Thin Film Collection

Soap bubbles merging

Thin-film thermocouples C016 / 6482
Thin-film thermocouples. Thermocouples, used for temperature measurements, are based on the thermoelectric effect between two metals

Thin-film thermocouple C016 / 6484
Thin-film thermocouple, close-up. Thermocouples, used for temperature measurements, are based on the thermoelectric effect between two metals

Thin-film thermocouple C016 / 6486
Thin-film thermocouple, close-up. Thermocouples, used for temperature measurements, are based on the thermoelectric effect between two metals

Thin-film thermocouple C016 / 6483
Thin-film thermocouple. Thermocouples, used for temperature measurements, are based on the thermoelectric effect between two metals

Thin-film thermocouple C016 / 6485
Thin-film thermocouple, close-up. Thermocouples, used for temperature measurements, are based on the thermoelectric effect between two metals

Thin-film thermocouples C016 / 6481
Thin-film thermocouples. Thermocouples, used for temperature measurements, are based on the thermoelectric effect between two metals

Thin-film thermocouples C016 / 6480
Thin-film thermocouples. Thermocouples, used for temperature measurements, are based on the thermoelectric effect between two metals

Soap bubble film iridescence C017 / 8528
Soap bubble film iridescence. Iridescence is the property of certain surfaces to change colour depending on the angle of light refraction or reflection, or the angle of view

Soap bubble film iridescence C017 / 8529
Soap bubble film iridescence. Iridescence is the property of certain surfaces to change colour depending on the angle of light refraction or reflection, or the angle of view

Soap bubble iridescence C017 / 8525
Soap bubble iridescence. Iridescence is the property of certain surfaces to change colour depending on the angle of light refraction or reflection, or the angle of view

Soap bubble iridescence C017 / 8524
Soap bubble iridescence. Iridescence is the property of certain surfaces to change colour depending on the angle of light refraction or reflection, or the angle of view

Soap bubble iridescence C017 / 8523
Soap bubble iridescence. Iridescence is the property of certain surfaces to change colour depending on the angle of light refraction or reflection, or the angle of view

MEMS production, furnace processing
MEMS production. Row of silicon wafers entering a furnace during the process of producing MEMS (microelectromechanical systems) devices

MEMS production
MODEL RELEASED. MEMS production. Clean room technician lifting a container of silicon wafers being used to produce MEMS (microelectromechanical systems) devices

Sphalerite ore, macrophotograph
Sphalerite. It is composed of zinc sulphate and the principal ore of zinc, it is found as either isometric tetrahedral crystals or in compact crypotocrystalline masses

Interference pattern. Light micrograph of interference patterns on a soap film. The different colours are due to interference of reflected light waves

Soap film patterns sequence. The sequence starts at left and ends at right. Over time, under the influence of gravity, the soap film degrades and breaks up

Soap film patterns. When white light is shone on a soap film (a thin mix of soap and water), coloured interference patterns are formed that correspond to the thickness of the film

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"Captivating Colors and Precision: Exploring the World of Thin Film" Step into a mesmerizing world where soap bubbles dance with vibrant hues, revealing an enchanting interference pattern. This captivating phenomenon is none other than thin film, a fascinating scientific concept that has found its way into various applications. One such application is in the realm of temperature measurement. Enter the realm of thin-film thermocouples - C016 / 6482, C016 / 6484, C016 / 6486, C016 / 6483, C016 / 6485 - these delicate sensors provide accurate readings by utilizing the principles technology. With their slim design and precise measurements, they have become invaluable tools in industries ranging from aerospace to automotive. But what exactly is this mysterious thin film? Picture a delicate soap bubble floating through the air; its iridescent shimmer catching your eye. That very same iridescence can be attributed to a soap bubble's thin film structure - layers upon layers of molecules forming an interference pattern that reflects light in stunning colors. Scientists have harnessed this natural phenomenon to create films for various purposes. In addition to thermocouples, thin films find themselves employed in diverse fields like optics and electronics. They play crucial roles in creating anti-reflective coatings on lenses or enhancing solar cell efficiency by reducing reflection loss. The precision offered by these films enables advancements in display technologies like LCDs and OLEDs as well. The possibilities seem endless when it comes to exploring the potential of thin films. From improving energy conversion systems to revolutionizing communication devices, their versatility knows no bounds. Researchers continue pushing boundaries with innovative designs such as Soap Bubble Film Iridescence (C017/8528) and (C017/8529), unlocking new realms of aesthetic beauty combined with scientific breakthroughs. So next time you spot a soap bubble glistening under sunlight or marvel at an interference pattern, take a moment to appreciate the wonders of thin film.