Nd: YAG is one of the mature developed laser crystals obtained by doping Nd ion into YAG crystal. The absorption bandwidth of Nd: YAG laser crystal is 730-760 nm and 790-820 nm and is usually pumped by a flash tube or laser diode. The typical laser emission peak is 1064 nm. It is also possible to emit lasers with wavelengths of 946 nm, 1120 nm, 1320 nm, and 1440 nm with some measures.
Q-switch and lock mode is adapted to obtain laser with different wavelengths (532 nm, 266 nm, 213 nm, etc.) and pulse width (10-25 ns), respectively, which makes the vast application in biophysics, medicine, military, machine, scientific research, and architecture, etc. The high concentration doped crystal is commonly applied to pulse laser, and the low concentration doped one is usually used in continuous wave output.
Turns With a Technology Base
Nd: YAG laser is usually pumped with lots of laser emission peaks enabled with lock mode. It takes a basic configuration to access a flash tube or laser diode. Thus, it considers an influential role in finding out pulse width and others. Doped crystals are made for low concentration. It usually grabs it basically on the laser with different wavelengths. It gains a coefficient that turns out with the latest technologies. They are well adapted by discovering mechanical and physical properties. It takes a wide absorption bandwidth by delivering excellent optical sources. A low-lasting threshold with a high gain coefficient is accessed with visual references.
Nd:YAG + V:YAG Bonding Crystal For 1319nm Laser
Size: 2.8*2.8*14.2mm; Nd:YAG:10mm; V:YAG:4.2mm, T0=75%@1319nm;
Nd:YAG Surface: R <1% @808±5nm & R > 99.9% @1319±1nm & R<10% @1064±1nm ,AOI=0±5°;
V:YAG Surface: R=85%±2% @1319±1nm & R<10% @1064±1nm, AOI=0±5°; Damage Threshold>700MW /cm2@10ns, 10Hz, 1319nm;
Nd:YAG crystal case (2) for 1064 nm laser
Size: Φ8×165 mm;
2-side polished;
Wavefront distortion: λ/8@633nm;
AR/AR@1064 R<0
Nd:YAG crystal case (3) for 1064 nm laser
Size: dia. 7 mm, length 140 mm;
Concentration 0.8-1%;
AR for working ends 1064 nm
Nd:YAG crystal case (4) for 1064 nm laser
Size: dia.4×10 mm;
Nd concentration – (standard for pulsed lasers) 0.9-1.3 at. %;
Coating: AR/AR for both sides at 1064nm
Nd:YAG + V:YAG bonding crystal for 1319nm laser
Nd: YAG surface:
R<1%@808±5 nm & R>99.9%@1319±1 nm & R<10%@1064±1 nm, AOI=0±5°
V: YAG surface:
R=85%±2%@1319±1 nm & R<10%@1064±1 nm, AOI=0±5°
Nd: YAG crystal case (6) for 1064 nm laser
Size: dia. 2*75 mm;
2-side polishing;
AR/AR@1064 nm
Nd:YAG crystal case (7) for 1064 nm laser
Size: dia. 8*165 mm;
Nd doping level: 0.8~1.1%;
2-side polished on Ø8 mm surface;
AR/AR@1064 R<0.2
Nd:YAG crystal case (8) for Laser Welding machine
Size: Ø7×145 mm;
Coating: AR/AR@1064nm R<0.2%
Nd:YAG crystal case (9)
Size: dia. 1*20 mm;
Nd doping level: 1.1%
Nd:YAG crystal case (10) for 1064 nm laser
Size: φ7×145 mm;
Concentration: 1.0-1.1%;
Coated: AR/AR@1064nm
Nd:YAG crystal case (11) – Nd:YAG case (11) – Custom
Size: Φ6.35×109 mm;
Groove =49.25*2=95.5 mm;
Coating: AR/AR@1064nm, R<0.25
Material Processing
266nm laser
532nm laser
1064nm laser
355nm laser
Optical Communication
532nm laser
Radar and Ranging
1064nm,532nm,355nm laser
Medical Applications
532nm laser
1064nm/532nm laser
1064nm laser
- High gain coefficient
- Low lasing threshold
- Excellent optical, mechanical and physical properties
- High slope efficiency
- Wide absorption bandwidth
| A LD side-pumped deep ultraviolet laser at 266nm by using a Nd:YAG/Cr4+:YAG/YAG composite crystal Optics & Laser Technology,Volume 63,50014,Pages 24-28, |
| Characterization of the optical properties of ArF laser irradiated Nd:YAG crystal Optik,Volume 127, Issue 4,50016,Pages 1681-1684 |
| Comparative study between Nd:GYSGG and Nd:YAG lasers passively Q-switched by a Cr:YAG crystal Optik,Volume 156,50018,Pages 260-264 |
| Crystal growth of high doped Nd:YAG Optical Materials,Volume 26, Issue 4,50004,Pages 337-341 |
| Crystal growth, Judd–Ofelt analysis and radiative properties of Nd:YAG single crystal grown by HDS Journal of Luminescence,Volume 140,50013,Pages 135-137 |
| Distribution of Neodymium and properties of Nd:YAG crystal by horizontal directional solidification Journal of Crystal Growth,Volume 340, Issue 1,50012,Pages 130-134 |
| Effect of XeCl laser irradiation on the defect structure of Nd:YAG crystals Optics and Lasers in Engineering,Volume 60,50014,Pages 12-17 |
| Fabrication and laser performance of polycrystal and single crystal Nd:YAG by advanced ceramic processing Optical Materials,Volume 29, Issue 10,50007,Pages 1289-1294 |
| Femtosecond laser irradiation on Nd:YAG crystal: Surface ablation and high-spatial-frequency nanograting Applied Surface Science,Volume 441,50018,Pages 372-380 |
If you can’t find the Literature you want, Contact us to get the PDF Get the Literature
| Femtosecond laser written channel optical waveguide in Nd:YAG crystal Optics & Laser Technology,Volume 58,50014,Pages 89-93 |
| Formation of gaseous cavity defect during growth of Nd:YAG single crystals Journal of Crystal Growth,Volume 367,50013,Pages 57-61 |
| Gain and laser operation of 1.1%Nd:YAG crystal fibers Optics Communications,Volume 197, Issues 4–6,50001,Pages 375-378 |
| High repetition rate, high peak power burst mode laser with YAG/Nd:YAG/Cr4+:YAG composite crystal Optik,Volume 175,50018,Pages 263-267 |
| Highly doped Nd:YAG crystal used for microchip lasers Optics Communications,Volume 197, Issues 4–6,50001,Pages 413-418 |
| Investigation of multi-segmented Nd:YAG/NdYVO4 crystals and their laser performance end-pumped by a fiber coupled diode laser Optik,Volume 179,50019,Pages 367-372 |
| Laser diode pumped Nd:YAG crystals frequency summing 589nm yellow laser Optik,Volume 127, Issue 2,50016,Pages 710-71 |
| Mechanical, thermal and optical properties of the SPS-processed polycrystalline Nd:YAG Optical Materials,Volume 38,50014,Pages 204-210 |
| Nonlinear mixing of Nd:YAG lasers; harmonic and sum frequency generation Optical Materials,Volume 65,50017,Pages 2-7 |
| Optical spectroscopy in channel waveguides made in Nd:YAG crystals by femtosecond laser writing Journal of Luminescence,Volume 128, Issues 5–6,50008,Pages 754-756 |
| Photonic crystal structure in Nd:YAG laser crystals Optical Materials,Volume 34, Issue 11,50012,Pages 1811-1814 |
| Preparation and Properties of Yb:YAG and Nd:YAG Nanocrystals Rare Metal Materials and Engineering,Volume 46, Issue 3,50017,Pages 591-595 |
| Post-treatment of nanopowders-derived Nd:YAG transparent ceramics by hot isostatic pressing Ceramics International,Volume 43, Issue 13,50017,Pages 10013-10019 |
| Role of internal radiation during Czochralski growth of YAG and Nd:YAG crystals International Journal of Thermal Sciences,Volume 45, Issue 2,50006,Pages 151-167 |
| Solar pumped Nd:YAG laser, Optik – International Journal for Light and Electron Optics,Volume 124, Issue 18,50013,Pages 3367-3370 |
| Study of structural and optical properties of YAG and Nd:YAG single crystals Materials Research Bulletin,Volume 63,50015,Pages 80-87 |
| Study on growth techniques and macro defects of large-size Nd:YAG laser crystal Journal of Crystal Growth,Volume 483,50018,Pages 200-205 |
| Ultrafast laser inscribed cladding waveguides in Nd:YAG crystal for mid-infrared wavelength Optics & Laser Technology,Volume 56,50014,Pages 382-386 |
| Y-junctions based on circular depressed-cladding waveguides fabricated with femtosecond pulses in Nd:YAG crystal: A route to integrate complex photonic circuits in crystals Optical Materials,Volume 72,50017,Pages 220-225 |
Parameter
| Nd Concentration Tolerance (atm%) | 0.1- 2.5(+/-0.1)atm% |
| Orientation | [001] or [110] or [111] <±0.5° |
| Parallelism | 10〞 |
| Perpendicularity | 5ˊ |
| Surface Quality | 10-5(MIL-O-13830A) |
| Wavefront Distortion | λ/4@632 nm |
| Surface Flatness | λ/8@632 nm |
| Clear Aperture | >95 % |
| Chamfer | <0.2×45° |
| Length Tolerance | +0.5/-0mm |
| Thickness/Diameter Tolerance | ±0.05 mm |
| Maximum Dimensions | dia (3~12.7)×(3~150) mm |
| Damage Threshold | >750 MW/cm2@1064 nm 10 ns 10 Hz |
| Chips | <0.1 mm |
| Extinction Ratio | >30 dB(depends on actual sizes ) |
| Barrel Finish | 400 grit |
| Crystal Structure | cubic – la3d |
| Lattice Constants | 12.01 Å |
| Density | 4.56 g/cm3 |
| Melting Point | 1950 °C |
| Thermal Conductivity/(W·m-1·K-1@25°C) | 14 |
| Specific Heat/(J·g-1·K-1) | 0.59 |
| Rupture Stress | 1.3-2.6*103 kg/cm2 |
| Thermal Expansion /(10-6·K-1@25°C ) | [100] Orientation–8.2 |
| [110] Orientation–7.7 | |
| [111] Orientation–7.8 | |
| Hardness (Mohs) | 8.5 |
| Young`s Modulus/GPa | 317 |
| Shear Modulus/Gpa | 54.66 |
| Extinction Ratio | 25 dB |
| Poisson Ratio | 0.25 |
| Laser Transition | 4F3/2 →> 4I11/2 |
| Photon Energy | 1.86×10-19 J |
| Laser Transition Wavelength, λl (nm) | 1064 |
| Pump Transition Wavelength, λp (nm) | 808 |
| Pump Transition Bandwidth, Δλp (nm) | <4 |
| Laser Transition Bandwidth, Δλl (nm) | ~0.6 |
| Pump Transition Peak Cross Section, σp (E-20 cm2) | 6.7 |
| Laser Transition Peak Cross Section, σl (E-20 cm2) | 28 |
| Pump Transition Saturation Intensity, φp (kW/cm2) | 12 |
| Laser Transition Saturation Intensity, φl (kW/cm2) | 2.6 |
| Laser Transition Saturation Fluence, Γl,sat (J/cm2) | 0.6 |
| Minimum Pump Intensity, Imin (kW/cm2) | ~0 |
| Upper Laser Manifold Lifetime, τ(msec) | 0.26 |
| Quantum Defect Fraction | 0.24 |
| Fractional Heat Generation | 0.37 |
| Refractive Index | 1.8197 @1.064 µm |
| Fluorescence Lifetime | 230 µs |
