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Ruby Rod Laser Technology Medical Instruments Made From Synthetic Sapphire Dia 1×7cm

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Ruby Rod Laser Technology Medical Instruments Made From Synthetic Sapphire Dia 1×7cm

Brand Name	ZMSH
Model Number	RUBY ROD
Place of Origin	China
Payment Terms	T/T
Delivery Time	2-4 weeks
Material	Synthetic Ruby (Aluminum Oxide)
Diameter	ypically ranges from a few millimeters to centimeters, depending on the application
Length	Customizable based on specific requirements
Wavelength Range	Typical Ruby laser wavelength is 694 nanometers (orange-red spectrum)
Refractive Index	Ruby's refractive index is approximately 1.77
Laser Line Width	Depends on laser design and tuning
Thermal Conductivity	Approximately 0.035 W/(cm·K)
Hardness	Approximately 9 on the Mohs scale

Detailed Product Description

ruby rod Laser Technology Medical Instruments made from synthetic sapphire dia 1×7cm

ruby rod's abstract

The Ruby Rod, a cylindrical component typically crafted from synthetic ruby (aluminum oxide), embodies unique optical and physical properties that render it indispensable across diverse applications. With diameters spanning from millimeters to centimeters and customizable lengths, these rods serve as pivotal elements in laser technology, particularly in the creation of ruby lasers with a characteristic wavelength of 694 nanometers, emitting vibrant orange-red light. Their refractive index, approximately 1.77, showcases their suitability for optical applications.

The thermal conductivity of Ruby Rods, measuring around 0.035 W/(cm·K), and their exceptional hardness, scoring approximately 9 on the Mohs scale, contribute to their resilience in challenging environments. This robustness, coupled with good temperature stability, positions Ruby Rods as core components in medical aesthetic devices for procedures like laser tattoo removal and pigmented lesion treatment.

Beyond medical applications, Ruby Rods find extensive use in optical research, industrial processes such as laser cutting and welding, and the calibration of optical instruments like spectrometers. Their fluorescence properties, contingent on specific wavelengths and excitation conditions, make them valuable in scientific experiments.

In education, Ruby Rods play a vital role in illustrating optical principles and laser concepts. Their versatility and adaptability, stemming from a combination of precise engineering and material excellence, make Ruby Rods indispensable in advancing technology, driving research, and facilitating innovative applications across a spectrum of industries.

ruby rod's key feature

Ruby rods, crafted predominantly from synthetic ruby (aluminum oxide), boast key features that set them apart in various applications. One defining characteristic is their versatility in diameter, ranging from a few millimeters to centimeters, providing adaptability to different use cases. This flexibility extends to customizable lengths, tailoring the rods to specific requirements.

At the core of their significance is their role in laser technology. Ruby rods serve as essential components in ruby lasers, emitting coherent light at a wavelength of approximately 694 nanometers, contributing to their distinctive orange-red spectrum. The unique refractive index of around 1.77 underscores their suitability for optical applications, ensuring efficient light propagation.

Ruby rods exhibit exceptional hardness, scoring approximately 9 on the Mohs scale, showcasing their durability and resilience. This hardness, coupled with a thermal conductivity of about 0.035 W/(cm·K), contributes to their stability in challenging thermal environments, making them integral to medical aesthetic devices like laser tattoo removal tools.

The fluorescence properties of ruby rods, contingent on specific wavelengths and excitation conditions, enhance their utility in scientific experiments and optical research. In industrial contexts, these rods find application in laser cutting and welding processes, showcasing their versatility across sectors.

Beyond their functional aspects, ruby rods play a pivotal role in educational settings, serving as tangible demonstrations of optical principles and laser concepts. This educational value, combined with their precision engineering, positions ruby rods as invaluable tools for advancing technology and driving innovation across diverse industries, from medical aesthetics to scientific research and beyond.

ruby rod's showcase

ruby rod's application

Ruby rods, predominantly engineered from synthetic ruby (aluminum oxide), encapsulate a set of key features that render them indispensable across a spectrum of applications. With diameters ranging from a few millimeters to centimeters, these rods exhibit a remarkable adaptability, accommodating diverse use cases. Additionally, their lengths are customizable, allowing tailored configurations to meet specific requirements.

A hallmark application of ruby rods lies in laser technology, where they serve as essential components in ruby lasers. Emitting coherent light at a distinctive wavelength of approximately 694 nanometers, these rods contribute to the creation of lasers with a vibrant orange-red spectrum. The unique refractive index, around 1.77, further emphasizes their suitability for optical applications, ensuring efficient light propagation and manipulation.

The exceptional hardness of ruby rods, scoring approximately 9 on the Mohs scale, stands as a testament to their durability and resilience. This inherent hardness, coupled with a commendable thermal conductivity of about 0.035 W/(cm·K), establishes their stability even in challenging thermal environments. Consequently, ruby rods find integral application in medical aesthetic devices, particularly in laser tattoo removal tools, where precision and reliability are paramount.

Beyond their fundamental characteristics, the fluorescence properties of ruby rods, contingent on specific wavelengths and excitation conditions, enhance their utility in scientific experiments and optical research. In industrial contexts, these rods are pivotal in processes such as laser cutting and welding, showcasing their versatility and effectiveness across sectors.

Apart from their functional significance, ruby rods play a crucial role in educational settings, serving as tangible and illustrative tools for conveying optical principles and laser concepts. This educational value, coupled with the precision engineering embedded in ruby rods, positions them as invaluable instruments for advancing technology and driving innovation across diverse industries. From medical aesthetics to scientific research, the ruby rod's key abstract lies in its ability to combine material excellence with functional versatility, thereby shaping advancements in various technological domains.

ruby rod's application Physical and Optical Properties

Density		3.98 g/cc		Refractive index at 700 nm	1.7638 Ordinary Ray
Melting Point		2040°			1.7556 Extraordinary Ray
Young's Modulus		345 Gpa		Birefringence	0.008
MOR		425 MPa		Refractive Index vs. Chromium Concentration	3 x 10^-3 (Δn / % Cr_2O3)
Compressive Strength		2.0 Gpa		Fluorescent Lifetime at 0.05% Cr_2O3	3 ms at 300 K
Hardness		9 Mhos, 2000 Knoop		Fluorescent Linewidth (R₁)	5.0 Å at 300K
Thermal Expansion	20° to 50° C	5.8 x 10-6 / ° C		Output Wavelength (R₁)	6.94.3 nm
Thermal Expansion	20°to 200° C	7.7 x 10-6 / ° C		Major Pump Bands	404 nm and 554 nm
Thermal Conductivity	at 0° C	46.02 W / (m•K)
	at 100° C	25.10 W / (m•K)
	at 400° C	12.55 W / (m•K)	All values are for 60° orientation material

Material and Fabrication Specification

Material
Crystallographic orientation, optical (c - axis) to rod axis			60° within 5°
Dopant Concentration: Cr₂O₃ Weight Per Cent Substitution for Al₂O₃			0.05% ± 0.005%
			0.03% ± 0.005%
Optical Quality, Double - Pass Interferometer set for minimum fringes in rod, all diameters to 1.00" (25.4 mm)		SIQ GRADE	SELECT GRADE
		0.5 fringes / inch of length	0.25 fringes / inch of length
Corefree Diameter		0.756" and smaller	0.625" and smaller
Bubbles, inclusions, scattering sites as viewed in white,focused illuminator light and under crossed polarisers		Free of imperfections visible to the naked eye
				Fabrication
Diameter Tolerance			± 0.001" (0.025 mm)
Length Tolerance		(Plano / Plano)	± 0.030" (0.75 mm)
Barrel Finish - Standard			30 microinch CLA
Polished Barrel Finish - Special Order			80 - 50
End Face Bevel		0.005" / 0.010" (0.1 / 0.25 mm) non - focusing radius type;bevel to 0.013" allowed to remove chips on large rods
				Chips	None on polished and faces. Up to 0.012" (0.3 mm) allowed to lie in area of bevel and extend into barrel surface
Flatness	Rod Diameters 0.590" (15 mm) and smaller	1 / 10th wave over 90% of diameter
	Rod Diameter 0.625" (16 mm) and larger	<1 / 5th wave over 90% of diameter
Parallelism of ends faces (measured geometrically with autocollimator and precision rotary table; 2 readings 90° rotation)

Plano / Plano			10 seconds of arc or less
Wedge / Wedge			20 seconds of arc or less
Brewster / Brewster			30 seconds of arc or less
Perpendicularity of end faces to rod axis		Standard	5 minutes of arc or less
		Special Order	2 minutes of arc or less
Surface Finish (viewed in low - angle, reflected light from high - intensity		Standard	20 - 10
microscope illuminator with condenser, by naked eye and 5X loupe)		Special Order	10 - 5
Brewster Angle			20° 34'
Brewster Angle Tolerance			± 30 minutes
Wedge Angle			15' to 8°
Wedge Angle Tolerance			± 10 minutes
Anti - Reflection Coating		Single layer magnesium fluoride, suitable for high power laser operation. Reflectivity at 694 nm is less than 0.25% per end face.
					Meets adherence and abrasion resistance of MIL - C - 48497

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Product Tags: Laser Synthetic Ruby Sapphire Ruby Sapphire Rod Medical Instruments Ruby Rod

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Ruby Rod Laser Technology Medical Instruments Made From Synthetic Sapphire Dia 1×7cm

Ruby Rod Laser Technology Medical Instruments Made From Synthetic Sapphire Dia 1×7cm

ruby rod's abstract

ruby rod's key feature

ruby rod's showcase

ruby rod's application

ruby rod's application Physical and Optical Properties

Material and Fabrication Specification

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