Electron Beam Deposition for Film Coating

Introduction

Electron beam deposition is a form of physical vapor deposition (PVD) in which the target anode material is bombarded with a stream of electrons generated by a tungsten filament. Electron beam thin film deposition techniques are widely used in R&D as well as in mass production applications.

Electron beam deposition is performed in a vacuum, typically starting the process at levels below 10-5 Torr. Once a suitable vacuum is reached, a tungsten filament in the electron beam source emits a stream of electrons. This electron beam can be generated in various ways, including thermionic emission, field electron emission, or ion arc source, depending on the design of the source and associated power supply.

In all cases, the negatively charged electrons are attracted to the positively charged anode material. The generated electron beam is accelerated to high kinetic energy and directed towards the material to be deposited on the substrate. This energy is converted into heat by interacting with the atoms of the evaporated material.

The purpose of generating a stream of electrons in an electron beam source is to heat the deposited material to a temperature above a vapor pressure threshold at a given background pressure. The vapor stream is then condensed onto the surface of the substrate.

Schematic representation of electron beam evaporation system depicting various parts.
Schematic representation of electron beam evaporation system depicting various parts.. Mohanty, P. & Kabiraj, Debdulal & Mandal, R.K. & Kulriya, Pawan Kumar & Sinha, Ask & Rath, Chandana. (2014). Evidence of room temperature ferromagnetism in argon/oxygen annealed TiO2 thin films deposited by electron beam evaporation technique. Journal of Magnetism and Magnetic Materials. 355. 240–245. 10.1016/j.jmmm.2013.12.025.

Deposition Rate

As with all thermal evaporation systems, the electron beam deposition rate depends on the temperature of the material being deposited and the vapor pressure (physical constant) of that material. For elemental materials, there is a fixed vapor pressure for any particular background pressure (vacuum) and material temperature. However, for alloys or composites, there may be different partial pressures associated with each component.

Compared with Sputter Coating

Unlike sputter deposition, where individual atoms arrive at the substrate surface with very high velocity and momentum, the thermally generated vapor stream arrives at the substrate surface at a considerably lower velocity, but a much greater velocity. In other words, e-beam deposition rates can be orders of magnitude greater than sputter deposition rates, making e-beam coatings very beneficial for high volume production or thick film requirements. One disadvantage, however, is that the material tends to condense directly on the substrate surface due to the different kinetic energy of the arriving species during electron beam evaporation than that of the sputtered species. In contrast, atoms of sputtered materials tend to penetrate several atomic layers (or more) to the substrate surface before losing momentum and then establishing cohesive bonds in nucleation structures and film growth. Thus sputtered films tend to provide better adhesion properties than thermally evaporated materials.

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An Overview of Mammary Gland Molybdenum Target X-Ray Inspection

Technology Introduction

Molybdenum target inspection is a new digital imaging technology that combines traditional radiology technology with modern computer technology. It finally transforms the ordinary X-ray image into a digital image that can be quantized. The traditional X-ray film technology and the qualitative quality of image quality make it easier for radiologists to find suspicious malignant lesions in mammography, which is considered to be a method to improve the early detection rate of breast cancer.

Advantages

The mammography system has the characteristics of clear imaging, convenient and quick inspection operation, and small radiation dose. The instrument can accurately detect the shape, size, density, and nature of breast hyperplasia, lesions, masses, and calcifications. It can accurately judge and identify calcifications of breast lesions that cannot be identified by color Doppler ultrasound, and is known as the “gold standard” for international breast disease examination.

As a non-invasive method of examination, mammary gland Molybdenum target X-Ray inspection has a relatively small pain in the examination of the breast. The images retained are available for comparison before and after, regardless of the limit of age or body shape. Mammography has now become a routine breast disease examination with a sensitivity of 82% to 89% for breast cancer and a specificity of 87% to 94%.

Molybdenum target mammograms of a patient.
Molybdenum target mammograms of a patient. (a) and (b) are molybdenum target mammograms of the patient’s left breast from the craniocaudal (CC) and mediolateral oblique (MLO) views, respectively, while (c) and (d) are molybdenum target mammograms of the patient’s right breast from the CC and MLO views, respectively. Sun, Lilei & Jie, Wen & Wang, Junqian & Zhao, Yong & Zhang, Bob & Wu, Jian & xu, Yong. (2022). Two‐view attention‐guided convolutional neural network for mammographic image classification. CAAI Transactions on Intelligence Technology. n/a-n/a. 10.1049/cit2.12096. 

Unique value

1 It can be used as a relatively non-invasive method of examination, and it can fully and accurately reflect the structure of the entire breast.

2 Molybdenum target inspection can be used to observe the effects of various physiological factors (such as menstrual cycle, pregnancy, lactation, economic status and endocrine changes) on the mammary gland structure, and can be used for dynamic observation.

3 Benign lesions and malignant tumors of the breast are relatively reliably identified.

4 Breast cancer can be detected early, and even occult breast cancer that is not clinically detectable can be detected.

5 According to the Molybdenum target inspection, some precancerous lesions can be found and can be followed up for observation.

Conclusion

In conclusion, Mammary gland Molybdenum target X-Ray inspection is currently the first choice and the easiest and most reliable non-invasive detection method to diagnose breast diseases. It is relatively less painful, easy to operate, and has high resolution.

Stanford Advanced Materials (SAM) Corporation is a global supplier of various sputtering targets such as metals, alloys, oxides, and ceramic materials which are widely used in the medical industry.  We will regularly update knowledge and interesting stories of sputtering targets on our website. If you are interested, please visit https://www.sputtertargets.net/ for more information.

Metal Molybdenum Target Used in Mobile Phone LCD Screen

Nowadays, mobile phones have become the most indispensable thing for the masses. Mobile phone displays are also becoming more and more high-end, such as full-screen designs, small bang designs, and so on.

One of the most important steps in making a mobile phone LCD screen is thin film coating, using magnetron sputtering to sputter the molybdenum target onto the liquid crystal glass to form a Mo thin film. Molybdenum thin films have the advantages of high melting point, high electrical conductivity, low specific impedance, good corrosion resistance and good environmental performance. Compared with the chromium film, the specific impedance and film stress of the molybdenum film are only half of that.

As an advanced film material preparation technology, sputtering has two characteristics of “high speed” and “low temperature”. It concentrates ions into a high-speed ion stream in a vacuum to bombard a solid surface. The kinetic energy exchange between the ions and the atoms on the solid surface causes the atoms on the solid surface to leave the target and deposit on the surface of the substrate to form a nano (or micro) film. The bombarded solid is a material for depositing a thin film by sputtering, which is called a sputtering target.

mobile phone lcd screen

In the electronics industry, molybdenum sputtering targets are mainly used for flat panel displays, electrodes and wiring materials for thin film solar cells, and barrier materials for semiconductors. These are based on its high melting point, high electrical conductivity, low specific impedance, good corrosion resistance, and good environmental performance.

Molybdenum used in components of LCDs can greatly improve the brightness, contrast, color, and life of the LCD. One of the major applications for molybdenum sputtering targets in the flat panel display industry is in the TFT-LCD field.

In addition to the flat panel display industry, with the development of the new energy industry, the application of molybdenum sputtering targets on thin film solar photovoltaic cells is also increasing. The molybdenum sputtering target mainly forms a CIGS (Copper Indium Gallium Selenide) thin-film battery electrode layer by sputtering. Among them, molybdenum is at the bottom of the solar cell, and as a back contact of the solar cell. It plays an important role in the nucleation, growth, and morphology of the CIGS thin film crystal.

For more information, please visit https://www.samaterials.com/.

History of Thermal Evaporation for Thin Film Coating

Thermal evaporation, or vacuum evaporation, refers to the vaporization of evaporation materials. By heating evaporation materials to a certain temperature, the vapor pressure becomes appreciable, and the surface or molecules are lost from the surface in the vacuum. Vaporization can come from the surface of a liquid or from the surface of a solid. The equilibrium vapor pressure (EVP) is 10-2 Torr. Some evaporation materials have a vapor pressure so that they can sublime or evaporate (e.g., titanium) at temperatures near their melting points. Some composites sublime and some evaporate.

Thermal Evaporation Materials. (Gold, Silver, Titanium, Silicon Dioxide, Tungsten, Copper)
Thermal Evaporation Materials. (Gold, Silver, Titanium, Silicon Dioxide, Tungsten, Copper)

From late 1800s to early 1900s

Studies about thermal evaporation in vacuum began in the late 19th century. In the 1880s, H. Hertz and S. Stefan determined the equilibrium vapor pressure, but they did not consider using of vapor to form thin films.
In 1884, Thomas Edison applied for a patent covering the vacuum evaporation of “heating to incandescence” and film deposition. However, his patent makes no mention of the evaporation of molten materials, and many materials do not evaporate at an appreciable rate until they reach or exceed their melting point. Edison did not use the process in any application, presumably because radiant heating from the source was detrimental to the vacuum materials available at the time.

 

In 1887, Nahrwold reported the formation of platinum thin films by subliming platinum evaporation materials in a vacuum. Therefore, some believe that he was the first to use thermal evaporation to form thin films in a vacuum.

In 1907, Soddy proposed that it would be possible to evaporate solid calcium onto the surface to reduce the residual pressure in the sealed tube. This is believed to be the first “reactive deposition” process in history.

In 1909, Knudsen proposed the “Knudsen Cosine Distribution Law” for vapor from a point source. After 6 years, he refined the free surface evaporation rate as a function of equilibrium vapor pressure and ambient pressure. The resulting equation is called the Hertz-Knudsen surface equation for free-surface vaporization. Honig summarized the equilibrium vapor pressure data for 1957.

Various Types of Evaporation Pellets
Various Types of Evaporation Pellets

From the early 1900s to the mid-1900s

In 1912, von Pohl and Pringsheim reported the formation of thin films by evaporating solid materials in a vacuum using a magnesia crucible as a container. Their experiments are sometimes considered the first thin-film deposition by thermal evaporation in a vacuum.

In 1931, Ritschl reported thermal evaporation of silver from a tungsten wire basket to form half-silvered mirrors. And he is often credited with being the first to use evaporation from a filament to form a film in a vacuum.

Evaporating Aluminum Thin-Film

Cartwright and Strong reported on the evaporation of metals from tungsten wire baskets in the same year. However, their attempts to vaporize aluminum failed, because molten aluminum would wet with the tungsten filament to form an alloy, which causes it to “burn out” when there is a relatively large volume of molten aluminum.

Aluminum thin films were not successfully produced by vacuum evaporation until 1933, when John Strong used large gauge tungsten filaments wetted by molten aluminum. John has done extensive development work for astronomical mirror coatings using the aluminothermic evaporation of multiple tungsten wires. Strong, with the help of designer Bruce Rule, used multiple filaments and a 19-foot diameter vacuum chamber to aluminize the 200-inch Palomar telescope mirror in 1947.

AR Coating

In 1933 A.H. Pfund vacuum-deposited the first single-layer (AR) coating (ZnS) while reporting on making beamsplitters and Bauer mentioned AR coatings in his work on the properties of alkali halides.

The Germans deposited CaF2 a nd MgF2 AR coatings during WWII. Plasma cleaning of glass surfaces is reported to have been used by Bauer at the Zeiss Company in 1934. The Schott Company (Germany) was also reported to have deposited three-layer AR coatings by flame-pyrolysis CVD during WWII.

In 1935, based on Bauer’s observation, A. Smakula of the Zeiss Company developed and patented AR coatings on camera lenses. The patent was immediately classified as a military secret and was not revealed until 1940.

In1936, Strong reported depositing AR coatings on glass.

In 1939, Cartwright and Turner deposited the first two-layer AR coatings.

One of the first major uses of coated lenses was on the projection lenses for the movie Gone With the Wind, which opened in December 1939. The AR-coated lenses gained importance in WWII for their light-gathering ability in such instruments as rangefinders and the Norden Bombsight.

The AR coated lenses gained importance in WWII for their light-gathering ability in such instruments as rangefinders and the Norden Bombsight. During WWII, baking of MgF2 films to increase their durability was developed by D.A. Lyon of the U.S. Naval Gun Factory. The baking step required that the lens makers coat the lens elements prior to assembly into compound lenses.

In 1943, the U.S. Army sponsored a conference on “Application of Metallic Fluoride Reflection Reducing Films to Optical Elements.” The proceedings of this conference are probably the first extensive publication on coating optical elements.

In 1958, the U.S. military formally approved the use of “vacuum cadmium plating” (VacCad) for application as corrosion protecmium. In recent years Physical Vapor Deposition (PVD) methods have been used to replace electroplating in a number of applications to avoid the water pollution associated with electroplating.

From the mid-1900s to the late 1900s

E-beam Evaporation Development

In 1949, Pierce described the “long-focus” electron beam gun for melting and evaporation in a vacuum. The long focus gun suffers from shorting due to the deposition of evaporated material on the filament insulators that are in the line of sight of the evaporating material. Deposition rates as high as 50 µm/s have been reported using e-beam evaporation. To avoid exposure of the filament to the vapor flux, bent-beam electron evaporators were developed.

In 1951, L. Holland patented the use of accelerated electrons to melt and evaporate the tip of a wire (“pendant drop”), which involved no filament or crucible.

In 1968, Hanks filed a patent on a 270° bent beam electron beam evaporation source that has become the most widely used design. Mastering the electron beam allows the energy of the electron beam to be distributed over the surface.

In 1970, Kurz was using an electron-beam system to evaporate gold for web coating. In electron beam evaporation a high negative “self-bias” can be generated on the surface of an insulating material or on an electrically isolated fixture. This bias can result in high-energy ion bombardment of the self-biased surface.

In 1971, Chambers and Carmichael avoided that problem by having the beam pass through a small hole in a thin sheet in a section of a plate that separated the deposition chamber from the chamber where the filament was located. This allowed a plasma to be formed in the deposition chamber while the filament chamber was kept under a good vacuum. The plasma in the deposition chamber allowed ion bombardment of the depositing film material as well as “activation” of reactive gas.

In 1972, the use of a hollow cathode electron emitter for e-beam evaporation was reported by J.R. Morley and H. Smith.

In 1978 H.R. Smith described a unique horizontally emitting electron beam (EB) vapor source. The source used a rotating crucible to retain the molten material, and its function was to coat large vertical glass plates. A number of thermoelectron-emitter e-beam source designs followed, including rod-fed sources and “multi-pocket” sources. The high voltage on the filament prevented the source from being used in a plasma where ions accelerated to the cathodic filament; this caused rapid sputter-erosion of the filament.

Crucible material Development

In 1951 Picard and Joy described the use of evaporation of materials from an RF-heated crucible. In 1966 Ames, Kaplan, and Roland reported the development of an electrically conductive TiB/BN composite ceramic (Union Carbide Co., UCAR™) crucible material that was compatible with molten aluminum.

Directed Deposition Development

The directed deposition is confining the vapor flux to one axis by eliminating off-axis components of the flux. Directed deposition can be attained by the collimation of the vaporized material. This was done in evaporation by Hibi (1952), who positioned a tube between the source and the substrate. Collimation was also attained by H. Fuchs and H. Gleiter in their studies of the effects of atom velocity on film formation using a rotating, spiral-groove, velocity selector.

In 1983, Ney described a source that emitted a gold atom beam with a 2° divergence. Recently, “directed deposition” has been obtained using a flux of thermal evaporated material projected into a directed gas flow.

Thermally Evaporating Development

When thermally evaporating alloys, the material is vaporized with a composition in accordance with Raoult’s Law (1887). This means that the deposited film will have a continuously varying composition unless very strict conditions are met as to the volume of the molten pool using a replenishing source. One way of avoiding the problem is by “flash evaporation” of small volumes of material.

In 1948, L. Harris and B.M. Siegel reported flash evaporation by dropping small amounts of material on a very hot surface so that all of the material was vaporized before the next material arrived on the hot surface.

In 1964, Smith and Hunt described a method for depositing continuous strips of alloy foils by evaporation. Other free-standing thin-film structures are also deposited, such as beryllium Xray windows and nuclear targets.

To learn more about the history of thermal evaporation, please follow our website. We will update articles about evaporation pellets every week, so stay tuned. If you want to buy high-quality evaporating pellets, please visit our official website for coating materials at https://www.sputtertargets.net/.