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Ion track

March 15, 2024

Ion tracks are damage-trails created by swift heavy ions penetrating through solids, which may be sufficiently-contiguous for chemical etching in a variety of crystalline, glassy, and/or polymeric solids.[1][2] They are associated with cylindrical damage-regions several nanometers in diameter[3][4] and can be studied by Rutherford backscattering spectrometry (RBS), transmission electron microscopy (TEM), small-angle neutron scattering (SANS), small-angle X-ray scattering (SAXS) or gas permeation.[5]

Strain-fields (bright) around ion-track cores in FeCr2O4

Ion track technology edit

Ion track technology deals with the production and application of ion tracks in microtechnology and nanotechnology.[6] Ion tracks can be selectively etched in many insulating solids, leading to cones or cylinders, down to 8 nanometers in diameter.[7] Etched track cylinders can be used as filters,[8][9] Coulter counter microchannels,[10] be modified with monolayers,[11] or be filled by electroplating.[12][13]

Ion track technology has been developed to fill certain niche areas where conventional nanolithography fails, including:

  • Direct shaping of radiation-resistant minerals, glasses and polymers[2]
  • Generation of elongated structures with a resolution limit down to 8 nanometers[7]
  • Direct generation of holes in thin films without any development process[14]
  • Defining structural depth by ion range rather than by target thickness[15][16]
  • Generating structures with aspect ratio (depth divided by width) up to 104.[2]
  • Shaping rigid and flexible materials at a defined cutting angle[17]
  • Exploring the realm of aligned textures with defined inclination angles[18]
  • Generation of random patterns consisting of partially overlapping single tracks[19]
  • Generation of large numbers of individual single track structures[20]
  • Generation of aimed patterns consisting of individual single tracks[21]

Materials susceptible to ion track recording edit

The class of ion track recording materials is characterized by the following properties:[2]

Irradiation apparatus and methods edit

Several types of swift heavy ion generators and irradiation schemes are currently used:

Alpha and fission sources[22][23] provide low intensity beams with broad angular-, mass-, and energy distribution. The range of the emitted fission fragments is limited to about 15 micrometers in polymers. Weak californium-252 or americium-241 sources[24] are used for scientific and technological explorations. They are compact, inexpensive, and can be handled safely.
 
Irradiation using radionuclide
Nuclear reactors provide fission fragments with broad angular-, mass-, and energy distributions. Similar to alpha and fission sources, the penetration range of the emitted fission fragments is limited to about 15 micrometers in polymers. Nuclear reactors are used for filter production.
 
Irradiation at nuclear reactor
Heavy ion particle accelerators provide parallel-beam irradiations at high luminosity with ions of defined mass, energy, and tilt angle.[25][26][27] Intensities are available in wide ranges, even up to billions of ions per second. Depending on the available energy, track lengths between a few and several hundred micrometers can be produced. Accelerators are used in micro- and nanotechnology. Radioactive contamination is absent at ion energies below the Coulomb barrier.[28]
 
Irradiation at ion accelerator
Single ion irradiations are used to fabricate individual micro- and nanostructures such as cones, channels, pins and wires.[20] The technique requires a weak ion beam which can be switched off after one ion has penetrated the target foil.
 
Single ion system
Ion microbeams offer the highest level of control of the irradiation process. These restrict the output of a heavy ion accelerator to a small filament which can be scanned over the sample surface. Scribing with individual swift heavy ions is possible with an aiming precision of about one micrometer.[21]
 
Ion microbeam system

Formation of ion tracks edit

When a swift heavy ion penetrates through a solid, it leaves behind a trace of irregular and modified material confined to a cylinder of few nanometers in diameter. The energy transfer between the heavy projectile ion and the light target electrons occurs in binary collisions. The knocked-off primary electrons leave a charged region behind, inducing a secondary electron collision cascade involving an increasing number of electrons of decreasing energy. This electron collision cascade stops when ionization is no longer possible. The remaining energy leads to atomic excitation and vibration, producing (heat). Due to the large proton-to-electron mass ratio, the energy of the projectile decreases gradually and the projectile path is straight.[29] A small fraction of the transferred energy remains as an ion track in the solid. The diameter of the ion track increases with increasing radiation sensitivity of the material. Several models are used to describe ion track formation.

  • According to the ion explosion spike model[30] the primary ionization induces an atomic collision cascade,[31] resulting in a disordered zone around the ion trajectory.
  • According to the electron collision cascade model the secondary electrons induce a radiation effect in the material, similar to a spatially-confined electron irradiation.[32] The electron collision cascade model is particularly suited for polymers.
  • According to the thermal spike model, the electron collision cascade is responsible for the energy transfer between the projectile ion and the target nuclei. If the temperature exceeds the melting temperature of the target substance, a liquid is formed. The rapid quenching leaves behind an amorphous state with decreased density. Its disorder corresponds to the ion track.[3][33]

The thermal spike model suggests the radiation sensitivity of different materials depends on their thermal conductivity and their melting temperature.

  •  
    Thermal spike model
    Ion track corresponds to frozen disorder after rapid quenching of melt zone around ion trajectory. Temperature represented by color. Ion path vertical to image plane.
  •  
    Latent ion track in muscovite mica. Depending on the stopping power of the projectile ion the track width is between 4 and 10 nanometer.
  •  
    Molecular dynamics simulation of collision cascade in gold.
  •  
    Track etch threshold: energy input required for selective etching. For ionic crystals, the threshold increases with the heat conductivity. Amorphous metal FeBSiC included for comparison.

Etching methods edit

Selective ion etching edit

Selective ion track etching[2] is closely related to the selective etching of grain boundaries and crystal dislocations. The etch process must be sufficiently slow to discriminate between the irradiated and the pristine material. The resulting shape depends on the type of material, the concentration of the etchant, and the temperature of the etch bath. In crystals and glasses, selective etching is due to the reduced density of the ion track. In polymers, selective etching is due to polymer fragmentation in the ion track core. The core zone is surrounded by a track halo in which cross-linking can impede track etching. After removal of the cross-linked track halo, the track radius grows linear in time. The result of selective etching is a trough, pore, or channel.

Surfactant enhanced etching edit

Surfactant enhanced etching is used to modify ion track shapes.[34] It is based on self-organized monolayers.[11] The monolayers are semi-permeable for the solvated ions of the etch medium and reduce surface attack. Depending on the relative concentration of the surfactant and the etch medium, barrel or cylindrical shaped ion track pores are obtained. The technique can be used to increase the aspect ratio.[35]

Other related terminology edit

Repeated irradiation and processing: A two-step irradiation and etching process used to create perforated wells.

Arbitrary irradiation angles enforce an anisotropy along one specific symmetry axis.

Multiangular channels are interpenetrating networks consisting of two or more channel arrays in different directions.

  •  
    Double sided etching of ion track at track etch ratio 5:1.
  •  
    Asymmetric ion track channels with strongly reduced top diameter.
  •  
    Microwells with perforated bottom.
  •  
    Two membranes with different channel inclination (vertical and 45 degrees).
  •  
    Three membranes perforated at two strutting angles (±10, ±20, ±45 degrees).
Track etching of common polymers[36]
Material pH Wet etchant Sensitizer1) Desensitizer2) T/°C3) Speed4) Selectivity5)
PC basic NaOH UV Alcohols 50-80 Fast 100-10000
PET basic NaOH UV, DMF Alcohols 50-90 Fast 10-1000
basic K2CO3 80 Slow 1000
PI basic NaOCl NaOH 50-80 Fast 100-1000
CR39 basic NaOH UV 50-80 Fast 10-1000
PVDF6) basic KMnO4 + NaOH 80 Medium 10-100
PMMA6) acidic KMnO4 + H2SO4 50-80 Medium 10
PP6) acidic CrO3 + H2SO4 80 Fast 10-100

1) Sensitizers increase the track etch ratio by breaking bonds or by increasing the free volume.
2) Desensitizers decrease the track etch ratio. Alternatively ion tracks can be thermally annealed.
3) Typical etch bath temperature range. Etch rates increase strongly with concentration and temperature.
4) Axial etching depends on track etch speed vt, radial etching depends on general etch speed vg.
5) Selectivity (aspect ratio, track etch ratio) = track etch speed / general etch speed = vt / vg.
6) This method requires to remove remaining metal oxide deposits by aqueous HCl solutions.

Replication edit

Etched ion tracks can be replicated by polymers[37] or metals.[12][38] Replica and template can be used as composite. A replica can be separated from its template mechanically or chemically. Polymer replicas are obtained by filling the etched track with a liquid precursor of the polymer and curing it. Curing can be activated by a catalyst, by ultraviolet radiation, or by heat. Metal replicas can be obtained either by electroless deposition or by electro-deposition. For replication of through-pores, a cathode film is deposited on one side of the membrane, and the membrane is immersed in a metal salt solution. The cathode film is negatively charged with respect to the anode, which is placed on the opposite side of the membrane. The positive metal ions are pulled toward the cathode, where they catch electrons and precipitate as a compact metal film. During electro-deposition, the channels fill gradually with metal, and the lengths of the nano-wires are controlled by the deposition time. Rapid deposition leads to polycrystalline wires, while slow deposition leads to single crystalline wires. A free-standing replica is obtained by removing the template after deposition of a bearing film on the anode side of the membrane.

Interpenetrating wire networks are fabricated by electro-deposition in multi-angle, track-etched membranes. Free-standing three-dimensional networks with tunable complexity and interwire connectivity are obtained.[39]

Segmented nanowires are fabricated by alternating the polarity during electro-deposition.[40] The segment length is adjusted by the pulse duration. In this way electrical, thermal, and optical properties can be tuned.

  •  
    Free standing metal replica of etched ion tracks in PC
  •  
    Interpenetrating wire network
  •  
    Bundle of segmented platinum nanowires

Applications edit

Microtechnology: The common mechanical tools of the macroworld are being supplemented and complemented, and in some applications replaced by, particle beams. Here, beams of photons and electrons modify the solubility of radiation-sensitive polymers, so-called "resists", while masking protects a selected area from exposure to radiation, chemical attack, and erosion by atomic impact. Typical products produced in this way are integrated circuits and microsystems. At present, the field of microtechnology is expanding toward nanotechnology. A recent branch of microfabrication is based on manipulation of individual ions.

Geology: Ion tracks are useful as they can remain unaltered for millions of years In minerals. Their density yields information about the time when the mineral solidified from its melt, and are used as geological clocks in fission track dating

Filters: Homoporous filters were among the first applications[8] of ion track technology, and are now fabricated by several companies.[41] Mica membranes with ion track pores were used by Beck and Schultz to determine the mechanism of hindered diffusion in nanopores.[42][43]

Classifying micro- and nanoparticles: The resistance of a channel filled by an electrolyte depends on the volume of the particle passing through it.[10] This technique is applied to the counting and sizing of individual red blood cells, bacteria, and virus particles.

pH Sensor: Charged channels filled with an electrolyte have a surface conductivity, in addition to the regular volume conductivity, of the electrolyte. Ions attached to a charged surface attract a cloud of mobile counterions. Fixed and mobile ions form a double layer. For small channels, surface conductivity is responsible for most of the charge transport. For small channels, surface conductivity exceeds volume conductivity. Negative surface charges can be occupied by firmly bound protons. At low pH (high proton concentration), the wall charge is completely neutralized. Surface conductivity vanishes. Due to the dependence of surface conductivity on pH, the channel becomes a pH sensor.[44]

Current rectifying pores: Asymmetric pores are obtained by one-sided etching. The geometric asymmetry translates into a conduction asymmetry. The phenomenon is similar to an electrical valve. The pore has two characteristic conduction states, open and closed. Above a certain voltage the valve opens. Below a certain voltage the valve closes.[45][46]

Thermo-responsive channel: Obtained by lining a channel with a thermo-responsive gel.[47]

Bio-sensor: Chemical modification of the channel wall changes its interaction with passing particles. Different wall claddings bind to specific molecules and delay their passage. In this sense, the wall recognizes the passing particle. As an example, DNA fragments are selectively bound by their complementary fragments. The attached molecules reduce the channel volume. The induced resistance change reflects the molecule's concentration.[48]

Anisotropic conduction: A platform covered with many free standing wires acts as large area field emitter.[49]

Magnetic multilayers: Nano-wires consisting of alternating magnetic/nonmagnetic layers act as magnetic sensors. As an example, cobalt/copper nanowires are obtained from an electrolyte containing both metals. At low voltage, pure copper is deposited while cobalt resists electro-deposition. At high voltage, both metals are deposited as an alloy. If the electrolyte contains predominantly cobalt, a magnetic cobalt-copper alloy is deposited with a high fraction of cobalt. The electrical conductivity of the multilayer wire depends on the applied external magnetic field. The magnetic order of the cobalt layers increases with the applied field. Without magnetic field, neighboring magnetic layers prefer the anti-parallel order. With magnetic field, the magnetic layers prefer the orientation parallel with the magnetic field. The parallel orientation corresponds to a reduced electrical resistance. The effect is used in reading heads of magnetic storage media (the "GMR effect").[50]

Spintronics: Spin valve structure consists of two magnetic layers of different thicknesses. The thick layer has a higher magnetic stability and is used as polarizer. The thin layer acts as analyzer. Depending on its magnetization direction with respect to the polarizer (parallel or antiparallel), its conductivity is low or high, respectively.[51]

Textures: Tilted textures with a hydrophobic coating are at the same time superhydrophobic and anisotropic,[18] and show a preferred direction of transport. The effect has been demonstrated to convert vibration into translation.[52]

  •  
    Etched ion tracks
  •  
    Particle Transit Channel. The transient current drop is proportional to the particle volume.
  •  
    pH Sensor: The moving circle represents the cross section of a negatively charged channel. Left: At low pH all surface charges are occupied by protons (low conductivity). Right: At high pH all surface charges are available (high conductivity).
  •  
    Asymmetric pore transmits positive ions preferentially from right to left.
  •  
    Thermo-responsive channel. The hydrogel-lined channel opens above and closes below the critical temperature of the hydrogel.
  •  
    Biospecific Sensor. The electrical resistance of a channel clad with an immuno reactant depends on the concentration of a specific molecule.
  •  
    Field emitter array
  •  
    Multilayer Magnetosensor.
    Low magnetic field: antiparallel orientation and high resistance.
    High magnetic field: parallel orientation and low resistance.
  •  
    Spin Analyzer
    The energy loss of spin-polarized electrons depends on the magnetic orientation of the analyzer. Left: polarizer (blue: spin-up). Right: analyzer (blue: spin-up; red: spin-down).
  •  
    Tilted Track Texture with asymmetric transport properties.

Notes edit

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External links edit

  •   Media related to Ion track at Wikimedia Commons

March 15, 2024
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This article needs attention from an expert in Engineering The specific problem is the article was tagged for copy editing but to do so requires understanding and this article is too technical WikiProject Engineering may be able to help recruit an expert November 2012 Ion tracks are damage trails created by swift heavy ions penetrating through solids which may be sufficiently contiguous for chemical etching in a variety of crystalline glassy and or polymeric solids 1 2 They are associated with cylindrical damage regions several nanometers in diameter 3 4 and can be studied by Rutherford backscattering spectrometry RBS transmission electron microscopy TEM small angle neutron scattering SANS small angle X ray scattering SAXS or gas permeation 5 Strain fields bright around ion track cores in FeCr2O4 Contents 1 Ion track technology 2 Materials susceptible to ion track recording 3 Irradiation apparatus and methods 4 Formation of ion tracks 5 Etching methods 5 1 Selective ion etching 5 2 Surfactant enhanced etching 5 3 Other related terminology 6 Replication 7 Applications 8 Notes 9 External linksIon track technology editIon track technology deals with the production and application of ion tracks in microtechnology and nanotechnology 6 Ion tracks can be selectively etched in many insulating solids leading to cones or cylinders down to 8 nanometers in diameter 7 Etched track cylinders can be used as filters 8 9 Coulter counter microchannels 10 be modified with monolayers 11 or be filled by electroplating 12 13 Ion track technology has been developed to fill certain niche areas where conventional nanolithography fails including Direct shaping of radiation resistant minerals glasses and polymers 2 Generation of elongated structures with a resolution limit down to 8 nanometers 7 Direct generation of holes in thin films without any development process 14 Defining structural depth by ion range rather than by target thickness 15 16 Generating structures with aspect ratio depth divided by width up to 104 2 Shaping rigid and flexible materials at a defined cutting angle 17 Exploring the realm of aligned textures with defined inclination angles 18 Generation of random patterns consisting of partially overlapping single tracks 19 Generation of large numbers of individual single track structures 20 Generation of aimed patterns consisting of individual single tracks 21 Materials susceptible to ion track recording editThe class of ion track recording materials is characterized by the following properties 2 High homogeneity Local density variations of the pristine material must be small in comparison to the density deficit of the ion track core Optically translucent materials such as polycarbonate and polyvinylidene fluoride have this property Grained polymers such as polytetrafluoroethylene do not have this property High electrical resistance Non conducting dielectric minerals glasses and polymers have this property while highly conducting metals and alloys do not have this property In metals the thermal diffusivity is coupled with the electrical conductivity suppressing the formation of a thermal spike High radiation sensitivity Polymers have high radiation sensitivity as compared to glasses and ionic crystals The radiation effect in polymers is caused by the secondary electron cascade inducing both chain scission dominating in the track core and cross linking dominating in the track halo Low atomic mobility For selective ion track etching the density contrast between the latent ion track and the pristine material must be high The contrast fades due to diffusion depending on the atomic mobility Ion tracks can be annealed Erasing is faster in glasses compared to ionic crystals Irradiation apparatus and methods editSeveral types of swift heavy ion generators and irradiation schemes are currently used Alpha and fission sources 22 23 provide low intensity beams with broad angular mass and energy distribution The range of the emitted fission fragments is limited to about 15 micrometers in polymers Weak californium 252 or americium 241 sources 24 are used for scientific and technological explorations They are compact inexpensive and can be handled safely nbsp Irradiation using radionuclideNuclear reactors provide fission fragments with broad angular mass and energy distributions Similar to alpha and fission sources the penetration range of the emitted fission fragments is limited to about 15 micrometers in polymers Nuclear reactors are used for filter production nbsp Irradiation at nuclear reactorHeavy ion particle accelerators provide parallel beam irradiations at high luminosity with ions of defined mass energy and tilt angle 25 26 27 Intensities are available in wide ranges even up to billions of ions per second Depending on the available energy track lengths between a few and several hundred micrometers can be produced Accelerators are used in micro and nanotechnology Radioactive contamination is absent at ion energies below the Coulomb barrier 28 nbsp Irradiation at ion acceleratorSingle ion irradiations are used to fabricate individual micro and nanostructures such as cones channels pins and wires 20 The technique requires a weak ion beam which can be switched off after one ion has penetrated the target foil nbsp Single ion systemIon microbeams offer the highest level of control of the irradiation process These restrict the output of a heavy ion accelerator to a small filament which can be scanned over the sample surface Scribing with individual swift heavy ions is possible with an aiming precision of about one micrometer 21 nbsp Ion microbeam systemFormation of ion tracks editWhen a swift heavy ion penetrates through a solid it leaves behind a trace of irregular and modified material confined to a cylinder of few nanometers in diameter The energy transfer between the heavy projectile ion and the light target electrons occurs in binary collisions The knocked off primary electrons leave a charged region behind inducing a secondary electron collision cascade involving an increasing number of electrons of decreasing energy This electron collision cascade stops when ionization is no longer possible The remaining energy leads to atomic excitation and vibration producing heat Due to the large proton to electron mass ratio the energy of the projectile decreases gradually and the projectile path is straight 29 A small fraction of the transferred energy remains as an ion track in the solid The diameter of the ion track increases with increasing radiation sensitivity of the material Several models are used to describe ion track formation According to the ion explosion spike model 30 the primary ionization induces an atomic collision cascade 31 resulting in a disordered zone around the ion trajectory According to the electron collision cascade model the secondary electrons induce a radiation effect in the material similar to a spatially confined electron irradiation 32 The electron collision cascade model is particularly suited for polymers According to the thermal spike model the electron collision cascade is responsible for the energy transfer between the projectile ion and the target nuclei If the temperature exceeds the melting temperature of the target substance a liquid is formed The rapid quenching leaves behind an amorphous state with decreased density Its disorder corresponds to the ion track 3 33 The thermal spike model suggests the radiation sensitivity of different materials depends on their thermal conductivity and their melting temperature nbsp Thermal spike modelIon track corresponds to frozen disorder after rapid quenching of melt zone around ion trajectory Temperature represented by color Ion path vertical to image plane nbsp Latent ion track in muscovite mica Depending on the stopping power of the projectile ion the track width is between 4 and 10 nanometer nbsp Molecular dynamics simulation of collision cascade in gold nbsp Track etch threshold energy input required for selective etching For ionic crystals the threshold increases with the heat conductivity Amorphous metal FeBSiC included for comparison Etching methods editSelective ion etching edit Selective ion track etching 2 is closely related to the selective etching of grain boundaries and crystal dislocations The etch process must be sufficiently slow to discriminate between the irradiated and the pristine material The resulting shape depends on the type of material the concentration of the etchant and the temperature of the etch bath In crystals and glasses selective etching is due to the reduced density of the ion track In polymers selective etching is due to polymer fragmentation in the ion track core The core zone is surrounded by a track halo in which cross linking can impede track etching After removal of the cross linked track halo the track radius grows linear in time The result of selective etching is a trough pore or channel Surfactant enhanced etching edit Surfactant enhanced etching is used to modify ion track shapes 34 It is based on self organized monolayers 11 The monolayers are semi permeable for the solvated ions of the etch medium and reduce surface attack Depending on the relative concentration of the surfactant and the etch medium barrel or cylindrical shaped ion track pores are obtained The technique can be used to increase the aspect ratio 35 Other related terminology edit Repeated irradiation and processing A two step irradiation and etching process used to create perforated wells Arbitrary irradiation angles enforce an anisotropy along one specific symmetry axis Multiangular channels are interpenetrating networks consisting of two or more channel arrays in different directions nbsp Double sided etching of ion track at track etch ratio 5 1 nbsp Asymmetric ion track channels with strongly reduced top diameter nbsp Microwells with perforated bottom nbsp Two membranes with different channel inclination vertical and 45 degrees nbsp Three membranes perforated at two strutting angles 10 20 45 degrees Track etching of common polymers 36 Material pH Wet etchant Sensitizer1 Desensitizer2 T C3 Speed4 Selectivity5 PC basic NaOH UV Alcohols 50 80 Fast 100 10000PET basic NaOH UV DMF Alcohols 50 90 Fast 10 1000basic K2CO3 80 Slow 1000PI basic NaOCl NaOH 50 80 Fast 100 1000CR39 basic NaOH UV 50 80 Fast 10 1000PVDF6 basic KMnO4 NaOH 80 Medium 10 100PMMA6 acidic KMnO4 H2SO4 50 80 Medium 10PP6 acidic CrO3 H2SO4 80 Fast 10 1001 Sensitizers increase the track etch ratio by breaking bonds or by increasing the free volume 2 Desensitizers decrease the track etch ratio Alternatively ion tracks can be thermally annealed 3 Typical etch bath temperature range Etch rates increase strongly with concentration and temperature 4 Axial etching depends on track etch speed vt radial etching depends on general etch speed vg 5 Selectivity aspect ratio track etch ratio track etch speed general etch speed vt vg 6 This method requires to remove remaining metal oxide deposits by aqueous HCl solutions Replication editEtched ion tracks can be replicated by polymers 37 or metals 12 38 Replica and template can be used as composite A replica can be separated from its template mechanically or chemically Polymer replicas are obtained by filling the etched track with a liquid precursor of the polymer and curing it Curing can be activated by a catalyst by ultraviolet radiation or by heat Metal replicas can be obtained either by electroless deposition or by electro deposition For replication of through pores a cathode film is deposited on one side of the membrane and the membrane is immersed in a metal salt solution The cathode film is negatively charged with respect to the anode which is placed on the opposite side of the membrane The positive metal ions are pulled toward the cathode where they catch electrons and precipitate as a compact metal film During electro deposition the channels fill gradually with metal and the lengths of the nano wires are controlled by the deposition time Rapid deposition leads to polycrystalline wires while slow deposition leads to single crystalline wires A free standing replica is obtained by removing the template after deposition of a bearing film on the anode side of the membrane Interpenetrating wire networks are fabricated by electro deposition in multi angle track etched membranes Free standing three dimensional networks with tunable complexity and interwire connectivity are obtained 39 Segmented nanowires are fabricated by alternating the polarity during electro deposition 40 The segment length is adjusted by the pulse duration In this way electrical thermal and optical properties can be tuned nbsp Free standing metal replica of etched ion tracks in PC nbsp Interpenetrating wire network nbsp Bundle of segmented platinum nanowiresApplications editMicrotechnology The common mechanical tools of the macroworld are being supplemented and complemented and in some applications replaced by particle beams Here beams of photons and electrons modify the solubility of radiation sensitive polymers so called resists while masking protects a selected area from exposure to radiation chemical attack and erosion by atomic impact Typical products produced in this way are integrated circuits and microsystems At present the field of microtechnology is expanding toward nanotechnology A recent branch of microfabrication is based on manipulation of individual ions Geology Ion tracks are useful as they can remain unaltered for millions of years In minerals Their density yields information about the time when the mineral solidified from its melt and are used as geological clocks in fission track datingFilters Homoporous filters were among the first applications 8 of ion track technology and are now fabricated by several companies 41 Mica membranes with ion track pores were used by Beck and Schultz to determine the mechanism of hindered diffusion in nanopores 42 43 Classifying micro and nanoparticles The resistance of a channel filled by an electrolyte depends on the volume of the particle passing through it 10 This technique is applied to the counting and sizing of individual red blood cells bacteria and virus particles pH Sensor Charged channels filled with an electrolyte have a surface conductivity in addition to the regular volume conductivity of the electrolyte Ions attached to a charged surface attract a cloud of mobile counterions Fixed and mobile ions form a double layer For small channels surface conductivity is responsible for most of the charge transport For small channels surface conductivity exceeds volume conductivity Negative surface charges can be occupied by firmly bound protons At low pH high proton concentration the wall charge is completely neutralized Surface conductivity vanishes Due to the dependence of surface conductivity on pH the channel becomes a pH sensor 44 Current rectifying pores Asymmetric pores are obtained by one sided etching The geometric asymmetry translates into a conduction asymmetry The phenomenon is similar to an electrical valve The pore has two characteristic conduction states open and closed Above a certain voltage the valve opens Below a certain voltage the valve closes 45 46 Thermo responsive channel Obtained by lining a channel with a thermo responsive gel 47 Bio sensor Chemical modification of the channel wall changes its interaction with passing particles Different wall claddings bind to specific molecules and delay their passage In this sense the wall recognizes the passing particle As an example DNA fragments are selectively bound by their complementary fragments The attached molecules reduce the channel volume The induced resistance change reflects the molecule s concentration 48 Anisotropic conduction A platform covered with many free standing wires acts as large area field emitter 49 Magnetic multilayers Nano wires consisting of alternating magnetic nonmagnetic layers act as magnetic sensors As an example cobalt copper nanowires are obtained from an electrolyte containing both metals At low voltage pure copper is deposited while cobalt resists electro deposition At high voltage both metals are deposited as an alloy If the electrolyte contains predominantly cobalt a magnetic cobalt copper alloy is deposited with a high fraction of cobalt The electrical conductivity of the multilayer wire depends on the applied external magnetic field The magnetic order of the cobalt layers increases with the applied field Without magnetic field neighboring magnetic layers prefer the anti parallel order With magnetic field the magnetic layers prefer the orientation parallel with the magnetic field The parallel orientation corresponds to a reduced electrical resistance The effect is used in reading heads of magnetic storage media the GMR effect 50 Spintronics Spin valve structure consists of two magnetic layers of different thicknesses The thick layer has a higher magnetic stability and is used as polarizer The thin layer acts as analyzer Depending on its magnetization direction with respect to the polarizer parallel or antiparallel its conductivity is low or high respectively 51 Textures Tilted textures with a hydrophobic coating are at the same time superhydrophobic and anisotropic 18 and show a preferred direction of transport The effect has been demonstrated to convert vibration into translation 52 nbsp Etched ion tracks nbsp Particle Transit Channel The transient current drop is proportional to the particle volume nbsp pH Sensor The moving circle represents the cross section of a negatively charged channel Left At low pH all surface charges are occupied by protons low conductivity Right At high pH all surface charges are available high conductivity nbsp Asymmetric pore transmits positive ions preferentially from right to left nbsp Thermo responsive channel The hydrogel lined channel opens above and closes below the critical temperature of the hydrogel nbsp Biospecific Sensor The electrical resistance of a channel clad with an immuno reactant depends on the concentration of a specific molecule nbsp Field emitter array nbsp Multilayer Magnetosensor Low magnetic field antiparallel orientation and high resistance High magnetic field parallel orientation and low resistance nbsp Spin AnalyzerThe energy loss of spin polarized electrons depends on the magnetic orientation of the analyzer Left polarizer blue spin up Right analyzer blue spin up red spin down nbsp Tilted Track Texture with asymmetric transport properties Notes edit D A Young 1958 Etching of radiation damage in lithium fluoride Nature 182 4632 375 377 Bibcode 1958Natur 182 375Y doi 10 1038 182375a0 PMID 13577844 S2CID 4282512 a b c d e R L Fleischer P B Price R M Walker 1975 Nuclear tracks in solids Vol 220 University of California Press pp 30 9 doi 10 1038 scientificamerican0669 30 ISBN 978 0 520 02665 0 PMID 5769561 a href Template Cite book html title Template Cite book cite book a journal ignored help a b F Seitz J S Koehler 1956 F Seitz D Turnbull eds Solid State Physics Academic Press 307 LCCN 55012299 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help M Toulemonde C Dufour A Meftah E Paumier 2000 Transient thermal processes in heavy ion irradiation of crystalline inorganic insulators Nuclear Instruments and Methods B 166 167 903 912 Bibcode 2000NIMPB 166 903T doi 10 1016 S0168 583X 99 00799 5 G Remmert Y Eyal B E Fischer R Spohr 1995 Gas permeability and cross section of latent ion tracks in polymers Nuclear Instruments and Methods B 105 1 4 197 199 Bibcode 1995NIMPB 105 197R doi 10 1016 0168 583X 95 00576 5 R Spohr 1990 Ion tracks and microtechnology Vieweg Verlag ISBN 978 3 528 06330 6 a b W D Williams N Giordano 1984 Fabrication of 80 A metal wires Review of Scientific Instruments 55 3 410 412 Bibcode 1984RScI 55 410W doi 10 1063 1 1137752 a b R L Fleischer P B Price R M Walker 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Molares W Ensinger 2011 Highly Ordered Supportless Three Dimensional Nanowire Networks with Tunable Complexity and Interwire Connectivity for Device Integration Nano Letters 11 6 2304 2310 Bibcode 2011NanoL 11 2304R doi 10 1021 nl2005516 PMID 21608990 M Rauber J Brotz J Duan J Liu S Muller R Neumann O Picht M E Toimil Molares W Ensinger 2010 Segmented All Platinum Nanowires with Controlled Morphology through Manipulation of the Local Electrolyte Distribution in Fluidic Nanochannels during Electrodeposition Journal of Physical Chemistry C 114 51 22502 22507 doi 10 1021 jp108889c Ion track companies Physicsconsult de 2011 07 04 Retrieved 2013 01 21 Beck R E Schultz J S 1970 12 18 Hindered Diffusion in Microporous Membranes with Known Pore Geometry Science 170 3964 1302 1305 Bibcode 1970Sci 170 1302B doi 10 1126 science 170 3964 1302 ISSN 0036 8075 PMID 17829429 S2CID 43124555 Beck Robert E Schultz Jerome S January 1972 Hindrance of solute diffusion within membranes as measured with microporous membranes of known pore geometry Biochimica et Biophysica Acta BBA Biomembranes 255 1 273 303 doi 10 1016 0005 2736 72 90028 4 hdl 2027 42 34175 PMID 4334681 A Wolf N Reber P Yu Apel B E Fischer R Spohr 1995 Electrolyte transport in charged single ion track capillaries Nuclear Instruments and Methods in Physics Research B 105 1 4 291 293 Bibcode 1995NIMPB 105 291W doi 10 1016 0168 583X 95 00577 3 P Y Apel Y E Korchev Z Siwy Z R Spohr M Yoshida 2001 Diode like single ion track membrane prepared by electro stopping Nuclear Instruments and Methods in Physics Research B 184 3 337 346 Bibcode 2001NIMPB 184 337A doi 10 1016 S0168 583X 01 00722 4 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link P Ramirez P Yu Apel J Cervera S Mafe 2008 Pore structure and function of synthetic nanopores with fixed charges tip shape and rectification properties Nanotechnology 19 31 315707 Bibcode 2008Nanot 19E5707R doi 10 1088 0957 4484 19 31 315707 PMID 21828799 S2CID 43193256 M Tamada M Yoshida M Asano H Omichi R Katakai R Spohr J Vetter 1992 Thermo response of ion track pores in copolymer films of methacryloyl L alaninemethylester and diethyleneglycol bis allylcarbonate CR 39 Polymer 33 15 3169 3172 doi 10 1016 0032 3861 92 90230 T L T Sexton L P Horne C R Martin 2007 Developing synthetic conical nanopores for biosensing applications Molecular BioSystems 3 10 667 685 doi 10 1039 b708725j PMID 17882330 F Maurer A Dangwal D Lysenkov G Muller M E Toimil Molares C Trautmann J Brotz H Fuess 2006 Field emission of copper nanowires grown in polymer ion track membranes Nuclear Instruments and Methods in Physics Research B 245 1 337 341 Bibcode 2006NIMPB 245 337M doi 10 1016 j nimb 2005 11 124 L Piraux J M George J F Despres C Leroy E Ferain R Legras K Ounadjela A Fert 1994 Giant magnetoresistance in magnetic multilayered nanowires Applied Physics Letters 65 19 2484 2486 Bibcode 1994ApPhL 65 2484P doi 10 1063 1 112672 B Doudin J P Ansermet 1997 Nanostructuring materials for spin electronics Europhysics News 28 1 14 17 Bibcode 1997ENews 28 14D doi 10 1007 s00770 997 0014 8 S2CID 123078833 Converting vibration into translation Retrieved 2013 01 21 External links edit nbsp Media related to Ion track at Wikimedia Commons Retrieved from https en wikipedia org w index php title Ion track amp oldid 1172058211, wikipedia, wiki, book, books, library,

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