Dichroic mirror
Dichroic mirrorIt refers to separating the light source into a specific spectrum and changing the light path direction of part of the spectrum when it is incident at 45 degrees or at a large angle. It
Dichroic mirror is an optical component that selectively reflects certain wavelengths (colors) of light while transmitting others. This is achieved through the interference properties of thin-film coatings deposited on the surface of the mirror. These coatings are designed to have different refractive indices and thicknesses, which enables them to reflect specific wavelengths based on the principles of optical interference. It is often used in sensor systems such as fluorescence microscope systems of enzyme label instruments, projection light engine systems, laser lights, optical instrument beam splitters, and video eyes. It is an optical component that optical designers are enthusiastically pursuing. The structure of the device can be effectively reduced to realize a multifunctional optical path.
Types of Dichroic Mirrors
Dichroic mirrors are classified by the way in which they transmit light. Types of dichroic mirrors include longpass dichroic mirrors, shortpass dichroic mirrors, and multi band dichroic mirrors. Hot and cold mirrors used to reflect or otherwise suppress unwanted heat in thermal sensitive applications are also dichroic mirrors.
Longpass dichroic mirrors will have a cut-on wavelength that separates a highly reflective and transmissive band. Longer wavelengths, above the cut on wavelength, are freely transmitted through the mirror, while shorter wavelengths are reflected back.
A shortpass dichroic mirror features a cut-off wavelength. Radiation above the cut-off wavelength experiences high reflectance, while radiation below the cut-off wavelength is transmitted.
Multi-band dichroic mirrors have both a cut-off and cut-on wavelength, and two transmission bands as well as one reflective band. The wavelength range between the cut-off and cut-on wavelength is highly reflective, while wavelength ranges above the cut-on and below the cut-off wavelengths are highly transmissive.
Dichroic mirrors find extensive use in many optical systems and instruments, including:
Optical Imaging
In fluorescence microscopy, they are used to separate the excitation light from the emitted fluorescence, allowing clear visualization of specific stained samples.
Laser Systems
They can be used to combine or separate laser beams of different wavelengths in laser-based applications such as laser shows, medical equipment, or industrial material processing.
Entertainment
LightingIn stage lighting and special effects, dichroic filters are used to create color effects by reflecting certain colors while transmitting others.
Telecommunications
They play a role in wavelength division multiplexing (WDM) systems, where multiple signals of different wavelengths are combined or separated for transmission along optical fibers.
Product parameters
Coating | IAD multilayer dielectric coating |
S1 | AR Coating 420-680nm@R<1% |
S2 | Dichroic coating |
Transmittance average in working band | T>95% |
Reflection average in working band | R>95% |
Size | 2*2~146*146mm, φ3~110mm |
Thickness | 0.3-5.0mm |
Clear aperture | >95% |
Surface quality | 40-20(S/D) |
Environmental testing | MIL-STD-810F |
General application
Model | Application | CWL | Transmission wavelength | Reflection wave | AR coating wavelength |
GA-DMSP-594 | Micro projection | 594 | 430-588nm | 600-650nm | 420-680nm |
GA-DMSP-486 | Micro projection | 486 | 430-470nm | 494-650nm | 420-680hm |
GA-DM P-675 | Fluorescence microscope | 675 | 690-800nm | 610-650nm | 420-800nm |
GA-DMLP-495 | Fluorescence microscope | 495 | 510-680nm | 450-480nm | 420-680nm |
GA-DMSP-560 | Fluorescence microscope | 560 | 530-550nm | 570-590nm | 420-680nm |
GA-DMSP-583 | Stage lighting | 583 | 420-560nm | 600-650nm | 420-680nm |
GA-DMLP-486 | Stage lighting | 486 | 490-650nm | 430-470nm | 420-680nm |
- Type: __Dichroic Mirror__
- Application: ____________________________ (e.g., Fluorescence microscopy, laser separation, optical filters)
Reflectance & Transmission Bands
- Reflective Wavelength Range: From ______ nm to ______ nm
- Reflectance Within Band: ≥ _______%
- Transmissive Wavelength Range: From ______ nm to ______ nm
- Transmittance Within Band: ≥ _______%
Cut-On/Cut-Off Specifications
- Cut-On Wavelength (if applicable): ______ nm
- Cut-Off Wavelength (if applicable): ______ nm
- Transition Width: ≤ ______ nm (The range over which reflection or transmission changes from low to high)
Angular Performance
- Angular Range: ± ______ ° (The range of angles at which the dichroic performance is maintained)
- Polarization Dependence: Yes / No (If yes, specify details)
Coating & Substrate Characteristics
- Coating Technology: ____________________ (E.g., Dielectric stack, metal-dielectric hybrid)
- Substrate Material: ________________________ (E.g., BK7, fused silica, quartz, etc.)
- Surface Quality: __________________________ (Scratch-Dig standard)
- Thickness: ______________________________ mm (If specific requirement)
Physical Characteristics
- Size/Shape: ______________________________ (Dimensions and shape, e.g.,圆形,矩形)
- Coating Coverage: ________________________ (Full area or partial)
- Surface Flatness: λ/____ (RMS or PV)
- Parallelism (if applicable): ± ______ °
Environmental & Operational Requirements
- Operating Temperature Range: From ______ °C to ______ °C
- Storage Temperature Range: From ______ °C to ______ °C
- Humidity Resistance: _______________________% RH
- Laser Damage Threshold (if applicable): ______ W/cm²
Additional Requirements or Tests
- Custom Mounting Holes or Tabs: Yes / No
- Adhesion Test: Yes / No
- Environmental Testing (optional): __________________
Notes or Special Instructions
- __________________________________________________________
- __________________________________________________________
This detailed specification sheet enables us to manufacture a custom dichroic mirror that precisely suits your application's wavelength separation needs, ensuring optimal performance in terms of reflection and transmission bands. Once we receive this completed form, we can proceed with the design, coating, and fabrication of your dichroic mirror, followed by thorough quality checks and delivery.