 10 22 for Al 36,42,50 and 5 3 10 24 for Er 21 . The available data for 0.5 at.% Er doping of GaSe by charge composition is claimed to have resulted in a 24% increase in the intrinsic nonlinearity 71 ; this result appears to be inconsistent, as Er has such low solubility.…”

“…GaSe doped with 0.5 at.% of Er in charge composition demonstrated a 24% increase in the intrinsic nonlinearity 71 . Bearing in mind the low Er solubility 21 , the increase appears to be due largely to the improved optical quality. It was established properly that the maximal transparency window 42,49,55,61,69 and THz range 51 absorption coefficients for all properly doped crystals grown by the modified method, i.e., with a rotating heat field, are 2-3 times lower (f0.03-0.06 cm 21 ) than those for crystals grown by the conventional vertical Bridgman method.…”

“…Other attractive physical properties of GaSe are its prodigious birefringence B 5 0.375 at l 5 10.6 mm and 0.79 at terahertz (THz) range 4 , and very high second-order nonlinear susceptibility d 22 5 54 pm V 21 at 10 mm 5 and 24.3 pm/V in the THz band 6 . Among the mid-infrared (IR) anisotropic nonlinear crystals, GaSe has the second highest optical damage threshold 7,8 and thermal conductivity in the plane of the (0001) layers (0.162 W(cm?deg) 21 ), accompanied by large thermal capacity C p 5 47.9 J (mol?deg) 21 and density 5.05 g cm 23 , close coefficients of linear thermal expansion a | 5 10.8?10 26 deg 21 and a H 5 9.1?10 26 deg 21 , and low two-photon absorption coefficients 0.2-0.5 cm 21 GW 21 for 0.7-0.8 mm pumping. The physical properties are well reviewed elsewhere 5,9 .…”

“…The hardness of GaSe has been measured to be close to 0 on the Mohs' scale 9 . The limited optical quality of grown GaSe crystals is caused by the weak technological control of defects: point defects (mainly Ga vacancies) and micro-defects (Ga precipitates, voids or bubbles, stacking disorders, broken layers, and dislocations) 20,21,22 . In particular, the dislocation density can reach 10 9 cm 22 22 , and the fraction of layer stacking faults may be up to 0.67 23 .…”

“…The original e-polytype structure of GaSe is strengthened by doping; meanwhile, the physical properties responsible for the efficiency of frequency conversion and the possibility of electro-optic applications may be noticeably modified. However, due to the negative effect on optical nonlinearity of doping by sulfur, the first agent explored 24 , only a few other dopants (In, Te, Er, and Ag), in limited concentration ranges, were used until the last decade to modify further physical properties for nonlinear optical applications 19,21,25,26 . In addition, these studies are mostly related to the physical properties of the ordinary light waves.…”

Doped GaSe crystals for laser frequency conversion

“…Therefore, the solubility of the following types of dopants is very limited and is difficult to measure accurately: f8 3 10 22 for Al 36,42,50 and 5 3 10 24 for Er 21 . The available data for 0.5 at.% Er doping of GaSe by charge composition is claimed to have resulted in a 24% increase in the intrinsic nonlinearity 71 ; this result appears to be inconsistent, as Er has such low solubility.…”

“…GaSe doped with 0.5 at.% of Er in charge composition demonstrated a 24% increase in the intrinsic nonlinearity 71 . Bearing in mind the low Er solubility 21 , the increase appears to be due largely to the improved optical quality. It was established properly that the maximal transparency window 42,49,55,61,69 and THz range 51 absorption coefficients for all properly doped crystals grown by the modified method, i.e., with a rotating heat field, are 2-3 times lower (f0.03-0.06 cm 21 ) than those for crystals grown by the conventional vertical Bridgman method.…”

“…Other attractive physical properties of GaSe are its prodigious birefringence B 5 0.375 at l 5 10.6 mm and 0.79 at terahertz (THz) range 4 , and very high second-order nonlinear susceptibility d 22 5 54 pm V 21 at 10 mm 5 and 24.3 pm/V in the THz band 6 . Among the mid-infrared (IR) anisotropic nonlinear crystals, GaSe has the second highest optical damage threshold 7,8 and thermal conductivity in the plane of the (0001) layers (0.162 W(cm?deg) 21 ), accompanied by large thermal capacity C p 5 47.9 J (mol?deg) 21 and density 5.05 g cm 23 , close coefficients of linear thermal expansion a | 5 10.8?10 26 deg 21 and a H 5 9.1?10 26 deg 21 , and low two-photon absorption coefficients 0.2-0.5 cm 21 GW 21 for 0.7-0.8 mm pumping. The physical properties are well reviewed elsewhere 5,9 .…”

“…The hardness of GaSe has been measured to be close to 0 on the Mohs' scale 9 . The limited optical quality of grown GaSe crystals is caused by the weak technological control of defects: point defects (mainly Ga vacancies) and micro-defects (Ga precipitates, voids or bubbles, stacking disorders, broken layers, and dislocations) 20,21,22 . In particular, the dislocation density can reach 10 9 cm 22 22 , and the fraction of layer stacking faults may be up to 0.67 23 .…”

“…The original e-polytype structure of GaSe is strengthened by doping; meanwhile, the physical properties responsible for the efficiency of frequency conversion and the possibility of electro-optic applications may be noticeably modified. However, due to the negative effect on optical nonlinearity of doping by sulfur, the first agent explored 24 , only a few other dopants (In, Te, Er, and Ag), in limited concentration ranges, were used until the last decade to modify further physical properties for nonlinear optical applications 19,21,25,26 . In addition, these studies are mostly related to the physical properties of the ordinary light waves.…”

Doped GaSe crystals for laser frequency conversion

Linear and nonlinear absorption, SHG and photobleaching behaviors of Dy doped GaSe single crystal

Growth and characterization of an Al-doped GaSe crystal