Patent Application
20140220258
This application claims the benefit under 35 U.S.C. §119(a) of Korean Patent Application No. 10-2013-0013046, filed on Feb. 5, 2013, in the Korean Intellectual Property Office, the entire disclosure of which is incorporated herein by reference for all purposes.
1. Field
The following description relates to a graphene fabrication method, and to, for example, a graphene fabrication method using a plurality of light sources.
2. Description of Related Art
Graphene is an allotrope of carbon, consisting of a single two-dimensional planar sheet of carbon atoms with a thickness of about 0.35 nanometers. In a graphene sheet, carbon atoms are packed into a honeycomb lattice, forming free spaces therebetween. The arrangement of carbon atoms and free spaces therebetween provide a graphene molecule with flexibility that allows a certain degree of deformation, such as bending and twisting. In addition, a hexagonal arrangement of carbon atoms ensures electrical conductivity and chemical stability.
Graphene can carry two hundred times more current than copper and can carry current two hundred times faster than silicon at a room temperature. In addition, graphene has twice the room-temperature thermal conductivity than diamond, and two hundred times more mechanical strength than steel. Therefore, researches for the utilization of graphene, as one of the most promising future electronic materials, are increasing. Due to such excellent properties, for example, an electrode made of graphene may have both high energy density of a battery and high power performance of a capacitor.
Graphene is generally obtained by an exfoliation method or a synthesis method. In an exfoliation method, a graphene layer may be exfoliated from graphite. Graphite is abundantly present in nature. Further, in comparison to a synthesis method, the exfoliation method is characterized by low energy consumption, and enables mass production of graphene. However, with the exfoliation method, it is difficult to achieve a graphene sheet having a large surface area, and the yield is generally low in comparison to the amount of graphite that is processed. The exfoliation method may be further classified into a physical exfoliation method and a chemical exfoliation method, depending on the treatment method used for exfoliation.
A synthesis method involves synthesizing a layer of graphene directly from a carbon source. In comparison to the exfoliation method, the synthesis method generally requires more energy. However, the synthesis method enables production of graphene sheets having a large surface area with low defects.
However, with the above described methods, limitations exist in effectively forming graphene sheets having a large surface area and excellent uniformity in the molecular arrangement of carbon atoms. For instance, the actual capacitance per unit weight exhibited by the graphene sheets formed by a general method is 99 to 130 F/g, which is much lower than the highest theoretical capacitance value, 550 F/g.
A method of fabricating graphene using a single type of light source, such as laser, has been suggested. However, laser light is concentrated on a relatively small area, and thus it may take a substantial amount of time and energy irradiating a large area with the laser light to obtain graphene by the suggested method, and the quality of graphene may vary depending on a position of laser irradiation to a graphite oxide layer.
In one general aspect, there is provided a method of fabricating graphene, including: irradiating a graphite oxide layer on a substrate with light from a first light source; and irradiating the irradiated graphite oxide layer with light from a second light source. The first light source may be a laser light source, and the second light source may be a flash light source.
In the alternative, the first light source may be a flash light source, and the second light source may be a laser light source.
The laser light source may emit light of wavelengths used in an optical recording device and/or an optical reproducing device.
The laser light source may emit light of wavelengths in a range of 400 nm to 820 nm.
The flash light source may include xenon flash and UV flash.
The general aspect of the method may further include: irradiating the second-light-irradiated graphite oxide layer with light from a third light source.
The third light source may be either a laser light source or a flash light source.
The first and second light sources may be laser light sources while the third light source may be a flash light source, or the first and second light sources may be flash light sources while the third light source may be a laser light source.
The first light source may be a laser light source while the second and third light sources may be flash light sources, or the first light source may be a flash light source while the second and third light sources may be laser light sources.
The substrate may be a thermoplastic polymer substrate containing polycarbonate.
In another general aspect, there is provided a method of fabricating graphene, including: forming a graphite oxide layer on a substrate; and irradiating the graphite oxide layer with both laser light and flash light to reduce the graphite oxide layer in a stepwise manner.
The reducing of the graphite oxide layer may include irradiating the graphite oxide layer alternately with the laser light and the flash light.
The reducing of the graphite oxide layer may include irradiating the graphite oxide layer with one of the laser light and the flash light twice consecutively, and then irradiating the graphite oxide layer again with the other light once.
The reducing of the graphite oxide layer may include irradiating the graphite oxide layer with one of the laser light and the flash light once, and then irradiating the graphite oxide layer again with the other light twice consecutively.
The substrate may be a thermoplastic polymer substrate containing polycarbonate.
The laser light may have a wavelength in a range of 400 nm to 820 nm.
The irradiating of the graphite oxide layer with laser light may involve exposing the graphite oxide layer formed on an optical disk to laser light from a laser light source of an optical recording device or an optical reproducing device.
The general aspect of the method may further involve collecting graphene from the reduced graphite oxide layer.
Other features and aspects may be apparent from the following detailed description, the drawings, and the claims.
Throughout the drawings and the detailed description, unless otherwise described, the same drawing reference numerals will be understood to refer to the same elements, features, and structures. The relative size and depiction of these elements may be exaggerated for clarity, illustration, and convenience.
The following description is provided to assist the reader in gaining a comprehensive understanding of the methods, apparatuses, and/or systems described herein. Accordingly, various changes, modifications, and equivalents of the methods, apparatuses, and/or systems described herein will be suggested to those of ordinary skill in the art. Also, descriptions of well-known functions and constructions may be omitted for increased clarity and conciseness.
The method includes irradiating a thin film layer of graphite oxide applied on a polycarbonate substrate of an optical disk, such as a DVD, CD, and the like, with light from both a laser light source and a flash light source, at least one time, in order to, to gradually reduce graphite oxide in the graphite oxide layer to graphene.
Polycarbonate, as a member of a particular thermoplastic polymer group, is capable of being easily manipulated, injection-molded and thermoformed. Polycarbonate is multifunctional engineering plastic with excellent heat-resistance, impact resistance, and optical properties, thereby being widely used for product plastic and engineering plastic and also as a material for exteriors of information appliances, such as, mobile phones, notebook computers, and monitors, and optical storage media, such as CDs and DVDs.
Although polycarbonate is taken as an example of a substrate material, the substrate may be made of various types of materials, such as resins, ferrous metals and non-ferrous metals.
Referring to
In this example, the first light source may be a laser light source, and the second light source may be a flash light source, or vice versa. For example, the laser light source may emit light of wavelengths used in an optical recording device and/or an optical reproducing device. For example, a general laser light source radiates infrared laser light having a wavelength of approximately 780 nm. The wavelength of laser light used in this example may be between 400 nm and 820 nm, but the range of wavelength of the laser light source is not limited thereto.
Flash light radiated from a flash light source momentarily releases energy greater than a predetermined amount. A flash light source that is generally used in a camera is a light source that emits strong light energy over a large area for a short period of time. In this example, various types of flash light sources, such as xenon flash, UV flash, and the like, may be used.
For example, to generate xenon flash light, xenon is injected into a hermetically sealed tube made of quartz glass, which is maintained within a pressure of 1 to 10 percent of atmospheric pressure. Then, a high voltage is applied between both electrodes of the tube, whereby a discharge occurs and a gas is ionized. After a certain period of time, currents of thousands of amperes from a charged condenser pass through the tube while exciting xenon atoms, resulting in the generation of flash light. Xenon flash light is white light having electromagnetic waves of all wavelengths. In an application that requires the use of electromagnetic waves having wavelengths in the infrared range, a different gas, such as krypton, may be used.
According to the example illustrated in
In another example of a method of fabricating graphene from a graphite oxide layer, the order of performing operations of
In additional examples illustrated in
Referring to
The order of performing operations illustrated in
Also, unlike the examples shown in
For example, as shown in
In the example illustrated in
In the example illustrated in
The graphite oxide layer may be exposed to light of first type and light of second type in an alternating manner in 320 and 330. However, exposure to light of one type may be repeated for twice or more before the layer is exposed to light of the other type. In this example, the light of first type and the light of second type may be laser light and flash light.
Also, three or more light sources that produce different wavelengths may be used to irradiate the graphite oxide layer. The exposure to alternating types of light may be repeated until the graphite oxide in the layer is fully reduced to graphene. In 350, the fully reduced graphene is collected or gathered from the surface of the substrate. When graphene is collected, it is possible that some portions of the graphite oxide layer may still include graphite oxide that has not been fully reduced.
In the examples shown in
Laser light is radiation that results from simultaneous emission of a large quantity of photons, and generally irradiates only a small area that is however strongly affected by the direct laser irradiation. For example, an area irradiated by infrared laser light is about 1 μm in diameter. Accordingly, it is difficult and inefficient to irradiate the entire area of a graphite oxide layer formed on a substrate with the laser light. To overcome such difficulties, flash light irradiation is also carried out to provide optical energy simultaneously to a large area. By the flash light irradiation, a remaining area of the graphite oxide layer, other than the area that is directly irradiated with laser light and is hence most strongly reduced, is reduced with flash light, so that a specific surface area is increased, resulting in a high capacitance. The laser light irradiation and the flash light irradiation may be performed in a complementary manner.
An explosion may occur on the surface of the graphite oxide layer when the simultaneous reduction of a large area by the flash light takes place. Such an explosion results in the graphite oxide layer having a porous structure. As the layer has more pores, the specific surface layer increases, and thus the layer can accumulate more electric charges, resulting in a higher capacitance, when compared with the case of fabricating a capacitor.
In one example, the reduced graphene may be collected in a form of a compressed layer of graphene. The graphite oxide layer that is exposed to laser light tends to be reduced as graphene in a form of a compressed layer. Exposure to flash light tends to result in a powder form of graphene. Performing a laser light irradiation before a flash light reduction may secure the structure of the graphite oxide layer, so that the laser light-irradiated graphite oxide layer is prevented from being scattered during a flash light irradiation process. Accordingly, in one example, the graphite oxide layer is first exposed to laser light before being exposed to flash light. However, the method of reducing the graphite oxide layer applied on the substrate is not limited thereto.
Referring to
Both a laser light source and a flash light source are used in fabrication of graphene by reducing a graphite oxide layer, so that drawbacks that may be caused when only one type of light source is used can be overcome and mass-production of high-quality graphene at a lower cost can be realized. In addition, the graphene produced by the examples of methods described above has superior characteristics than graphene produced by other methods.
Described above are examples of methods of fabricating graphene by gradually reducing a graphite oxide layer to graphene while irradiating the graphite oxide layer with each of laser light and flash light at least once. Also described above are examples of methods of fabricating graphene, including: irradiating a thin film of graphite oxide layer applied on a substrate with light from a first light source; and irradiating the irradiated graphite oxide layer with light from a second light source. The first light source may be a laser light source while the second light source may be a flash light source, or the first light source may be a flash light source while the second light source may be a laser light source. In addition, the examples of methods may further include irradiating the second-light-irradiated graphite oxide layer with light from a third light source, and the third light source may be either a laser light source or a flash light source.
Also described above are examples of methods of fabricating graphene, including: preparing a substrate with a thin film of graphite oxide layer applied thereon; and irradiating the graphite oxide layer with each of laser light and flash light at least once to reduce the graphite oxide layer in a stepwise manner. The reducing of the graphite oxide layer may include irradiating the graphite oxide layer alternately with the laser light and the flash light one at a time. The reducing of the graphite oxide layer may include irradiating the graphite oxide layer with one of the laser light and the flash light twice consecutively, and then irradiating the graphite oxide layer again with the other light once. Alternatively, the reducing of the graphite oxide layer may include irradiating the graphite oxide layer with one of the laser light and the flash light once, and then irradiating the graphite oxide layer again with the other light twice consecutively.
By using both laser light and flash light to reduce a graphite oxide layer to graphene, it may be possible to reduce a large area of the graphite oxide layer as compared to a method in which only one light source is used. Accordingly, with these examples of methods of fabricating graphene, it is possible to realize mass production of high-quality graphene at a lower cost.
A number of examples have been described above. Nevertheless, it should be understood that various modifications may be made. For example, suitable results may be is achieved if the described techniques are performed in a different order and/or if components in a described system, architecture, device, or circuit are combined in a different manner and/or replaced or supplemented by other components or their equivalents. Accordingly, other implementations are within the scope of the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2013-0013046 | Feb 2013 | KR | national |
