RU2465623C1 - Optical nanogenerator - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: device has a pair of telescopic nanotubes, a constant optical signal source, two output optical nano-waveguides, a constant signal source, an electric power supply, a group of electric contacts and two optical nano-waveguide Y-splitters.

EFFECT: broader capabilities of the device owing to execution of optical pulse generator functions, said generator having a nanosize design.

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Description

The invention relates to optical pulse technology and can be used in optical information processing devices and optical computers as a source of clock pulses.

A well-known optical generator is an optical multivibrator consisting of optical waveguides, optical splitters and optical bistable elements [Patent No. 2050017, Russia, 1995. Optical multivibrator. / Sokolov S.V.].

The disadvantages of this device are the design complexity and the inability to implement the device in nanoscale execution.

The essential features of this analogue common with the claimed device are optical waveguides, an optical splitter.

The closest in technical execution to the claimed device is an optical nanocomparator [Patent No. 2357275 of the Russian Federation. Optical nanocomparator. / Sokolov SV, Kamensky VV, 2009, BI No. 15], containing input and output optical nanowaves, telescopic nanotubes, a constant signal source.

The essential features of the prototype common with the claimed device are telescopic nanotubes, a constant signal source, and output optical nanowaves.

The disadvantage of the prototype is the inability to generate optical pulses.

The objectives of the invention are the creation of an optical device capable of generating both coherent and incoherent optical pulses, as well as the implementation of the device in nanoscale execution.

The technical result is to expand the capabilities of the device by performing the functions of an optical pulse generator in the implementation of the latter in nanoscale execution.

The essence of the invention lies in the fact that in an optical nanogenerator containing a pair of telescopic nanotubes, an optical source of a constant signal, two output optical nanowaves, a constant signal source, an electric power source, a group of electrical contacts, two optical nanowave Y-couplers, an output of an electric power source are introduced connected to the input of the first constant signal source through a group of electrical contacts, the output of the second constant signal source is connected to an ode of the first optical nanowaveguide Y-coupler, the first output of which is optically connected to the input of the second optical nanowaveguide Y-coupler, the first output of the second optical nanowaveguide Y-coupler is connected to the input of the first output optical nanowaveguide, and the second output of the second optical nanowaveguide Y-coupler is optically coupled the second output optical nanowaveguide, a pair of telescopic nanotubes is located between the output of the first constant signal source and the second output ne of a new optical nanowaveguide Y-splitter so that in the initial position the inner nanotube of a pair of telescopic nanotubes breaks the optical connection between the first output of the second optical nanowaveguide Y-splitter and the input of the first output optical nanowaveguide, while there is an optical connection between the second output of the second optical nanowave splitter and the input of the second output optical nanowave, as well as a closed group of electrical contacts in the far right In this case, the inner nanotube of a pair of telescopic nanotubes breaks the optical connection between the second output of the second optical nanowaveguide Y-splitter and the input of the second output optical nanowaveguide and opens the group of electrical contacts, while there is an optical connection between the first output of the second optical nanowaveguide Y-splitter and the input of the first output optical nanowave , the output of the first output optical nanowave is the first output of the device, the output of the second output optical nanowave is the second output of the device.

The claimed device is built on the basis of optical nanowaveguides, technical options for which are described in [Optics of nanostructures. / Edited by A.V. Fedorov: St. Petersburg. Nedra, 2005; Krenn J.R., Dereux A., Weeber J.C. et al. Squeezing the optical near-field zone by plasmon coupling of metal nanoparticles. Physical Review Letters, 1999, 82, 12, 2590], and telescopic nanotubes, which are understood as a pair of nanotubes embedded in each other [Multiwalled Carbon Nanotubes as Gigahertz Oscillators. / Quanshui Zheng, Qing Jiang // Phys. Rev. Lett. 88, 045503, 28 January, 2002].

Functional diagram of the optical nanogenerator shown in figure 1.

Optical nanogenerator contains:

- 1 ₁ , 1 ₂ , - two sources of constant radiation (AI); the radiation intensity of the first AI 1 ₁ is m sr (unit) units (units); the radiation intensity of the second AI 1 ₂ is 4 × n srvc .; moreover, 2 × n <m;

- 2 - source of electrical power (IEP);

- 3 - group of electrical contacts;

- 4 ₁ , 4 ₂ - the first and second optical nanowaveguide Y-splitters;

- 5 ₁ , 5 ₂ - a pair of telescopic nanotubes containing an inner nanotube 5 ₁ and an outer nanotube 5 ₂ ;

- 6 ₁ , 6 ₂ - the first and second output optical nanowaveguides.

The first AI 1 _{1 is} included in the circuit of the IEP 2, closed by a group of electrical contacts 3.

The output of the second AI 1 _{2 is} connected to the input of the first optical nanowaveguide Y-splitter 4 ₁ , the first output of which is optically connected to the input of the second optical nanowaveguide Y-splitter 4 ₂ .

The first output of the second optical nanowaveguide Y-coupler 4 _{2 is} optically connected to the input of the first output optical nanowave 6 ₁ , and the second output is optically connected to the input of the second output optical nanowave 6 ₂ .

A pair of telescopic nanotubes 5 ₁ , 5 ₂ is located between the output of the first AI 1 ₁ and the second output of the first optical nanowave Y-splitter 4 ₁ along the propagation axis of their optical signals.

In the initial state, the inner nanotube 5 ₁ pair of telescopic nanotubes 5 ₁ , 5 ₂ breaks the optical connection between the first output of the second optical nanowave Y-splitter 4 ₂ and the input of the first output optical nanowave 6 ₁ - there is an optical connection between the second output of the second optical nanowave Y -splitter 4 ₂ and the input of the second output optical nanowave 6 ₂ , as well as a closed group of electrical contacts 3.

In the extreme right position, the inner nanotube 5 ₁ pair of telescopic nanotubes 5 ₁ , 5 ₂ breaks the optical connection between the second output of the second optical nanowave Y-splitter 4 ₂ and the input of the second output optical nanowave 6 ₂ and opens the group of electrical contacts 3, while there is an optical connection between the first output of the second optical nanowave Y-splitter 4 ₂ and the input of the first output optical nanowave 6 ₁ .

Under the influence of a force due to the pressure of the light flux or the pressure difference of the light fluxes (optical powers of 1-5 watts create forces of 5-15 nN), the inner nanotube 5 _{1 of a} pair of telescopic nanotubes 5 ₁ , 5 ₂ will move in the direction of the optical flux with greater intensity (it must be borne in mind that the minimum required force for moving a nanotube is atttonewtons [Multiwalled Carbon Nanotubes as Gigahertz Oscillators. / Quanshui Zheng, Qing Jiang // Phys. Rev. Lett. 88, 045503, January 28, 2002]).

Output of the first output optical nanowaveguide June ₁ is the first output of the apparatus (output 1), the output of the second output optical nanowaveguide June ₂ is the second output of the apparatus (output 2).

The operation of the device proceeds as follows.

From the output of the second AI 1 ₂ optical stream with an intensity of 4 × n srvc arrives at the input of the first optical nanowaveguide Y-splitter 4 ₁ , from the first and second outputs of which optical flows are formed with an intensity of 2 × n conv.ed. everyone. The first of them enters the input of the second optical nanowaveguide Y-splitter 4 ₂ . At the first and second outputs of the second optical nanowave-wave Y-splitter 4 ₂ formed optical flows with an intensity of n srvc everyone. From the second output of the first optical nanowave Y-splitter 4 ₁ optical flow with an intensity of 2 × n srvc enters the inner nanotube 5 ₁ pair of telescopic nanotubes 5 ₁ , 5 ₂ .

In the initial position, at the output of the second output optical nanowave 6 ₂ (at the “Output 2” of the device), an optical stream with an intensity of n conv.

Simultaneously, the inner nanotube May ₁ pair of telescopic nanotubes May ₁ and 5 ₂ in the rest position closes a set of electrical contacts 3. In this case the input of the first AI January ₁ is energized by ISP 3. The output of the first AI ₁ January optical flux with an intensity m> 2 × n conv. enters the inner nanotube 5 ₁ pair of telescopic nanotubes 5 ₁ , 5 ₂ .

Under the influence of the pressure difference of the optical flows, the inner nanotube 5 ₁ pairs of telescopic nanotubes 5 ₁ , 5 ₂ will begin to move to the right and will occupy the right extreme position. In this case, there will be no optical connection between the second output of the second optical nanowave Y-splitter 4 ₂ and the input of the second output optical nanowave 6 ₂ . In addition, optical coupling will be present between the first output of the second optical coupler Y-nanovolnovodnogo April ₂ and the input of the first output optical nanowaveguide June _1, is opened and a group of electrical contacts 3. Therefore, output from the second output optical nanowaveguide February ₆ (on the "output 2 "Device) optical flow with an intensity of n srvc more will not be formed, and at the output of the first output optical nanowave 6 ₁ (at the “Output 1” of the device) an optical stream with an intensity of n conv.

Since in the extreme right position the group of electrical contacts 3 is open, then the input of the first AI 1 ₁ voltage is not supplied from the IED 3. From the output of the first AI 1 ₁ optical stream with an intensity of m> 2 × n srvc The pairs of telescopic nanotubes 5 ₁ , 5 ₂ , which previously arrive at the inner nanotube 5 ₁ , are no longer formed.

Under the action of pressure from the optical stream from the second output of the first optical nanowave Y-splitter 4 ₁ with an intensity of 2 × n srvc the inner nanotube 5 ₁ pairs of telescopic nanotubes 5 ₁ , 5 ₂ will begin to move to the left and will occupy the leftmost - initial position. There will be no optical connection between the first output of the first optical nanowave Y-splitter 4 ₂ and the input of the first output optical nanowave 6 ₂ . In addition, optical coupling will be present between the second output of the second optical coupler Y-nanovolnovodnogo April ₂ and input of the second output optical nanowaveguide June _1, a group is also closed electrical contacts 3. Therefore, output from the first output optical nanowaveguide June ₁ (on the "Exit 1 "Device) optical flow with an intensity of n srvc more will not be formed, and at the output of the second output optical nanofibre 6 ₂ (at the “Output 2” of the device), an optical stream with an intensity of n conv.

The device has returned to its original state. Further operation of the optical nanogenerator is carried out similarly to the foregoing.

The frequency of the generated pulses is determined by the mass of the inner nanotube (≈10 ^-15 -10 ^-16 g), the friction force during its movement (≈10 ^-10 N), the intensity and dynamic characteristics of the radiation sources (for radiation sources made in the embodiment of the injection laser diode, performance is about 10 ^-10 ... 10 ^-12 s [Nosov Yu.R. Optoelectronics. / Yu.R. Nosov. - M .: Publishing House "Radio and Communication", 1989. - 360 p.]) and is ≈ 10 ⁹ -10 ¹⁰ s ^-1 .

Claims (1)

An optical nanogenerator containing a pair of telescopic nanotubes, an optical source of a constant signal, two output optical nanowaves, characterized in that a constant signal source, an electric power source, a group of electrical contacts, two optical nanowave Y-couplers are inserted into it, the output of the electric power source is connected to the input of the first constant signal source through a group of electrical contacts, the output of the second constant signal source is connected to the input of the first optical nanowaveguide Y-splitter, the first output of which is optically connected to the input of the second optical nanowaveguide Y-splitter, the first output of the second optical nanowaveguide Y-splitter is connected to the input of the first output optical nanowave, and the second output of the second optical nanowave Y-splitter is optically connected to the second output optical nanowaveguide, a pair of telescopic nanotubes is located between the output of the first constant signal source and the second output of the first optical of a nanowaveguide Y-splitter in such a way that in the initial position the inner nanotube of a pair of telescopic nanotubes breaks the optical connection between the first output of the second optical nanowaveguide Y-splitter and the input of the first output optical nanowaveguide, while there is an optical connection between the second output of the second optical nanowaveguide Y-splitter and the input of the second output optical nanowave, and also a group of electrical contacts is closed, in the extreme right position a nanotube of a pair of telescopic nanotubes breaks the optical connection between the second output of the second optical nanowaveguide Y splitter and the input of the second output optical nanowaveguide and opens the group of electrical contacts, while there is an optical connection between the first output of the second optical nanowaveguide Y splitter and the input of the first output optical nanowave the output of the first output optical nanowave is the first output of the device, the output of the second output optical nanowave is the second output of the device.