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TN-EVV195-II-HH-SS
TN
Introducing our state-of-the-art Thermal Evaporation Coating Instrument, designed to meet the diverse needs of thin film deposition in various industries. This cutting-edge instrument is equipped with advanced technology to provide high-quality coatings for a wide range of applications.
Our Thermal Evaporation Coating Instrument is capable of depositing a variety of coatings, including optical coatings, metallic and dielectric coatings, decorative coatings, barrier coatings, and protective coatings. Whether you require a thin film for optical purposes or a protective coating for industrial applications, our instrument can deliver exceptional results.
One of the key features of our Thermal Evaporation Coating Instrument is its high vacuum thermal evaporation capability. This technology allows for precise control over the deposition process, ensuring uniform and consistent coatings every time. With this instrument, you can achieve the desired thickness and composition of the coating with ease.
In addition to its advanced capabilities, our Thermal Evaporation Coating Instrument is designed for ease of use and reliability. Its user-friendly interface and intuitive controls make it simple to operate, while its robust construction ensures long-lasting performance.
Trust our Thermal Evaporation Coating Instrument to meet your thin film deposition needs with precision and efficiency. Contact us today to learn more about how this instrument can benefit your business.
High vacuum thermal evaporation coating instrument technical parameters:
Product name | High vacuum dual source thermal evaporation coating | |
Product model | TN-EVV195-II-HH-SS | |
Sample stage | Position | Top setting |
Dimensions | Diameter φ65mm | |
Speed | 0-20 rpm | |
Pitch | Adjustable distance between sample holder and evaporation source | |
Adjustable temperature | ≦500℃ | |
Thermal evaporation source | Tungsten wire basket × 2, tungsten boat × 2 | |
Evaporation power supply | Each evaporation source is equipped with an independent power supply; two evaporation sources can be evaporated at the same time | |
Vacuum chamber | Cavity size | diameterφ195mm×H210mm |
Observation window | diameterφ100mm | |
Cavity material | 304 Stainless steel | |
Opening method | Open cover | |
Film thickness measurement | Crystal film thickness measuring instrument (film thickness controller is also optional) | |
Vacuum system | Foreline pump | Bipolar rotary vane pump, gas pumping speed 1.1L/S |
Secondary pump | Turbomolecular pump, gas pumping speed 600L/S | |
Vacuum measurement | Compound vacuum gauge (ionization gauge + resistance gauge) | |
System vacuum | 5×10-4Pa | |
Control System | CYKYSelf-developed professional-grade controller | |
Other parameters | Power supply | AC380V,50Hz |
Complete size | 600mm×650mm×1500mm | |
Complete power | 7KW | |
Complete weight | 260kg | |
high vacuum thermal evaporation coater is a piece of equipment used for depositing thin films onto substrates through a thermal evaporation process in a high vacuum environment. Here are the primary purposes and applications of a high vacuum thermal evaporation coater:
Thin Film Deposition: The primary purpose of a high vacuum thermal evaporation coater is to deposit thin films of various materials, such as metals, semiconductors, and dielectrics, onto substrates. The process involves heating a material in a high vacuum until it evaporates and then condenses onto the substrate, forming a thin film.
Microelectronics and Semiconductor Fabrication: Thermal evaporation is used in the semiconductor industry to deposit metal contacts, adhesion layers, and other conductive films on semiconductor wafers. It is a key technique in the fabrication of microelectronic devices such as transistors, diodes, and integrated circuits.
Optical Coatings: The coater is widely used to apply optical coatings, including anti-reflective coatings, beam splitters, and mirrors, onto lenses, glass, and other optical components. The high vacuum environment ensures that the coatings are uniform, pure, and have the desired optical properties.
Metallic and Dielectric Coatings: High vacuum thermal evaporation is used to deposit both metallic films (such as gold, silver, aluminum) and dielectric films (such as silicon dioxide, titanium dioxide) for various applications, including reflective coatings, capacitors, and insulating layers.
Decorative Coatings: The coater is also used for decorative purposes, where thin metallic films are deposited onto consumer products like watches, jewelry, and electronic casings to give them a metallic finish or aesthetic appeal.
Research and Development: In research labs, thermal evaporation is a common method for preparing thin films for material science, physics, and nanotechnology research. The ability to control the thickness and uniformity of the film makes it a valuable tool for experimental studies and prototyping.
Fabrication of Organic and Inorganic Devices: Thermal evaporation is used in the fabrication of organic light-emitting diodes (OLEDs), thin-film transistors (TFTs), and other organic electronics. The technique is also employed in the production of inorganic thin-film devices like solar cells and sensors.
Nanotechnology Applications: In nanotechnology, thermal evaporation is used to deposit thin films for the fabrication of nanostructures and nanoscale devices. The high vacuum environment ensures that the deposition is clean and precise, which is crucial for nanoscale applications.
Barrier and Protective Coatings: The coater can be used to apply protective and barrier coatings on various substrates to enhance their durability, corrosion resistance, and other surface properties. These coatings are used in industries ranging from packaging to aerospace.
Overall, a high vacuum thermal evaporation coater is a versatile tool that plays a crucial role in various industries and research fields. It is valued for its ability to deposit high-purity, uniform thin films with precise control over thickness, making it essential for applications in microelectronics, optics, material science, and beyond.
Introducing our state-of-the-art Thermal Evaporation Coating Instrument, designed to meet the diverse needs of thin film deposition in various industries. This cutting-edge instrument is equipped with advanced technology to provide high-quality coatings for a wide range of applications.
Our Thermal Evaporation Coating Instrument is capable of depositing a variety of coatings, including optical coatings, metallic and dielectric coatings, decorative coatings, barrier coatings, and protective coatings. Whether you require a thin film for optical purposes or a protective coating for industrial applications, our instrument can deliver exceptional results.
One of the key features of our Thermal Evaporation Coating Instrument is its high vacuum thermal evaporation capability. This technology allows for precise control over the deposition process, ensuring uniform and consistent coatings every time. With this instrument, you can achieve the desired thickness and composition of the coating with ease.
In addition to its advanced capabilities, our Thermal Evaporation Coating Instrument is designed for ease of use and reliability. Its user-friendly interface and intuitive controls make it simple to operate, while its robust construction ensures long-lasting performance.
Trust our Thermal Evaporation Coating Instrument to meet your thin film deposition needs with precision and efficiency. Contact us today to learn more about how this instrument can benefit your business.
High vacuum thermal evaporation coating instrument technical parameters:
Product name | High vacuum dual source thermal evaporation coating | |
Product model | TN-EVV195-II-HH-SS | |
Sample stage | Position | Top setting |
Dimensions | Diameter φ65mm | |
Speed | 0-20 rpm | |
Pitch | Adjustable distance between sample holder and evaporation source | |
Adjustable temperature | ≦500℃ | |
Thermal evaporation source | Tungsten wire basket × 2, tungsten boat × 2 | |
Evaporation power supply | Each evaporation source is equipped with an independent power supply; two evaporation sources can be evaporated at the same time | |
Vacuum chamber | Cavity size | diameterφ195mm×H210mm |
Observation window | diameterφ100mm | |
Cavity material | 304 Stainless steel | |
Opening method | Open cover | |
Film thickness measurement | Crystal film thickness measuring instrument (film thickness controller is also optional) | |
Vacuum system | Foreline pump | Bipolar rotary vane pump, gas pumping speed 1.1L/S |
Secondary pump | Turbomolecular pump, gas pumping speed 600L/S | |
Vacuum measurement | Compound vacuum gauge (ionization gauge + resistance gauge) | |
System vacuum | 5×10-4Pa | |
Control System | CYKYSelf-developed professional-grade controller | |
Other parameters | Power supply | AC380V,50Hz |
Complete size | 600mm×650mm×1500mm | |
Complete power | 7KW | |
Complete weight | 260kg | |
high vacuum thermal evaporation coater is a piece of equipment used for depositing thin films onto substrates through a thermal evaporation process in a high vacuum environment. Here are the primary purposes and applications of a high vacuum thermal evaporation coater:
Thin Film Deposition: The primary purpose of a high vacuum thermal evaporation coater is to deposit thin films of various materials, such as metals, semiconductors, and dielectrics, onto substrates. The process involves heating a material in a high vacuum until it evaporates and then condenses onto the substrate, forming a thin film.
Microelectronics and Semiconductor Fabrication: Thermal evaporation is used in the semiconductor industry to deposit metal contacts, adhesion layers, and other conductive films on semiconductor wafers. It is a key technique in the fabrication of microelectronic devices such as transistors, diodes, and integrated circuits.
Optical Coatings: The coater is widely used to apply optical coatings, including anti-reflective coatings, beam splitters, and mirrors, onto lenses, glass, and other optical components. The high vacuum environment ensures that the coatings are uniform, pure, and have the desired optical properties.
Metallic and Dielectric Coatings: High vacuum thermal evaporation is used to deposit both metallic films (such as gold, silver, aluminum) and dielectric films (such as silicon dioxide, titanium dioxide) for various applications, including reflective coatings, capacitors, and insulating layers.
Decorative Coatings: The coater is also used for decorative purposes, where thin metallic films are deposited onto consumer products like watches, jewelry, and electronic casings to give them a metallic finish or aesthetic appeal.
Research and Development: In research labs, thermal evaporation is a common method for preparing thin films for material science, physics, and nanotechnology research. The ability to control the thickness and uniformity of the film makes it a valuable tool for experimental studies and prototyping.
Fabrication of Organic and Inorganic Devices: Thermal evaporation is used in the fabrication of organic light-emitting diodes (OLEDs), thin-film transistors (TFTs), and other organic electronics. The technique is also employed in the production of inorganic thin-film devices like solar cells and sensors.
Nanotechnology Applications: In nanotechnology, thermal evaporation is used to deposit thin films for the fabrication of nanostructures and nanoscale devices. The high vacuum environment ensures that the deposition is clean and precise, which is crucial for nanoscale applications.
Barrier and Protective Coatings: The coater can be used to apply protective and barrier coatings on various substrates to enhance their durability, corrosion resistance, and other surface properties. These coatings are used in industries ranging from packaging to aerospace.
Overall, a high vacuum thermal evaporation coater is a versatile tool that plays a crucial role in various industries and research fields. It is valued for its ability to deposit high-purity, uniform thin films with precise control over thickness, making it essential for applications in microelectronics, optics, material science, and beyond.
