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Sputtering

April 26, 2024

In physics, sputtering is a phenomenon in which microscopic particles of a solid material are ejected from its surface, after the material is itself bombarded by energetic particles of a plasma or gas.[2] It occurs naturally in outer space, and can be an unwelcome source of wear in precision components. However, the fact that it can be made to act on extremely fine layers of material is utilised in science and industry—there, it is used to perform precise etching, carry out analytical techniques, and deposit thin film layers in the manufacture of optical coatings, semiconductor devices and nanotechnology products. It is a physical vapor deposition technique.[3]

A commercial AJA Orion sputtering system at Cornell NanoScale Science and Technology Facility
Ion thruster operating on iodine (yellow) using a xenon (blue) hollow cathode. High-energy ions emitted from plasma thrusters sputter material off the surrounding test chamber, causing problems for ground testing of high-power thrusters.[1]

Physics edit

When energetic ions collide with atoms of a target material, an exchange of momentum takes place between them.[2][4][5]

 
Sputtering from a linear collision cascade. The thick line illustrates the position of the surface, with everything below it being atoms inside of the material, and the thinner lines the ballistic movement paths of the atoms from beginning until they stop in the material. The purple circle is the incoming ion. Red, blue, green and yellow circles illustrate primary, secondary, tertiary and quaternary recoils, respectively. Two of the atoms happen to move out from the sample, i.e. they are sputtered.

These ions, known as "incident ions", set off collision cascades in the target. Such cascades can take many paths; some recoil back toward the surface of the target. If a collision cascade reaches the surface of the target, and its remaining energy is greater than the target's surface binding energy, an atom will be ejected. This process is known as "sputtering". If the target is thin (on an atomic scale), the collision cascade can reach through to its back side; the atoms ejected in this fashion are said to escape the surface binding energy "in transmission".

The average number of atoms ejected from the target per incident ion is called the "sputter yield". The sputter yield depends on several things: the angle at which ions collide with the surface of the material, how much energy they strike it with, their masses, the masses of the target atoms, and the target's surface binding energy. If the target possesses a crystal structure, the orientation of its axes with respect to the surface is an important factor.

The ions that cause sputtering come from a variety of sources—they can come from plasma, specially constructed ion sources, particle accelerators, outer space (e.g. solar wind), or radioactive materials (e.g. alpha radiation).

A model for describing sputtering in the cascade regime for amorphous flat targets is Thompson's analytical model.[6] An algorithm that simulates sputtering based on a quantum mechanical treatment including electrons stripping at high energy is implemented in the program TRIM.[7]

Another mechanism of physical sputtering is called "heat spike sputtering". This can occur when the solid is dense enough, and the incoming ion heavy enough, that collisions occur very close to each other. In this case, the binary collision approximation is no longer valid, and the collisional process should be understood as a many-body process. The dense collisions induce a heat spike (also called thermal spike), which essentially melts a small portion of the crystal. If that portion is close enough to its surface, large numbers of atoms may be ejected, due to liquid flowing to the surface and/or microexplosions.[8] Heat spike sputtering is most important for heavy ions (e.g. Xe or Au or cluster ions) with energies in the keV–MeV range bombarding dense but soft metals with a low melting point (Ag, Au, Pb, etc.). The heat spike sputtering often increases nonlinearly with energy, and can for small cluster ions lead to dramatic sputtering yields per cluster of the order of 10,000.[9] For animations of such a process see "Re: Displacement Cascade 1" in the external links section.

Physical sputtering has a well-defined minimum energy threshold, equal to or larger than the ion energy at which the maximum energy transfer from the ion to a target atom equals the binding energy of a surface atom. That is to say, it can only happen when an ion is capable of transferring more energy into the target than is required for an atom to break free from its surface.

This threshold is typically somewhere in the range of ten to a hundred eV.

Preferential sputtering can occur at the start when a multicomponent solid target is bombarded and there is no solid state diffusion. If the energy transfer is more efficient to one of the target components, or it is less strongly bound to the solid, it will sputter more efficiently than the other. If in an AB alloy the component A is sputtered preferentially, the surface of the solid will, during prolonged bombardment, become enriched in the B component, thereby increasing the probability that B is sputtered such that the composition of the sputtered material will ultimately return to AB.

Electronic sputtering edit

The term electronic sputtering can mean either sputtering induced by energetic electrons (for example in a transmission electron microscope), or sputtering due to very high-energy or highly charged heavy ions that lose energy to the solid, mostly by electronic stopping power, where the electronic excitations cause sputtering.[10] Electronic sputtering produces high sputtering yields from insulators, as the electronic excitations that cause sputtering are not immediately quenched, as they would be in a conductor. One example of this is Jupiter's ice-covered moon Europa, where a MeV sulfur ion from Jupiter's magnetosphere can eject up to 10,000 H2O molecules.[11]

Potential sputtering edit

 
A commercial sputtering system

In the case of multiple charged projectile ions a particular form of electronic sputtering can take place that has been termed potential sputtering.[12][13] In these cases the potential energy stored in multiply charged ions (i.e., the energy necessary to produce an ion of this charge state from its neutral atom) is liberated when the ions recombine during impact on a solid surface (formation of hollow atoms). This sputtering process is characterized by a strong dependence of the observed sputtering yields on the charge state of the impinging ion and can already take place at ion impact energies well below the physical sputtering threshold. Potential sputtering has only been observed for certain target species[14] and requires a minimum potential energy.[15]

Etching and chemical sputtering edit

Removing atoms by sputtering with an inert gas is called ion milling or ion etching.

Sputtering can also play a role in reactive-ion etching (RIE), a plasma process carried out with chemically active ions and radicals, for which the sputtering yield may be enhanced significantly compared to pure physical sputtering. Reactive ions are frequently used in secondary ion mass spectrometry (SIMS) equipment to enhance the sputter rates. The mechanisms causing the sputtering enhancement are not always well understood, although the case of fluorine etching of Si has been modeled well theoretically.[16]

Sputtering observed to occur below the threshold energy of physical sputtering is also often called chemical sputtering.[2][5] The mechanisms behind such sputtering are not always well understood, and may be hard to distinguish from chemical etching. At elevated temperatures, chemical sputtering of carbon can be understood to be due to the incoming ions weakening bonds in the sample, which then desorb by thermal activation.[17] The hydrogen-induced sputtering of carbon-based materials observed at low temperatures has been explained by H ions entering between C-C bonds and thus breaking them, a mechanism dubbed swift chemical sputtering.[18]

Applications and phenomena edit

Sputtering only happens when the kinetic energy of the incoming particles is much higher than conventional thermal energies ( 1 eV). When done with direct current (DC sputtering), voltages of 3-5 kV are used. When done with alternating current (RF sputtering), frequencies are around the 14 MHz range.

Sputter cleaning edit

Surfaces of solids can be cleaned from contaminants by using physical sputtering in a vacuum. Sputter cleaning is often used in surface science, vacuum deposition and ion plating. In 1955 Farnsworth, Schlier, George, and Burger reported using sputter cleaning in an ultra-high-vacuum system to prepare ultra-clean surfaces for low-energy electron-diffraction (LEED) studies.[19][20][21] Sputter cleaning became an integral part of the ion plating process. When the surfaces to be cleaned are large, a similar technique, plasma cleaning, can be used. Sputter cleaning has some potential problems such as overheating, gas incorporation in the surface region, bombardment (radiation) damage in the surface region, and the roughening of the surface, particularly if over done. It is important to have a clean plasma in order to not continually recontaminate the surface during sputter cleaning. Redeposition of sputtered material on the substrate can also give problems, especially at high sputtering pressures. Sputtering of the surface of a compound or alloy material can result in the surface composition being changed. Often the species with the least mass or the highest vapor pressure is the one preferentially sputtered from the surface.

Film deposition edit

Main article: Sputter deposition

Sputter deposition is a method of depositing thin films by sputtering that involves eroding material from a "target" source onto a "substrate", e.g. a silicon wafer, solar cell, optical component, or many other possibilities.[22] Resputtering, in contrast, involves re-emission of the deposited material, e.g. SiO2 during the deposition also by ion bombardment.

Sputtered atoms are ejected into the gas phase but are not in their thermodynamic equilibrium state, and tend to deposit on all surfaces in the vacuum chamber. A substrate (such as a wafer) placed in the chamber will be coated with a thin film. Sputtering deposition usually uses an argon plasma because argon, a noble gas, will not react with the target material.

Sputter damage edit

Sputter damage is usually defined during transparent electrode deposition on optoelectronic devices, which is usually originated from the substrate's bombardment by highly energetic species. The main species involved in the process and the representative energies can be listed as (values taken from[23]):

  • Sputtered atoms (ions) from the target surface (~10 eV), the formation of which mainly depends on the binding energy of the target material;
  • Negative ions (originating from the carrier gas) formed in the plasma (~5–15 eV), the formation of which mainly depends on the plasma potential;
  • Negative ions formed at the target surface (up to 400 eV), the formation of which mainly depends on the target voltage;
  • Positive ions formed in the plasma (~15 eV), the formation of which mainly depends on the potential fall in front of a substrate at floating potential;
  • Reflected atoms and neutralized ions from the target surface (20–50 eV), the formation of which mainly depends on the background gas and the mass of the sputtered element.

As seen in the list above, negative ions (e.g., O and In for ITO sputtering) formed at the target surface and accelerated toward the substrate acquire the largest energy, which is determined by the potential between target and plasma potentials. Although the flux of the energetic particles is an important parameter, high-energy negative O ions are additionally the most abundant species in plasma in case of reactive deposition of oxides. However, energies of other ions/atoms (e.g., Ar+, Ar0, or In0) in the discharge may already be sufficient to dissociate surface bonds or etch soft layers in certain device technologies. In addition, the momentum transfer of high-energy particles from the plasma (Ar, oxygen ions) or sputtered from the target might impinge or even increase the substrate temperature sufficiently to trigger physical (e.g., etching) or thermal degradation of sensitive substrate layers (e.g. thin film metal halide perovskites).

This can affect the functional properties of underlying charge transport and passivation layers and photoactive absorbers or emitters, eroding device performance. For instance, due to sputter damage, there may be inevitable interfacial consequences such as pinning of the Fermi level, caused by damage-related interface gap states, resulting in the formation of Schottky-barrier impeding carrier transport. Sputter damage can also impair the doping efficiency of materials and the lifetime of excess charge carriers in photoactive materials; in some cases, depending on its extent, such damage can even lead to a reduced shunt resistance.[23]

Etching edit

In the semiconductor industry sputtering is used to etch the target. Sputter etching is chosen in cases where a high degree of etching anisotropy is needed and selectivity is not a concern. One major drawback of this technique is wafer damage and high voltage use.

For analysis edit

Another application of sputtering is to etch away the target material. One such example occurs in secondary ion mass spectrometry (SIMS), where the target sample is sputtered at a constant rate. As the target is sputtered, the concentration and identity of sputtered atoms are measured using mass spectrometry. In this way the composition of the target material can be determined and even extremely low concentrations (20 µg/kg) of impurities detected. Furthermore, because the sputtering continually etches deeper into the sample, concentration profiles as a function of depth can be measured.

In space edit

Sputtering is one of the forms of space weathering, a process that changes the physical and chemical properties of airless bodies, such as asteroids and the Moon. On icy moons, especially Europa, sputtering of photolyzed water from the surface leads to net loss of hydrogen and accumulation of oxygen-rich materials that may be important for life. Sputtering is also one of the possible ways that Mars has lost most of its atmosphere and that Mercury continually replenishes its tenuous surface-bounded exosphere.

References edit

  1. ^ Lobbia, R.B.; Polk, J.E.; Hofer, R.R.; Chaplin, V.H; Jorns, B. (2019-08-19). "Accelerating 23,000 hours of ground test backsputtered carbon on a magnetically shielded Hall thruster". AIAA Propulsion and Energy 2019 Forum. doi:10.2514/6.2019-3898.
  2. ^ a b c R. Behrisch, ed. (1981). Sputtering by Particle bombardment. Springer, Berlin. ISBN 978-3-540-10521-3.
  3. ^ "What is DC Sputtering?". 26 November 2016.
  4. ^ P. Sigmund, Nucl. Instrum. Methods Phys. Res. B (1987). "Mechanisms and theory of physical sputtering by particle impact". Nuclear Instruments and Methods in Physics Research Section B. 27 (1): 1–20. Bibcode:1987NIMPB..27....1S. doi:10.1016/0168-583X(87)90004-8.
  5. ^ a b R. Behrisch and W. Eckstein (eds.) (2007). Sputtering by Particle bombardment: Experiments and Computer Calculations from Threshold to Mev Energies. Springer, Berlin. {{cite book}}: |author= has generic name (help)
  6. ^ M.W. Thompson (1962). "Energy spectrum of ejected atoms during the high- energy sputtering of gold". Phil. Mag. 18 (152): 377. Bibcode:1968PMag...18..377T. doi:10.1080/14786436808227358.
  7. ^ J. F. Ziegler, J. P, Biersack, U. Littmark (1984). The Stopping and Range of Ions in Solids," vol. 1 of series Stopping and Ranges of Ions in Matter. Pergamon Press, New York. ISBN 978-0-08-021603-4.{{cite book}}: CS1 maint: multiple names: authors list (link)
  8. ^ Mai Ghaly & R. S. Averback (1994). "Effect of viscous flow on ion damage near solid surfaces". Physical Review Letters. 72 (3): 364–367. Bibcode:1994PhRvL..72..364G. doi:10.1103/PhysRevLett.72.364. PMID 10056412.
  9. ^ S. Bouneau; A. Brunelle; S. Della-Negra; J. Depauw; D. Jacquet; Y. L. Beyec; M. Pautrat; M. Fallavier; J. C. Poizat & H. H. Andersen (2002). "Very large gold and silver sputtering yields induced by keV to MeV energy Aun clusters (n=1–13)". Phys. Rev. B. 65 (14): 144106. Bibcode:2002PhRvB..65n4106B. doi:10.1103/PhysRevB.65.144106. S2CID 120941773.
  10. ^ T. Schenkel; Briere, M.; Schmidt-Böcking, H.; Bethge, K.; Schneider, D.; et al. (1997). "Electronic Sputtering of Thin Conductors by Neutralization of Slow Highly Charged Ions". Physical Review Letters. 78 (12): 2481. Bibcode:1997PhRvL..78.2481S. doi:10.1103/PhysRevLett.78.2481. S2CID 56361399.
  11. ^ Johnson, R. E.; Carlson, R. W.; Cooper, J. F.; Paranicas, C.; Moore, M. H.; Wong, M. C. (2004). Fran Bagenal; Timothy E. Dowling; William B. McKinnon (eds.). Radiation effects on the surfaces of the Galilean satellites. In: Jupiter. The planet, satellites and magnetosphere. Vol. 1. Cambridge, UK: Cambridge University Press. pp. 485–512. Bibcode:2004jpsm.book..485J. ISBN 0-521-81808-7.
  12. ^ T. Neidhart; Pichler, F.; Aumayr, F.; Winter, HP.; Schmid, M.; Varga, P.; et al. (1995). "Potential sputtering of lithium fluoride by slow multicharged ions". Physical Review Letters. 74 (26): 5280–5283. Bibcode:1995PhRvL..74.5280N. doi:10.1103/PhysRevLett.74.5280. PMID 10058728. S2CID 33930734.
  13. ^ M. Sporn; Libiseller, G.; Neidhart, T.; Schmid, M.; Aumayr, F.; Winter, HP.; Varga, P.; Grether, M.; Niemann, D.; Stolterfoht, N.; et al. (1997). "Potential Sputtering of Clean SiO2 by Slow Highly Charged Ions". Physical Review Letters. 79 (5): 945. Bibcode:1997PhRvL..79..945S. doi:10.1103/PhysRevLett.79.945. S2CID 59576101.
  14. ^ F. Aumayr & H. P. Winter (2004). "Potential sputtering". Philosophical Transactions of the Royal Society A. 362 (1814): 77–102. Bibcode:2004RSPTA.362...77A. doi:10.1098/rsta.2003.1300. PMID 15306277. S2CID 21891721.
  15. ^ G. Hayderer; Schmid, M.; Varga, P.; Winter, H; Aumayr, F.; Wirtz, L.; Lemell, C.; Burgdörfer, J.; Hägg, L.; Reinhold, C.; et al. (1999). "Threshold for Potential Sputtering of LiF" (PDF). Physical Review Letters. 83 (19): 3948. Bibcode:1999PhRvL..83.3948H. doi:10.1103/PhysRevLett.83.3948.
  16. ^ T. A. Schoolcraft and B. J. Garrison, Journal of the American Chemical Society (1991). "Initial stages of etching of the silicon Si110 2x1 surface by 3.0-eV normal incident fluorine atoms: a molecular dynamics study". Journal of the American Chemical Society. 113 (22): 8221. doi:10.1021/ja00022a005.
  17. ^ J. Küppers (1995). "The hydrogen surface chemistry of carbon as a plasma facing material". Surface Science Reports. 22 (7–8): 249–321. Bibcode:1995SurSR..22..249K. doi:10.1016/0167-5729(96)80002-1.
  18. ^ E. Salonen; Nordlund, K.; Keinonen, J.; Wu, C.; et al. (2001). "Swift chemical sputtering of amorphous hydrogenated carbon". Physical Review B. 63 (19): 195415. Bibcode:2001PhRvB..63s5415S. doi:10.1103/PhysRevB.63.195415. S2CID 67829382.
  19. ^ Farnsworth, H. E.; Schlier, R. E.; George, T. H.; Burger, R. M. (1955). "Ion Bombardment-Cleaning of Germanium and Titanium as Determined by Low-Energy Electron Diffraction". Journal of Applied Physics. 26 (2). AIP Publishing: 252–253. Bibcode:1955JAP....26..252F. doi:10.1063/1.1721972. ISSN 0021-8979.
  20. ^ Farnsworth, H. E.; Schlier, R. E.; George, T. H.; Burger, R. M. (1958). "Application of the Ion Bombardment Cleaning Method to Titanium, Germanium, Silicon, and Nickel as Determined by Low-Energy Electron Diffraction". Journal of Applied Physics. 29 (8). AIP Publishing: 1150–1161. Bibcode:1958JAP....29.1150F. doi:10.1063/1.1723393. ISSN 0021-8979.
  21. ^ G.S. Anderson and Roger M. Moseson, “Method and Apparatus for Cleaning by Ionic Bombardment,” U.S. Patent #3,233,137 (filed Aug. 28, 1961) (Feb.1, 1966)
  22. ^ "Sputtering Targets | Thin Films". Admat Inc. Retrieved 2018-08-28.
  23. ^ a b Aydin, Erkan; Altinkaya, Cesur; Smirnov, Yury; Yaqin, Muhammad A.; Zanoni, Kassio P. S.; Paliwal, Abhyuday; Firdaus, Yuliar; Allen, Thomas G.; Anthopoulos, Thomas D.; Bolink, Henk J.; Morales-Masis, Monica (2021-11-03). "Sputtered transparent electrodes for optoelectronic devices: Induced damage and mitigation strategies". Matter. 4 (11): 3549–3584. doi:10.1016/j.matt.2021.09.021. hdl:10754/673293. ISSN 2590-2393. S2CID 243469180.

External links edit

 
Wikimedia Commons has media related to Sputtering.
  • Thin Film Evaporation Guide
  • What is Sputtering? - an introduction with animations
  • Sputtering Basics - animated film of a sputtering process
  • Free molecular dynamics simulation program (Kalypso) capable of modeling sputtering 2010-05-20 at the Wayback Machine
  • American Vacuum Society short courses 2006-04-11 at the Wayback Machine on thin film deposition
  • H. R. Kaufman, J. J. Cuomo and J. M. E. Harper (1982). "Technology and applications of broad-beam ion sources used in sputtering. Part I. Ion source technology". Journal of Vacuum Science and Technology. 21 (3): 725–736. Bibcode:1982JVST...21..725K. doi:10.1116/1.571819.(The original paper on Kaufman sputter sources.)
  • Re: Displacement Cascade 1. YouTube. 2008. Archived from the original on 2021-12-11.

April 26, 2024
sputtering, physics, sputtering, phenomenon, which, microscopic, particles, solid, material, ejected, from, surface, after, material, itself, bombarded, energetic, particles, plasma, occurs, naturally, outer, space, unwelcome, source, wear, precision, componen. In physics sputtering is a phenomenon in which microscopic particles of a solid material are ejected from its surface after the material is itself bombarded by energetic particles of a plasma or gas 2 It occurs naturally in outer space and can be an unwelcome source of wear in precision components However the fact that it can be made to act on extremely fine layers of material is utilised in science and industry there it is used to perform precise etching carry out analytical techniques and deposit thin film layers in the manufacture of optical coatings semiconductor devices and nanotechnology products It is a physical vapor deposition technique 3 A commercial AJA Orion sputtering system at Cornell NanoScale Science and Technology Facility Ion thruster operating on iodine yellow using a xenon blue hollow cathode High energy ions emitted from plasma thrusters sputter material off the surrounding test chamber causing problems for ground testing of high power thrusters 1 Contents 1 Physics 2 Electronic sputtering 3 Potential sputtering 4 Etching and chemical sputtering 5 Applications and phenomena 5 1 Sputter cleaning 5 2 Film deposition 5 3 Sputter damage 5 4 Etching 5 5 For analysis 5 6 In space 6 References 7 External linksPhysics editWhen energetic ions collide with atoms of a target material an exchange of momentum takes place between them 2 4 5 nbsp Sputtering from a linear collision cascade The thick line illustrates the position of the surface with everything below it being atoms inside of the material and the thinner lines the ballistic movement paths of the atoms from beginning until they stop in the material The purple circle is the incoming ion Red blue green and yellow circles illustrate primary secondary tertiary and quaternary recoils respectively Two of the atoms happen to move out from the sample i e they are sputtered These ions known as incident ions set off collision cascades in the target Such cascades can take many paths some recoil back toward the surface of the target If a collision cascade reaches the surface of the target and its remaining energy is greater than the target s surface binding energy an atom will be ejected This process is known as sputtering If the target is thin on an atomic scale the collision cascade can reach through to its back side the atoms ejected in this fashion are said to escape the surface binding energy in transmission The average number of atoms ejected from the target per incident ion is called the sputter yield The sputter yield depends on several things the angle at which ions collide with the surface of the material how much energy they strike it with their masses the masses of the target atoms and the target s surface binding energy If the target possesses a crystal structure the orientation of its axes with respect to the surface is an important factor The ions that cause sputtering come from a variety of sources they can come from plasma specially constructed ion sources particle accelerators outer space e g solar wind or radioactive materials e g alpha radiation A model for describing sputtering in the cascade regime for amorphous flat targets is Thompson s analytical model 6 An algorithm that simulates sputtering based on a quantum mechanical treatment including electrons stripping at high energy is implemented in the program TRIM 7 Another mechanism of physical sputtering is called heat spike sputtering This can occur when the solid is dense enough and the incoming ion heavy enough that collisions occur very close to each other In this case the binary collision approximation is no longer valid and the collisional process should be understood as a many body process The dense collisions induce a heat spike also called thermal spike which essentially melts a small portion of the crystal If that portion is close enough to its surface large numbers of atoms may be ejected due to liquid flowing to the surface and or microexplosions 8 Heat spike sputtering is most important for heavy ions e g Xe or Au or cluster ions with energies in the keV MeV range bombarding dense but soft metals with a low melting point Ag Au Pb etc The heat spike sputtering often increases nonlinearly with energy and can for small cluster ions lead to dramatic sputtering yields per cluster of the order of 10 000 9 For animations of such a process see Re Displacement Cascade 1 in the external links section Physical sputtering has a well defined minimum energy threshold equal to or larger than the ion energy at which the maximum energy transfer from the ion to a target atom equals the binding energy of a surface atom That is to say it can only happen when an ion is capable of transferring more energy into the target than is required for an atom to break free from its surface This threshold is typically somewhere in the range of ten to a hundred eV Preferential sputtering can occur at the start when a multicomponent solid target is bombarded and there is no solid state diffusion If the energy transfer is more efficient to one of the target components or it is less strongly bound to the solid it will sputter more efficiently than the other If in an AB alloy the component A is sputtered preferentially the surface of the solid will during prolonged bombardment become enriched in the B component thereby increasing the probability that B is sputtered such that the composition of the sputtered material will ultimately return to AB Electronic sputtering editThe term electronic sputtering can mean either sputtering induced by energetic electrons for example in a transmission electron microscope or sputtering due to very high energy or highly charged heavy ions that lose energy to the solid mostly by electronic stopping power where the electronic excitations cause sputtering 10 Electronic sputtering produces high sputtering yields from insulators as the electronic excitations that cause sputtering are not immediately quenched as they would be in a conductor One example of this is Jupiter s ice covered moon Europa where a MeV sulfur ion from Jupiter s magnetosphere can eject up to 10 000 H2O molecules 11 Potential sputtering edit nbsp A commercial sputtering system In the case of multiple charged projectile ions a particular form of electronic sputtering can take place that has been termed potential sputtering 12 13 In these cases the potential energy stored in multiply charged ions i e the energy necessary to produce an ion of this charge state from its neutral atom is liberated when the ions recombine during impact on a solid surface formation of hollow atoms This sputtering process is characterized by a strong dependence of the observed sputtering yields on the charge state of the impinging ion and can already take place at ion impact energies well below the physical sputtering threshold Potential sputtering has only been observed for certain target species 14 and requires a minimum potential energy 15 Etching and chemical sputtering editRemoving atoms by sputtering with an inert gas is called ion milling or ion etching Sputtering can also play a role in reactive ion etching RIE a plasma process carried out with chemically active ions and radicals for which the sputtering yield may be enhanced significantly compared to pure physical sputtering Reactive ions are frequently used in secondary ion mass spectrometry SIMS equipment to enhance the sputter rates The mechanisms causing the sputtering enhancement are not always well understood although the case of fluorine etching of Si has been modeled well theoretically 16 Sputtering observed to occur below the threshold energy of physical sputtering is also often called chemical sputtering 2 5 The mechanisms behind such sputtering are not always well understood and may be hard to distinguish from chemical etching At elevated temperatures chemical sputtering of carbon can be understood to be due to the incoming ions weakening bonds in the sample which then desorb by thermal activation 17 The hydrogen induced sputtering of carbon based materials observed at low temperatures has been explained by H ions entering between C C bonds and thus breaking them a mechanism dubbed swift chemical sputtering 18 Applications and phenomena editSputtering only happens when the kinetic energy of the incoming particles is much higher than conventional thermal energies 1 eV When done with direct current DC sputtering voltages of 3 5 kV are used When done with alternating current RF sputtering frequencies are around the 14 MHz range Sputter cleaning edit Surfaces of solids can be cleaned from contaminants by using physical sputtering in a vacuum Sputter cleaning is often used in surface science vacuum deposition and ion plating In 1955 Farnsworth Schlier George and Burger reported using sputter cleaning in an ultra high vacuum system to prepare ultra clean surfaces for low energy electron diffraction LEED studies 19 20 21 Sputter cleaning became an integral part of the ion plating process When the surfaces to be cleaned are large a similar technique plasma cleaning can be used Sputter cleaning has some potential problems such as overheating gas incorporation in the surface region bombardment radiation damage in the surface region and the roughening of the surface particularly if over done It is important to have a clean plasma in order to not continually recontaminate the surface during sputter cleaning Redeposition of sputtered material on the substrate can also give problems especially at high sputtering pressures Sputtering of the surface of a compound or alloy material can result in the surface composition being changed Often the species with the least mass or the highest vapor pressure is the one preferentially sputtered from the surface Film deposition edit Main article Sputter deposition Sputter deposition is a method of depositing thin films by sputtering that involves eroding material from a target source onto a substrate e g a silicon wafer solar cell optical component or many other possibilities 22 Resputtering in contrast involves re emission of the deposited material e g SiO2 during the deposition also by ion bombardment Sputtered atoms are ejected into the gas phase but are not in their thermodynamic equilibrium state and tend to deposit on all surfaces in the vacuum chamber A substrate such as a wafer placed in the chamber will be coated with a thin film Sputtering deposition usually uses an argon plasma because argon a noble gas will not react with the target material Sputter damage edit Sputter damage is usually defined during transparent electrode deposition on optoelectronic devices which is usually originated from the substrate s bombardment by highly energetic species The main species involved in the process and the representative energies can be listed as values taken from 23 Sputtered atoms ions from the target surface 10 eV the formation of which mainly depends on the binding energy of the target material Negative ions originating from the carrier gas formed in the plasma 5 15 eV the formation of which mainly depends on the plasma potential Negative ions formed at the target surface up to 400 eV the formation of which mainly depends on the target voltage Positive ions formed in the plasma 15 eV the formation of which mainly depends on the potential fall in front of a substrate at floating potential Reflected atoms and neutralized ions from the target surface 20 50 eV the formation of which mainly depends on the background gas and the mass of the sputtered element As seen in the list above negative ions e g O and In for ITO sputtering formed at the target surface and accelerated toward the substrate acquire the largest energy which is determined by the potential between target and plasma potentials Although the flux of the energetic particles is an important parameter high energy negative O ions are additionally the most abundant species in plasma in case of reactive deposition of oxides However energies of other ions atoms e g Ar Ar0 or In0 in the discharge may already be sufficient to dissociate surface bonds or etch soft layers in certain device technologies In addition the momentum transfer of high energy particles from the plasma Ar oxygen ions or sputtered from the target might impinge or even increase the substrate temperature sufficiently to trigger physical e g etching or thermal degradation of sensitive substrate layers e g thin film metal halide perovskites This can affect the functional properties of underlying charge transport and passivation layers and photoactive absorbers or emitters eroding device performance For instance due to sputter damage there may be inevitable interfacial consequences such as pinning of the Fermi level caused by damage related interface gap states resulting in the formation of Schottky barrier impeding carrier transport Sputter damage can also impair the doping efficiency of materials and the lifetime of excess charge carriers in photoactive materials in some cases depending on its extent such damage can even lead to a reduced shunt resistance 23 Etching edit In the semiconductor industry sputtering is used to etch the target Sputter etching is chosen in cases where a high degree of etching anisotropy is needed and selectivity is not a concern One major drawback of this technique is wafer damage and high voltage use For analysis edit Another application of sputtering is to etch away the target material One such example occurs in secondary ion mass spectrometry SIMS where the target sample is sputtered at a constant rate As the target is sputtered the concentration and identity of sputtered atoms are measured using mass spectrometry In this way the composition of the target material can be determined and even extremely low concentrations 20 µg kg of impurities detected Furthermore because the sputtering continually etches deeper into the sample concentration profiles as a function of depth can be measured In space edit Sputtering is one of the forms of space weathering a process that changes the physical and chemical properties of airless bodies such as asteroids and the Moon On icy moons especially Europa sputtering of photolyzed water from the surface leads to net loss of hydrogen and accumulation of oxygen rich materials that may be important for life Sputtering is also one of the possible ways that Mars has lost most of its atmosphere and that Mercury continually replenishes its tenuous surface bounded exosphere References edit Lobbia R B Polk J E Hofer R R Chaplin V H Jorns B 2019 08 19 Accelerating 23 000 hours of ground test backsputtered carbon on a magnetically shielded Hall thruster AIAA Propulsion and Energy 2019 Forum doi 10 2514 6 2019 3898 a b c R Behrisch ed 1981 Sputtering by Particle bombardment Springer Berlin ISBN 978 3 540 10521 3 What is DC Sputtering 26 November 2016 P Sigmund Nucl Instrum Methods Phys Res B 1987 Mechanisms and theory of physical sputtering by particle impact Nuclear Instruments and Methods in Physics Research Section B 27 1 1 20 Bibcode 1987NIMPB 27 1S doi 10 1016 0168 583X 87 90004 8 a b R Behrisch and W Eckstein eds 2007 Sputtering by Particle bombardment Experiments and Computer Calculations from Threshold to Mev Energies Springer Berlin a href Template Cite book html title Template Cite book cite book a author has generic name help M W Thompson 1962 Energy spectrum of ejected atoms during the high energy sputtering of gold Phil Mag 18 152 377 Bibcode 1968PMag 18 377T doi 10 1080 14786436808227358 J F Ziegler J P Biersack U Littmark 1984 The Stopping and Range of Ions in Solids vol 1 of series Stopping and Ranges of Ions in Matter Pergamon Press New York ISBN 978 0 08 021603 4 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Mai Ghaly amp R S Averback 1994 Effect of viscous flow on ion damage near solid surfaces Physical Review Letters 72 3 364 367 Bibcode 1994PhRvL 72 364G doi 10 1103 PhysRevLett 72 364 PMID 10056412 S Bouneau A Brunelle S Della Negra J Depauw D Jacquet Y L Beyec M Pautrat M Fallavier J C Poizat amp H H Andersen 2002 Very large gold and silver sputtering yields induced by keV to MeV energy Aun clusters n 1 13 Phys Rev B 65 14 144106 Bibcode 2002PhRvB 65n4106B doi 10 1103 PhysRevB 65 144106 S2CID 120941773 T Schenkel Briere M Schmidt Bocking H Bethge K Schneider D et al 1997 Electronic Sputtering of Thin Conductors by Neutralization of Slow Highly Charged Ions Physical Review Letters 78 12 2481 Bibcode 1997PhRvL 78 2481S doi 10 1103 PhysRevLett 78 2481 S2CID 56361399 Johnson R E Carlson R W Cooper J F Paranicas C Moore M H Wong M C 2004 Fran Bagenal Timothy E Dowling William B McKinnon eds Radiation effects on the surfaces of the Galilean satellites In Jupiter The planet satellites and magnetosphere Vol 1 Cambridge UK Cambridge University Press pp 485 512 Bibcode 2004jpsm book 485J ISBN 0 521 81808 7 T Neidhart Pichler F Aumayr F Winter HP Schmid M Varga P et al 1995 Potential sputtering of lithium fluoride by slow multicharged ions Physical Review Letters 74 26 5280 5283 Bibcode 1995PhRvL 74 5280N doi 10 1103 PhysRevLett 74 5280 PMID 10058728 S2CID 33930734 M Sporn Libiseller G Neidhart T Schmid M Aumayr F Winter HP Varga P Grether M Niemann D Stolterfoht N et al 1997 Potential Sputtering of Clean SiO2 by Slow Highly Charged Ions Physical Review Letters 79 5 945 Bibcode 1997PhRvL 79 945S doi 10 1103 PhysRevLett 79 945 S2CID 59576101 F Aumayr amp H P Winter 2004 Potential sputtering Philosophical Transactions of the Royal Society A 362 1814 77 102 Bibcode 2004RSPTA 362 77A doi 10 1098 rsta 2003 1300 PMID 15306277 S2CID 21891721 G Hayderer Schmid M Varga P Winter H Aumayr F Wirtz L Lemell C Burgdorfer J Hagg L Reinhold C et al 1999 Threshold for Potential Sputtering of LiF PDF Physical Review Letters 83 19 3948 Bibcode 1999PhRvL 83 3948H doi 10 1103 PhysRevLett 83 3948 T A Schoolcraft and B J Garrison Journal of the American Chemical Society 1991 Initial stages of etching of the silicon Si110 2x1 surface by 3 0 eV normal incident fluorine atoms a molecular dynamics study Journal of the American Chemical Society 113 22 8221 doi 10 1021 ja00022a005 J Kuppers 1995 The hydrogen surface chemistry of carbon as a plasma facing material Surface Science Reports 22 7 8 249 321 Bibcode 1995SurSR 22 249K doi 10 1016 0167 5729 96 80002 1 E Salonen Nordlund K Keinonen J Wu C et al 2001 Swift chemical sputtering of amorphous hydrogenated carbon Physical Review B 63 19 195415 Bibcode 2001PhRvB 63s5415S doi 10 1103 PhysRevB 63 195415 S2CID 67829382 Farnsworth H E Schlier R E George T H Burger R M 1955 Ion Bombardment Cleaning of Germanium and Titanium as Determined by Low Energy Electron Diffraction Journal of Applied Physics 26 2 AIP Publishing 252 253 Bibcode 1955JAP 26 252F doi 10 1063 1 1721972 ISSN 0021 8979 Farnsworth H E Schlier R E George T H Burger R M 1958 Application of the Ion Bombardment Cleaning Method to Titanium Germanium Silicon and Nickel as Determined by Low Energy Electron Diffraction Journal of Applied Physics 29 8 AIP Publishing 1150 1161 Bibcode 1958JAP 29 1150F doi 10 1063 1 1723393 ISSN 0021 8979 G S Anderson and Roger M Moseson Method and Apparatus for Cleaning by Ionic Bombardment U S Patent 3 233 137 filed Aug 28 1961 Feb 1 1966 Sputtering Targets Thin Films Admat Inc Retrieved 2018 08 28 a b Aydin Erkan Altinkaya Cesur Smirnov Yury Yaqin Muhammad A Zanoni Kassio P S Paliwal Abhyuday Firdaus Yuliar Allen Thomas G Anthopoulos Thomas D Bolink Henk J Morales Masis Monica 2021 11 03 Sputtered transparent electrodes for optoelectronic devices Induced damage and mitigation strategies Matter 4 11 3549 3584 doi 10 1016 j matt 2021 09 021 hdl 10754 673293 ISSN 2590 2393 S2CID 243469180 External links edit nbsp Wikimedia Commons has media related to Sputtering Thin Film Evaporation Guide What is Sputtering an introduction with animations Sputtering Basics animated film of a sputtering process Free molecular dynamics simulation program Kalypso capable of modeling sputtering Archived 2010 05 20 at the Wayback Machine American Vacuum Society short courses Archived 2006 04 11 at the Wayback Machine on thin film deposition H R Kaufman J J Cuomo and J M E Harper 1982 Technology and applications of broad beam ion sources used in sputtering Part I Ion source technology Journal of Vacuum Science and Technology 21 3 725 736 Bibcode 1982JVST 21 725K doi 10 1116 1 571819 The original paper on Kaufman sputter sources Re Displacement Cascade 1 YouTube 2008 Archived from the original on 2021 12 11 Retrieved from https en wikipedia org w index php title Sputtering amp oldid 1203863308, wikipedia, wiki, book, books, library,

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