Home > Laser crystals > Nd:YVO4 > Nd:YVO4 Crystals
Nd:YVO4 is the most efficient laser host crystal for diode pumping among the current commercial laser crystals, especially, for low to middle power density. This is mainly for Nd:YVO4's absorption and emission features surpassing Nd:YAG. Pumped by laser diodes, Nd:YVO4 crystal has been incorporated with high NLO coefficient crystals (LBO,BBO,or KTP) to frequency-shift the output from the near infrared to green, blue, or even UV. This incorporation to construct all solid state lasers is an ideal laser tool that can cover the most widespread applications of lasers, including machining, material processing, spectroscopy, wafer inspection, light displays, medical diagnostics, laser printing, and data storage, etc. It has been shown that Nd:YVO4 based diode pumped solid state lasers are rapidly occupying the markets traditionally dominated by water-cooled ion lasers and lamp-pumped lasers, especially when compact design and single-longitudinal-mode outputs are required.
Nd:YVO4’s advantages over Nd:YAG
As high as about five times larger absorption efficient over a wide pumping bandwidth around 808 nm (therefore, the dependency on pumping wavelength is much lower and a strong tendency to the single mode soutput)
One of the most attractive character of Nd:YVO4 is, compared with Nd:YAG, it has 5 times larger absorption coefficient in a broader absorption bandwidth around the 808 nm peak pump wavelength, which just matches the standard of high power laser diodes currently available. This means a smaller Nd:YVO4 crystal that could be used for the laser, leading to a more compact laser system. For a given output power, this also means a lower power level at which the laser diode operates, thus extending the lifetime of the expensive laser diode. The broader absorption bandwidth of Nd:YVO4 which may reaches 2.4 to 6.3 times that of Nd:YAG, is also valuable. Besides more efficient pumping, Nd:YVO4 also means a broader range of selection of diode specifications. This will be helpful to laser system makers for wider tolerance and lower cost choice.
◇As large as three times larger stimulated emission cross-section at the lasing wavelength of 1064nm
Nd:YVO4 crystal has larger stimulated emission cross-sections, both at 1064nm and 1342nm. When a-axis cut Nd:YVO4 crystal lasing at 1064m, it is about 4 times higher than that of Nd:YAG, while at 1340nm the stimulated cross-section is 18 times larger, which leads to a CW operation completely outperforming Nd:YAG at 1320nm. These make Nd:YVO4 laser be easy to maintain a strong single line emission at the two wavelengths.
◇Lower lasing threshold and higher slope efficiency
◇As a uniaxial crystal with a large birefringence, the emission is only a linearly polarized.
Another important character of Nd:YVO4 lasers is, because it is an uniaxial rather than a high symmetry of cubic as Nd:YAG, what it emits is only a linearly polarized, thus avoiding undesired birefringent effects on the frequency conversion. Although the lifetime of Nd:YVO4 is about 2.7 times shorter than that of Nd:YAG, its slope efficiency can be still quite high for a proper design of laser cavity, because of its high pump quantum efficiency.
The major laser properties of Nd:YVO4 vs Nd:YAG are listed in Table below, including stimulated emission cross-sections (σ), Absorption Coefficient (α) Fluorescent lifetime (τ),Absorption Length (La),threshold Power (Pth) and Pump Quantum Efficiency (ηs).
LASER CRYSTAL
|
DOPING(atm%)
|
σ
(x10-19cm2) |
α
(cm-1) |
τ
(μs) |
Lα
(mm) |
Pth
(mW) |
ηs
(%) |
Nd:YVO4(a-cut)
|
1.0
2.0 |
25
25 |
31.2
72.4 |
90
50 |
0.32
0.14 |
30
78 |
52
48.6 |
Nd:YVO4(c-cut)
|
1.1
|
7
|
9.2
|
90
|
|
231
|
45.5
|
Nd:YAG
|
0.85
|
6
|
7.1
|
230
|
1.41
|
115
|
38.6
|
Crystals
|
Size(mm3)
|
Pump Power
|
Output (at 1064nm)
|
Nd:YVO4
|
3x3x1
|
850mW
|
350mW
|
Nd:YVO4
|
3x3x5
|
15W
|
6W
|
Nd:YAG
|
3x3x2
|
850mW
|
34mW
|
Atomic Density:
|
1.26x1020 atoms/cm3 (Nd1.0%)
|
Crystal Structure:
|
Zircon Tetragonal, space group D4h-I4/amd
a=b=7.1193A,c=6.2892A |
Density;
|
4.22g/cm3
|
Mohs Hardness:
|
4-5(Glass-like)
|
Thermal Expansion Coefficient(300K):
|
αa=4.43x10-6/K
αc=11.37x10-6/K |
Thermal Conductivity Coefficient(300K):
|
//C:0.0523W/cm/K
⊥C:0.0510W/cm/K |
Lasing wavelength:
|
1064nm,1342nm
|
Thermal optical coefficient (300K):
|
dno/dT=8.5×10-6/K
dne/dT=2.9×10-6/K |
Stimulated emission cross-section:
|
25×10-19cm2 @ 1064nm
|
Fluorescent lifetime:
|
90μs(1% Nd doping)
|
Absorption coefficient:
|
31.4cm-1 @810nm
|
Intrinsic loss:
|
0.02cm-1 @1064nm
|
Gain bandwidth:
|
0.96nm@1064nm
|
Polarized laser emission:
|
π polarization; parallel to optic axis(c-axis)
|
Diode pumped optical to optical efficiency:
|
>60%
|
Sellemeier equations (λ in um)
|
n02=3.77834+0.069736/(λ2-0.04724)-0.010813λ2
ne2=4.59905+0.110534/(λ2-0.04813)-0.012676λ2
|
Main Specifications
|
|
Nd dopant concentration
Dopant tolerance |
0.3~2.0(±0.1)atm%
|
Transmitting wavefront distortion
|
less than λ/4 @ 633nm
|
Dimension tolerance
|
(W±0.1mm)x(H±0.1mm)x(L+0.5/-0.1mm) (L≥2.5mm)
(W±0.1mm)x(H±0.1mm)x(L+0.2/-0.1mm) (L<2.5mm)
|
Flatness
|
λ/8 @ 633 nm (L≥2.5mm), λ/4 @ 633nm (L<2.5mm)
|
Sccratch/Digv
|
10/5 @MIL-PRF-13830B
|
Parallelism
|
better than 20 arc seconds
|
Perpendicularity
|
< 5 arc minutes
|
Angle tolerance
|
≤0.5°
|
Clear aperture
|
Central 95%
|
Chamfer
|
0.1mmx45°
|
Damage threshold
|
>500MW/cm^2
|