Classifications

• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B21/00—Microscopes
  • G02B21/32—Micromanipulators structurally combined with microscopes

Definitions

• the invention relates to a device for trapping particles.
• the device of the invention finds applications, for example, in the field of nanotechnologies (manipulation and assembly of micro and nanoparticles, dielectrics, semiconductors and metals, nanowires or nanotubes), biology
• an optical trap forming device comprises a laser source which emits a laser beam and means of focusing the laser beam which strongly concentrate the laser beam with the aid of a microscope objective whose opening numeric is greater than 1.
• FIGS. 1A and 1B illustrate the known principle of trapping a particle P with the aid of an optical clamp.
• a particle P is placed in a liquid L.
• a laser beam F emitted by a laser source (not shown in the figure) is focused in the liquid L and has a central zone of smaller diameter W, commonly called “waist”.
• W central zone of smaller diameter W
• the particle P has a refractive index greater than that of the liquid medium L surrounding it and if it is placed in the vicinity of the beam, it enters, under the effect of forces commonly called “forces of gradient "in the field of the beam F (see Figure IA). In fact, these forces attract the particle P towards the maximum intensity of the beam, that is to say at waist level. The particle then stops in the center of the waist (see Figure IB).
• the particle thus trapped is then displaced by relative displacement of the beam F and the medium containing the particle (displacement of the medium containing the particle P with respect to the beam, displacement of the beam F relative to the medium, mutual displacement of the beam and the medium).
• the diameters of the trapped particles range from ten microns to ten nanometers.
• the particles can be of different types: dielectric, metallic, semiconductive, biological, polymeric, etc.
• a major disadvantage of the particle trapping method described above is that the trapping volume of the clamp is limited by diffraction at the objective.
• the trapping volume depends on the size of the waist of the beam, which is related to the wavelength used, the numerical aperture of the objective and the middle index in which the lens is immersed. .
• the positioning accuracy by an optical clamp of this type is several hundred nanometers, even micron, which is not a good accuracy.
• Optical traps of this type exhibit strong spatial confinement of the electromagnetic field and thus allow a more precise location of the object.
• the positioning accuracy is of the order of ten nanometers.
• FIG. 2 A first example of this type of optical trap is given in FIG. 2.
• a metal mask M provided with nano-openings 0 is deposited on a structure T.
• the structure T is transparent to the wavelength of the laser beam F which must trap the particles.
• the laser beam F propagates in the structure T in a direction substantially perpendicular to the flat surface on which the mask M is deposited.
• the laser beam F then passes through all the openings 0 which thus constitute so many traps for the particles. It is then possible, for example, to trap a latex particle of 200 nm in diameter in a nano-opening of 500 nm in diameter.
• the disadvantages of such an optical clamp are, on the one hand, the number of steps related to the manufacture of nano-openings is important and, on the other hand, that the particles are not trapped in a free space but in a hole.
• FIG. 3 represents a schematic diagram of such a point Pt placed in a laser beam and the distribution of the intensity of the electromagnetic field around the tip. Intensity levels are increasing as you get closer to the tip (darker and darker areas in Figure 3).
• FIGS. 4A and 4B relate to another known device for optical trapping with an optical near-field effect.
• This other known device comprises a photonic crystal array Ph in which a cavity Q is formed.
• the photonic crystal array Ph is fixed on a transparent substrate T.
• a laser beam F passes through the substrate T to reach the photonic crystal array Ph.
• an overcurrent is generated at the cavity Q.
• FIG. 4B illustrates the presence of this overcurrent.
• FIG. 4B represents the normalized power R which is radiated, at the level of the cavity Q, by the device of FIG. 4A.
• the normalized power curve R is plotted as a function of the normalized wave wavelength ⁇ of the wave propagation in the device ( ⁇ is expressed in multiples of the period "a" of the photonic crystal array). It appears, at a given wavelength A 0 , an overcurrent of the optical power in the network. This overcurrent is used for particle trapping.
• the disadvantages of such a device are the large number and complexity the various technological steps necessary for the fabrication of the photonic crystal array, the cost of the tunable laser source necessary for the proper functioning of the device and the tuning of the tuning wavelength A 0 which depends on the size, the shape and the nature of the particles.
• FIG. 5 Another optical near-field optical trapping device is also known from the prior art. This other device is shown in FIG. 5. It comprises a Pr pr pr transparent to the wavelength of use on which are deposited a glass plate V and a thin layer of gold f. A laser beam F passes through the prism and the glass slide V until it reaches the gold layer f on which it is reflected to create the reflected beam Fr. The direction of the laser beam F must imperatively deviate from the normal to the glass slide (ie the angle of incidence ⁇ of the beam on the glass slide must be non-zero). The coupling of the laser light in the metal layer f leads to the formation of a plasmon on the surface of the gold layer f and the appearance of an evanescent electromagnetic field Ev on this surface.
• the particles are trapped in an annular arrangement that results from two contributions: a) the optical forces attract the objects towards the center of the beam; b) the thermophoretic forces expel the particles from the beam.
• a disadvantage of this device is its complexity due, among other things, to the use of a prism.
• the invention does not have the disadvantages mentioned above.
• the invention relates to a device for trapping particles contained in a liquid placed in a tank, characterized in that it comprises a transparent substrate at a working wavelength, a thin layer of material with no optical properties. -linear reversible at the working wavelength fixed on a first face of the transparent substrate and forming all or part of at least one wall of the vessel in contact with the liquid, a near field effect optical trap forming device lens which comprises a laser source which emits a laser beam at the working wavelength and means for forming a waist of the laser beam, said means being positioned relative to the transparent substrate so that the laser beam is incident on a second face of the transparent substrate located opposite the first face and that the waist of the laser beam is formed in the thin layer, an electromagnetic field evanes This is formed as an extension of the laser beam waist on the surface of the thin layer.
• the device for trapping particles comprises an optical mask provided with openings deposited on the thin layer.
• the particle trapping device comprises an optical mask provided with openings placed between the thin layer and the first face of the substrate.
• a light modulator modulates the phase of the laser beam so that a plurality of elementary laser beams are formed under the action of the light modulator, each elementary laser beam participating in the formation of the laser beam. an evanescent field at the surface of the thin layer.
• each evanescent field at the surface of the thin layer is capable of trapping a particle.
• an additional layer having an antireflection or mirror function is placed between the thin layer and the substrate.
• a negative refractive index lens is placed on the surface of the thin layer, in contact with the liquid.
• the negative index lens comprises a stack of metal / dielectric bilayers.
• the thin layer is covered with a treatment layer capable of controlling the wettability of the surface of the thin layer which is in contact with the liquid.
• the treatment layer is hydrophobic.
• the thin layer constitutes a light intensity mask that moves with the laser beam.
• the device of the invention does not necessarily have to include complex nanostructure to precisely locate small or large objects (typical dimensions ranging from 10 nm to more than 1 ⁇ m), as is the case with the devices of the art. prior.
• FIGS. 1A and 1B illustrate the principle of trapping a particle using an optical clamp according to the known art
• FIG. 2 represents a first example of an optical near field effect optical trap forming device according to the prior art
• FIG. 3 represents a second example of an optical near field effect optical trap forming device according to the prior art
• FIGS. 4A and 4B illustrate a third example of an optical near field effect optical trap forming device according to the prior art
• FIG. 5 represents a fourth example of an optical near field effect optical trap forming device according to the prior art
• FIG. 6 represents an optical near-field optical trap forming device according to the invention
• FIGS. 7A and 7B respectively represent a first variant and a second variant of a first improvement of the optical near field effect optical trap forming device of the invention
• Fig. 8 shows a second improvement of the optical near field effect optical trap forming device of the invention
• FIG. 9 represents a particle trapping device which comprises an optical trap forming device according to the device represented in FIG. 6;
• FIG. 10 represents a first improvement of the particle trapping device represented in FIG. 9;
• FIG. 11 represents a second improvement of the particle trapping device represented in FIG. 9;
• FIG. 12 represents a third improvement of the particle trapping device shown in FIG. 9;
• FIG. 13 shows a particle trapping device which comprises an optical trap forming device according to the device shown in FIG. 7;
• FIG. 14 represents a particle trapping device which comprises an optical trap forming device according to the device represented in FIG. 8.
• FIG. 6 represents an optical near-field optical trap forming device according to the invention.
• the device comprises an objective 3 which focuses a laser beam F coming from a laser source (not shown in the figure), a support 2 transparent to the wavelength of the laser beam and a thin layer 1 of material with non-optical properties.
• "Material with reversible non-linear optical properties" means a material whose refractive index changes as a function of the illumination it receives, the number of photons arriving on this material being taken per unit of solid angle, and returning to its initial value after the illumination has ceased.
• the material with reversible nonlinear optical properties is, for example, a III-V type semiconductor material with a small bandgap (for example InSb, GaAs, InAs, InP, GaP, CdTe, ZnS, CdS, etc.) or weakly doped (for example In x Sb y Te z ), or a material composed of KDP, or KH 2 PO 4 , or LiNbO 3 , or LiTaO 3 , or BaTiO 3 , or KNbO 3 , or BiI 2 SiO 2 O, or BiI 2 TiO 2 O, or KTP, or a phase change material such as, for example , a calcine.
• a III-V type semiconductor material with a small bandgap for example InSb, GaAs, InAs, InP, GaP, CdTe, ZnS, CdS, etc.
• weakly doped for example In x Sb y Te z
• the objective 3 focuses the laser beam F so that the waist W of the beam is located in the thin layer 1.
• the thin layer 1 changes the electronic structure of the as observed during super-resolution phenomena in optical recording (see Pichon et al., "Multiphysics Simulation of Super-Resolution BD ROM Optical Disk Readout", pages 206-208, ODS 2006).
• the laser beam is then confined, inside the thin layer 1, in a zone z of dimensions smaller than the diffraction limit in this layer and leaves the thin layer 1 in the form of an evanescent electromagnetic field Ev very concentrated. This very concentrated evanescent electromagnetic field allows high performance optical trapping of particles.
• FIG. 7A represents a first variant of a first improvement of the optical near-field optical trap forming device according to the invention.
• the optical trap comprises an optical mask M such as that mentioned above with reference to FIG. 2.
• the mask M is placed on the face of the layer 1.
• the mask M advantageously creates a local overcurrent which, combined with the overcurrent created by the thin layer 1, leads to an even greater concentration of the evanescent field. It is then advantageously possible to use a laser beam of lower power than in the configuration without mask while obtaining identical results in terms of concentration of the evanescent field.
• the optical mask M is placed under the face of the thin layer 1, that is to say between the thin layer 1 and the transparent support 2.
• FIG. 7B illustrates this second variant.
• Fig. 8 shows a second improvement of the optical trap forming device of the invention.
• the device represented in FIG. 8 comprises a mod spatial light modulator, for example a liquid crystal screen, and a computer or a personal computer PC which controls the spatial modulator. of light Mod.
• a particle surrounded by several elementary laser beams can to be kept in the center of these beams by repulsion.
• Other means than a liquid crystal display can be used for forming multi-beam clamps such as, for example, an interferometer or a diffraction grating, or a hologram.
• FIG. 9 represents a particle trapping device which is associated with the optical near-field optical trap forming device represented in FIG. 6.
• the particles P evolve in a liquid L contained in a tank 4 whose bottom wall is made by the thin layer 1.
• the very concentrated evanescent electromagnetic field Ev traps any particle located in its vicinity. To make a displacement of a particle thus trapped, a relative displacement of the laser beam F and the structure consisting of the elements 1, 2 and 4 is performed.
• the thickness of the thin layer 1 can vary, for example, from 5 nm to 100 nm.
• the laser beam F may be a continuous or pulsed beam in a frequency range from Hz to THz.
• the following table illustrates some examples, without limitation:
• the substrate 2 transparent at the wavelength of use is made, for example, of silicon
• FIG. 10 represents a first improvement of the particle trapping device represented in FIG. 9.
• the device of FIG. 10 comprises, between the substrate 2 and the layer 1, an additional layer. 5 which has an optical function, for example antireflection / mirror.
• the layer 5 is formed of a single layer or a set of layers.
• the thickness of the layer or of the set of layers constituting the layer 5 is typically between 10 nm and 10 ⁇ m.
• the transfer of the layer 5 between the substrate 2 and the layer 1 is carried out by sol-gel, PVD (PVD for "Physical Vapor Deposition"), IBS (IBS for "Ion Beam Sputtering", spraying, CVD (CVD for "Chemical Vapor Deposition ”) ).
• the material (s) which constitutes (s) the layer 5 is (are) chosen from among the dielectrics such as, for example, SiO 2 , HgO 2 , Ta 2 O 5 , TiO 2 , ZrO 2 , Al 2 O 3 , YF 3 , LaF , Ta 2 O 6 .
• the layer 5 constitutes a heat sink which makes it possible to avoid the heating of the liquid L, which heating can occur under the effect of the laser beam.
• the material or materials that constitute the layer 5 are then chosen from metals (for example, copper, aluminum, etc.), oxides, or nitrides (for example Si 3 N 4 ).
• Fig. 11 shows a second improvement of the particle trapping device of the invention.
• the thin layer 1 is covered with a treatment for controlling the wettability of the surface on the portion of the stack in contact with the liquid L.
• a hydrophobic treatment is carried out with a layer of polytetrafluoroethylene commonly known as teflon or by grafting appropriate organic molecules to form, for example, a silane layer.
• the hydrophobic layer advantageously makes it possible to prevent the particles P from sticking to the thin layer 1.
• Fig. 12 shows a third improvement of the particle trapping device of the invention.
• the device comprises, above the layer 1, a negative refractive index lens 6.
• the negative refractive index lens consists of a stack of metal / dielectric bilayers.
• each bilayer of the stack of bilayers is produced by a layer silver (Ag) covered by a layer of silica (SiO 2 ) •
• the lens 6 advantageously makes it possible to image, on the surface of the lens, the confined beam at the surface of the layer 1 while maintaining its lateral dimension.
• FIG. a particle trapping device which comprises an optical trap forming device according to the device shown in Figure 7A.
• the device of FIG. 13 comprises a tank 4 situated above the layer 1. All the variants of the particle trapping devices represented in FIGS. 9-12 apply, if necessary, to particle trap device shown in FIG. 13.
• FIG. 14 shows a particle trap device which comprises an optical trap forming device according to the device shown in FIG. 8. In addition to the elements represented in FIG. 8, the device of FIG. FIG.
• the optical near-field optical trap forming device forms the bottom of the tank. More generally, the invention relates to other embodiments in which the optical near-field optical trap forming device constitutes all or part of any wall of the tank, the term "wall" in front of 'hear like any element of the tank in contact with the liquid and which delimits the inside of the outside of the tank (side wall, cover, bottom).
• a silica substrate for example of Hérasil Hl type
• a layer of InSb of 30 nm thickness is deposited by a sputtering method
• annealing is carried out for two hours with an oven heated to 200 ° C.
• a liquid solution is prepared containing 300 nm diameter latex beads which are injected into the tank by a micropipette;
• vat is covered by a coverslip
• the assembly thus constituted is placed on a sample holder of the optical system constituted by an inverted microscope construct which includes a lens digital aperture of, for example, 1.2 and into which is injected a laser beam from a laser diode emitting, for example, at the wavelength 405 nm, a modulated wave at 1 GHz and 50 mW power.
• the sample holder is moved to trap the latex beads using the optical trap.
• particle is used to refer generally to an object or nanoobject capable of being trapped using the optical trap forming device of the invention.
• the term "nano-object" must of course not be understood as an object whose dimensions are exclusively of the order of a few nanometers.

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• Physics & Mathematics (AREA)
• Chemical & Material Sciences (AREA)
• Analytical Chemistry (AREA)
• General Physics & Mathematics (AREA)
• Optics & Photonics (AREA)
• Physical Or Chemical Processes And Apparatus (AREA)
• Microscoopes, Condenser (AREA)

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• 2008
  • 2008-05-26 FR FR0853414A patent/FR2931582B1/fr not_active Expired - Fee Related
• 2009
  • 2009-05-25 WO PCT/EP2009/056274 patent/WO2009144187A1/fr active Application Filing
  • 2009-05-25 EP EP09753842A patent/EP2297745A1/de not_active Withdrawn
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