quarter wave plate
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266nm Viertelwellenplatte nullter Ordnung 20Hz unterstützt Hochleistungslaser
Air Spaced Zero Order λ/4 Quarter Wave Plate, High Damage Threshold Overview: Air spaced zero order wave plate is built by placing a spacing ring between the two multi-order wave plates to form an air gab between them. The slow axis of one waveplate is aligned with the fast axis of the other waveplate. To achieve the required retardace will request carefully match the thickness differences of the two multi order waveplates. For high power lasers and applications require to
550–750 nm achromatische Viertelwellenplatte 13,5 mm Empfindlichkeit bei niedrigen Temperaturen
Achromatic Λ/4 Quarter Wave Plate, Wide Spectral Bandwidth For Tunable Lasers Overview: Achromatic Wave Plates (Retarders) are a pair of crystalline quartz and magnesium fluoride plates of controlled thickness with crossed fast axes to create a λ/2 or λ/4 delay in the broad wavelength range. Quarter wave plates can turn linearly polarized light into circularly polarized light and vice versa. The difference in dispersion between materials allows the arrangement of a slow phase
980-nm-Viertelwellenplatte mit mehreren Ordnungen Gute Wellenfrontverzerrung
Multiple Order λ/4 Quarter Wave Plate, High Damage Threshold, Low Cost Overview: A Multiple Order Wave plate is made from a single birefrigent crystal (crystal quartz is the most commonly used material) that produces an integer multiple of the rated retardance. Quarter Wave Plate is one of the common types of waveplates which converts linearly polarized light into circularly polarized light or vice versa. While a multiple order waveplate produces an integer multiple of rated
Single Plate Optical Waveplate 1030 mm Viertelwellenplatte
Single Plate High Power Quartz Waveplate, High Energy, Wide Acceptance Angle Overview: Single Plate High Power Quartz Wavep lates are available in both λ/4 and λ/2 retardance for discrete laser wavelengths from the UV to NIR and can withstand energy densities up to >10 J/cm2 at 1064nm. A large acceptance angle and wide operating temperature range enables these waveplates to be integrated into harsh environments applications. The extremely thin thickness which can be made down
λ/2 halbe Viertelwellenplatte 266nm
Multiple Order λ/2 Half Wave Plate, High Damage Threshold, Low Cost Overview: Multiple Order Wave plate means the fact that the retardance of a light path will undergo a certain number of full wavelength shifts in addition to the fractional design retardance. Half Wave Plates are typically used to rotate the polarization of light. The net effect of multi order waveplate at the design wavelength is basically the same as zero order waveplate. But the optical bandwidth is
20 mm Optische Wellenplatte Optischer Pfad Klebstofffreie Quarz-Wellenplatte
Optically Contacted Zero Order Λ/4 Quarter Wave Plate, Optical Path Glue-Free Overview: Optically contacted zero order waveplate is made from two multiple order plates with slightly different thicknesses. The two plates are constructed by optically contacted method and this design allows the optically contacted zero order waveplate to operate well in relatively high power application and wide wavelength range. The slow axis of one waveplate is aligned with the fast axis of
λ/4-Viertel-Wellenplatten nullter Ordnung
True Zero Order λ/4 Quarter Wave Plate, Large Feild Angle, for imaging systems Overview: Comparing with normal two plates design Zero order waveplates having a relatively larger thickness which reduces the field angle, the True zero order wave plates are made of a very thin plate or cemented with a BK7 substrate, which ensures the best possible field angle, temperature and wavelength performance. If the angle between the electric field vector of the linearly polarized
Optische Verzögerungsplatte aus kristallinem Quarz mit 38,1 mm breiter Wellenlängenbandbreite
Cemented Zero Order λ/4 Quarter Wave Plate, High Retardance Overview: Cemented zero order wave plate is constructed by two quartz plates with their fast axis crossed. The retardance is determined by the difference in thickness between the two quartz plates. The main difference between cemented zero order waveplates and other kind of waveplates is they have epoxy on its optical path as the two quartz plates are glued with each other by UV epoxy. However, cemented zero order
MgF2 Optische Wellenplatte Flatter Retardance Super Achromatische Wellenplatte
Super Achromatic Waveplate Flat Retardance Over A Super Broad Spectral Range Overview: Super Achromatic Wave plate (Retarder) consists of three achromatic waveplates (made of quartz, MgF2 and sapphire) that optically cemented to maximize transmission and carefully aligned to minimize the wavelength dependence of the retardance based on Pancharatnama's design is used for modulator in polarimeter. Comparing to the normal achtomatic waveplate which consists of one quartz plate
