TWI464113B - Carbon nanotube film - Google Patents
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- TWI464113B TWI464113B TW101115681A TW101115681A TWI464113B TW I464113 B TWI464113 B TW I464113B TW 101115681 A TW101115681 A TW 101115681A TW 101115681 A TW101115681 A TW 101115681A TW I464113 B TWI464113 B TW I464113B
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- 239000002238 carbon nanotube film Substances 0.000 title claims description 264
- OKTJSMMVPCPJKN-UHFFFAOYSA-N Carbon Chemical compound [C] OKTJSMMVPCPJKN-UHFFFAOYSA-N 0.000 claims description 341
- 239000002041 carbon nanotube Substances 0.000 claims description 262
- 229910021393 carbon nanotube Inorganic materials 0.000 claims description 262
- 239000011148 porous material Substances 0.000 claims description 13
- 238000005411 Van der Waals force Methods 0.000 claims description 10
- 229910052799 carbon Inorganic materials 0.000 claims description 7
- 229910021392 nanocarbon Inorganic materials 0.000 claims description 6
- CREMABGTGYGIQB-UHFFFAOYSA-N carbon carbon Chemical compound C.C CREMABGTGYGIQB-UHFFFAOYSA-N 0.000 claims 2
- 239000011203 carbon fibre reinforced carbon Substances 0.000 claims 2
- 238000002834 transmittance Methods 0.000 description 29
- 239000012528 membrane Substances 0.000 description 20
- 239000002904 solvent Substances 0.000 description 19
- 238000000034 method Methods 0.000 description 16
- 238000002360 preparation method Methods 0.000 description 10
- 239000003292 glue Substances 0.000 description 7
- LFQSCWFLJHTTHZ-UHFFFAOYSA-N Ethanol Chemical compound CCO LFQSCWFLJHTTHZ-UHFFFAOYSA-N 0.000 description 6
- 239000000758 substrate Substances 0.000 description 6
- 238000011282 treatment Methods 0.000 description 5
- 238000002474 experimental method Methods 0.000 description 4
- 239000011259 mixed solution Substances 0.000 description 4
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 4
- DKPFZGUDAPQIHT-UHFFFAOYSA-N Butyl acetate Natural products CCCCOC(C)=O DKPFZGUDAPQIHT-UHFFFAOYSA-N 0.000 description 3
- OKKJLVBELUTLKV-UHFFFAOYSA-N Methanol Chemical compound OC OKKJLVBELUTLKV-UHFFFAOYSA-N 0.000 description 3
- 230000008602 contraction Effects 0.000 description 3
- FUZZWVXGSFPDMH-UHFFFAOYSA-N hexanoic acid Chemical compound CCCCCC(O)=O FUZZWVXGSFPDMH-UHFFFAOYSA-N 0.000 description 3
- 238000013532 laser treatment Methods 0.000 description 3
- 238000004519 manufacturing process Methods 0.000 description 3
- 238000000879 optical micrograph Methods 0.000 description 3
- 239000003960 organic solvent Substances 0.000 description 3
- 238000000059 patterning Methods 0.000 description 3
- 238000012545 processing Methods 0.000 description 3
- 238000004544 sputter deposition Methods 0.000 description 3
- CSCPPACGZOOCGX-UHFFFAOYSA-N Acetone Chemical compound CC(C)=O CSCPPACGZOOCGX-UHFFFAOYSA-N 0.000 description 2
- HEDRZPFGACZZDS-UHFFFAOYSA-N Chloroform Chemical compound ClC(Cl)Cl HEDRZPFGACZZDS-UHFFFAOYSA-N 0.000 description 2
- XLOMVQKBTHCTTD-UHFFFAOYSA-N Zinc monoxide Chemical compound [Zn]=O XLOMVQKBTHCTTD-UHFFFAOYSA-N 0.000 description 2
- 238000004590 computer program Methods 0.000 description 2
- 238000001704 evaporation Methods 0.000 description 2
- 239000011521 glass Substances 0.000 description 2
- 238000001000 micrograph Methods 0.000 description 2
- 238000002156 mixing Methods 0.000 description 2
- 239000000243 solution Substances 0.000 description 2
- SCYULBFZEHDVBN-UHFFFAOYSA-N 1,1-Dichloroethane Chemical compound CC(Cl)Cl SCYULBFZEHDVBN-UHFFFAOYSA-N 0.000 description 1
- 238000002679 ablation Methods 0.000 description 1
- 238000004458 analytical method Methods 0.000 description 1
- 238000000137 annealing Methods 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 229910052793 cadmium Inorganic materials 0.000 description 1
- BDOSMKKIYDKNTQ-UHFFFAOYSA-N cadmium atom Chemical compound [Cd] BDOSMKKIYDKNTQ-UHFFFAOYSA-N 0.000 description 1
- CXKCTMHTOKXKQT-UHFFFAOYSA-N cadmium oxide Inorganic materials [Cd]=O CXKCTMHTOKXKQT-UHFFFAOYSA-N 0.000 description 1
- CFEAAQFZALKQPA-UHFFFAOYSA-N cadmium(2+);oxygen(2-) Chemical compound [O-2].[Cd+2] CFEAAQFZALKQPA-UHFFFAOYSA-N 0.000 description 1
- 238000004364 calculation method Methods 0.000 description 1
- 239000011248 coating agent Substances 0.000 description 1
- 238000000576 coating method Methods 0.000 description 1
- 238000011161 development Methods 0.000 description 1
- 229910003460 diamond Inorganic materials 0.000 description 1
- 239000010432 diamond Substances 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 238000010894 electron beam technology Methods 0.000 description 1
- 238000005286 illumination Methods 0.000 description 1
- AMGQUBHHOARCQH-UHFFFAOYSA-N indium;oxotin Chemical compound [In].[Sn]=O AMGQUBHHOARCQH-UHFFFAOYSA-N 0.000 description 1
- 238000011221 initial treatment Methods 0.000 description 1
- 239000004973 liquid crystal related substance Substances 0.000 description 1
- 238000002844 melting Methods 0.000 description 1
- 230000008018 melting Effects 0.000 description 1
- 229910044991 metal oxide Inorganic materials 0.000 description 1
- 150000004706 metal oxides Chemical class 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 239000002105 nanoparticle Substances 0.000 description 1
- 230000001590 oxidative effect Effects 0.000 description 1
- 230000035699 permeability Effects 0.000 description 1
- 238000003672 processing method Methods 0.000 description 1
- 238000001878 scanning electron micrograph Methods 0.000 description 1
- 238000010257 thawing Methods 0.000 description 1
- 239000011787 zinc oxide Substances 0.000 description 1
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- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L31/00—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L31/18—Processes or apparatus specially adapted for the manufacture or treatment of these devices or of parts thereof
- H01L31/1884—Manufacture of transparent electrodes, e.g. TCO, ITO
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- D03D15/00—Woven fabrics characterised by the material, structure or properties of the fibres, filaments, yarns, threads or other warp or weft elements used
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- H—ELECTRICITY
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- H10K—ORGANIC ELECTRIC SOLID-STATE DEVICES
- H10K30/00—Organic devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation
- H10K30/80—Constructional details
- H10K30/81—Electrodes
- H10K30/82—Transparent electrodes, e.g. indium tin oxide [ITO] electrodes
- H10K30/821—Transparent electrodes, e.g. indium tin oxide [ITO] electrodes comprising carbon nanotubes
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Description
本發明涉及一種奈米碳管膜。 The present invention relates to a carbon nanotube film.
透明導電膜係指對可見光的光透過率較高,電導率高的薄膜。自1907年Badker報導了通過濺射鎘並使之熱氧化形成氧化鎘製備出透明導電薄膜以來,透明導電薄膜的研究受到普遍重視。隨著科學的不斷發展,透明導電薄膜在液晶顯示、觸控屏、電致變色器件、飛機熱窗、除霜玻璃等領域起著重要的作用。 The transparent conductive film refers to a film having a high light transmittance to visible light and a high electrical conductivity. Since 1907, Badker reported that the transparent conductive film has been widely studied by sputtering cadmium and thermally oxidizing it to form cadmium oxide. With the continuous development of science, transparent conductive films play an important role in the fields of liquid crystal display, touch screen, electrochromic device, aircraft hot window, defrosting glass and the like.
目前,先前之透明導電膜氧化銦錫、氧化鋅等金屬氧化物薄膜,這些透明導電膜的製備方法主要包括蒸發法、濺射法等方法。蒸發法、濺射法屬於玻璃深加工方法,設備複雜、成本較高、不適合大規模生產。且,由於採用上述方法形成透明導電膜時,均需經過一個較高的退火過程,對透明導電膜的基底造成損害,無法在熔點較低的基底上形成,限制了透明導電膜的應用。 At present, the conventional transparent conductive film is a metal oxide film such as indium tin oxide or zinc oxide. The preparation methods of these transparent conductive films mainly include an evaporation method, a sputtering method and the like. The evaporation method and the sputtering method belong to the glass deep processing method, and the equipment is complicated, the cost is high, and it is not suitable for mass production. Moreover, since the transparent conductive film is formed by the above method, a higher annealing process is required, which damages the substrate of the transparent conductive film and cannot be formed on the substrate having a lower melting point, which limits the application of the transparent conductive film.
人們研究發現碳奈米管具有優異的導電特性,且人們可以通過從碳奈米管陣列中採用拉伸的方法製備出一種奈米碳管膜,該奈米碳管膜不但具有導電性,而且還具有一定的透光度。但該奈米碳管膜係直接從一碳奈米管陣列中拉取獲得的,該奈米碳管膜中的相鄰的碳奈米管之間的間隙比較小,從而使得該奈米碳管膜的透光度不夠高,不利於該奈米碳管膜的廣泛應用。 It has been found that carbon nanotubes have excellent electrical conductivity, and one can prepare a carbon nanotube membrane by stretching from a carbon nanotube array, which is not only electrically conductive, but also It also has a certain degree of transparency. However, the carbon nanotube film is directly taken from a carbon nanotube array, and the gap between adjacent carbon nanotubes in the carbon nanotube film is relatively small, thereby making the nanocarbon The transparency of the tube film is not high enough, which is not conducive to the wide application of the carbon nanotube film.
有鑒於此,確有必要提供一種製備具有較高透光度的奈米碳管膜。 In view of this, it is indeed necessary to provide a carbon nanotube film having a high transmittance.
一種奈米碳管膜,其包括複數碳奈米管線以及複數碳奈米管團簇,該複數碳奈米管線間隔設置;該複數碳奈米管團簇通過該複數碳奈米管線隔開,且位於相鄰的碳奈米管線之間的複數碳奈米管團簇間隔設置。 A carbon nanotube film comprising a plurality of carbon nanotube pipelines and a plurality of carbon nanotube clusters, the plurality of carbon nanotube pipelines being spaced apart; the plurality of carbon nanotube clusters being separated by the plurality of carbon nanotube pipelines And a plurality of carbon nanotube clusters located between adjacent carbon nanotube lines are spaced apart.
一種奈米碳管膜,其包括複數碳奈米管及複數孔隙,該複數碳奈米管組成複數碳奈米管線及複數碳奈米管團簇;該複數碳奈米管與該複數孔隙的面積比大於0,且小於等於1:19。 a carbon nanotube film comprising a plurality of carbon nanotubes and a plurality of pores, the plurality of carbon nanotubes forming a plurality of carbon nanotubes and a plurality of carbon nanotube clusters; the plurality of carbon nanotubes and the plurality of pores The area ratio is greater than 0 and less than or equal to 1:19.
與先前技術相比較,由本發明提供之奈米碳管膜包括複數間隔設置的碳奈米管線及複數碳奈米管團簇,且該複數碳奈米管團簇通過該複數碳奈米管線隔開,位於相鄰的碳奈米管線之間的碳奈米管團簇也係間隔設置的,所以該奈米碳管膜中形成複數孔隙,因此,該奈米碳管膜具有較高的透光度。 Compared with the prior art, the carbon nanotube film provided by the present invention comprises a plurality of carbon nanotube pipelines and a plurality of carbon nanotube clusters disposed at intervals, and the plurality of carbon nanotube clusters are separated by the plurality of carbon nanotube pipelines. The carbon nanotube clusters located between adjacent carbon nanotubes are also spaced apart, so that a plurality of pores are formed in the carbon nanotube membrane, and therefore, the carbon nanotube membrane has a high permeability. Luminosity.
10;20‧‧‧奈米碳管膜 10;20‧‧‧Nano carbon nanotube film
110‧‧‧碳奈米管陣列 110‧‧‧Carbon nanotube array
112‧‧‧基底 112‧‧‧Base
114‧‧‧膠帶 114‧‧‧ Tape
12‧‧‧碳奈米管線 12‧‧‧Carbon Pipeline
120‧‧‧初始奈米碳管膜 120‧‧‧Initial carbon nanotube film
122‧‧‧通孔 122‧‧‧through hole
124‧‧‧連接部 124‧‧‧Connecting Department
126‧‧‧延伸部 126‧‧‧Extension
128‧‧‧固定體 128‧‧‧ fixed body
130‧‧‧滴瓶 130‧‧‧Dripper
132‧‧‧乙醇 132‧‧‧Ethanol
14;24‧‧‧碳奈米管團簇 14;24‧‧‧Carbon nanotube clusters
242‧‧‧第二碳奈米管 242‧‧‧Second carbon nanotube
圖1為本發明提供之奈米碳管膜的製備流程圖。 1 is a flow chart showing the preparation of a carbon nanotube film provided by the present invention.
圖2為本發明提供之初始奈米碳管膜的掃描電鏡照片。 2 is a scanning electron micrograph of an initial carbon nanotube film provided by the present invention.
圖3為本發明提供之形成有一行通孔的初始奈米碳管膜的平面結構示意圖。 3 is a schematic plan view showing the structure of an initial carbon nanotube film formed with a row of through holes according to the present invention.
圖4為本發明提供之形成有多行通孔的初始奈米碳管膜的平面結構示意圖。 4 is a schematic plan view showing the structure of an initial carbon nanotube film formed with a plurality of rows of through holes according to the present invention.
圖5為本發明第一實施例提供之奈米碳管膜的結構示意圖,且該 奈米碳管膜中的碳奈米管團簇成陣列排列。 FIG. 5 is a schematic structural view of a carbon nanotube film according to a first embodiment of the present invention, and The carbon nanotube clusters in the carbon nanotube film are arranged in an array.
圖6為本發明第一實施例提供之奈米碳管膜的結構示意圖,且該奈米碳管膜中的碳奈米管團簇交錯排列。 FIG. 6 is a schematic structural view of a carbon nanotube film according to a first embodiment of the present invention, and the carbon nanotube clusters in the carbon nanotube film are staggered.
圖7係本發明第一實施例提供之奈米碳管膜的製備工藝流程圖。 Figure 7 is a flow chart showing the preparation process of the carbon nanotube film provided by the first embodiment of the present invention.
圖8係本發明第一實施例提供之形成有通孔的初始奈米碳管膜的平面結構示意圖。 Fig. 8 is a schematic plan view showing the structure of an initial carbon nanotube film formed with a through hole according to a first embodiment of the present invention.
圖9為圖8所示的形成有通孔的初始奈米碳管膜的部分光學顯微鏡照片。 Fig. 9 is a partial optical micrograph of the initial carbon nanotube film formed with a through hole shown in Fig. 8.
圖10為本發第一明實施例提供之奈米碳管膜的光學顯微鏡照片。 Figure 10 is an optical micrograph of a carbon nanotube film provided in the first embodiment of the present invention.
圖11為本發明第一實施例提供之奈米碳管膜與各種膜的透光度比較圖。 Figure 11 is a graph showing the transmittance of a carbon nanotube film and various films according to a first embodiment of the present invention.
圖12係本發明第二實施例提供之奈米碳管膜的結構示意圖。 Figure 12 is a schematic view showing the structure of a carbon nanotube film provided by a second embodiment of the present invention.
圖13係本發明第二實施例提供之奈米碳管膜的光學顯微鏡照片。 Figure 13 is an optical micrograph of a carbon nanotube film provided by a second embodiment of the present invention.
本發明提供一奈米碳管膜,該奈米碳管膜包括複數間隔設置的碳奈米管線以及複數碳奈米管團簇,該複數碳奈米管線與複數碳奈米管團簇通過凡得瓦爾力(Van der Waals Force)相互連接。該複數碳奈米管團簇通過該複數碳奈米管線隔開,且位於相鄰的兩個碳奈米管線之間的碳奈米管團簇間隔設置。 The invention provides a carbon nanotube film comprising a plurality of carbon nanotube pipelines disposed at intervals and a plurality of carbon nanotube clusters, wherein the plurality of carbon nanotube pipelines and the plurality of carbon nanotube clusters pass through Van der Waals Force is connected to each other. The plurality of carbon nanotube clusters are separated by the plurality of carbon nanotube lines, and the carbon nanotube clusters located between adjacent two carbon nanotube lines are spaced apart.
所述複數碳奈米管線基本沿第一方向延伸且相互間隔設置。優選地,該複數碳奈米管線平行且等間距設置,該複數碳奈米管線設置於一個平面內。每個碳奈米管線的直徑大於等於0.1微米,且 小於等於100微米。優選地,每個碳奈米管線的直徑大於等於5微米,且小於等於50微米。該複數碳奈米管線之間的間隔不限,優選地,相鄰的碳奈米管線之間的間距大於0.1毫米。所述複數碳奈米管線的直徑及間隔可以根據實際需要確定。優選地,該複數碳奈米管線的直徑基本相等。每個碳奈米管線包括複數第一碳奈米管,該複數第一碳奈米管基本沿所述第一方向擇優取向排列,即,該複數第一碳奈米管沿所述碳奈米管線的軸向擇優取向排列。位於所述碳奈米管線的軸向上的相鄰的第一碳奈米管通過凡得瓦爾力首尾相連。優選地,該複數碳奈米管的軸向基本與該碳奈米管線的軸向平行。其中,所述第一方向基本平行於所述碳奈米管線的軸向及所述第一碳奈米管的軸向。 The plurality of carbon nanotube lines extend substantially in a first direction and are spaced apart from each other. Preferably, the plurality of carbon nanotube lines are arranged in parallel and at equal intervals, and the plurality of carbon nanotube lines are disposed in one plane. Each carbon nanotube line has a diameter of 0.1 micron or more, and Less than or equal to 100 microns. Preferably, each carbon nanotube line has a diameter of 5 microns or more and 50 microns or less. The spacing between the plurality of carbon nanotube lines is not limited, and preferably, the spacing between adjacent carbon nanotube lines is greater than 0.1 mm. The diameter and spacing of the plurality of carbon nanotube lines can be determined according to actual needs. Preferably, the plurality of carbon nanotube lines are substantially equal in diameter. Each carbon nanotube line includes a plurality of first carbon nanotubes, the plurality of first carbon nanotubes being arranged substantially in a preferred orientation along the first direction, ie, the plurality of first carbon nanotubes along the carbon nanotube The axial orientation of the pipeline is aligned. Adjacent first carbon nanotubes located in the axial direction of the carbon nanotube line are connected end to end by van der Waals force. Preferably, the axial direction of the plurality of carbon nanotubes is substantially parallel to the axial direction of the carbon nanotube line. Wherein the first direction is substantially parallel to an axial direction of the carbon nanotube line and an axial direction of the first carbon nanotube.
所述複數碳奈米管團簇間隔設置,且搭接於相鄰的碳奈米管線之間,使得該奈米碳管膜具有自支撐特性,為一自支撐結構。所謂“自支撐”係指該奈米碳管膜不需要支撐體支撐就可以保持其固有的形狀。該複數碳奈米管團簇在第二方向上間隔設置,且通過所述複數碳奈米管線區分開。也可以說,位於該第二方向上的複數碳奈米管團簇通過該複數碳奈米管線連接在一起。位於第二方向上的複數碳奈米管團簇可以交錯排列,不成行排列,由此,通過所述複數碳奈米管線連接在第二方向上形成非直線形的導電通路。位於該第二方向上的複數碳奈米管團簇整齊排列成行,通過該複數碳奈米管線形成一連續的直線形導電通路。優選地,該複數碳奈米管團簇在該奈米碳管膜中呈陣列排布。其中,該第二方向與所述第一方向相交設置,優選地,該第二方向與第一方向垂直設置。每個碳奈米管團簇在所述第二方向上的長度基本與與該碳奈米管團簇相連的碳奈米管線的間距相等。所以,該碳奈米管 團簇在第二方向上的長度優選地大於0.1毫米。另外,位於相鄰的碳奈米管線之間的複數碳奈米管團簇間隔設置,即,該複數碳奈米管團簇在所述第一方向上間隔設置。優選地,相鄰的碳奈米管團簇在第一方向上的間距大於等於1毫米。 The plurality of carbon nanotube clusters are spaced apart and overlapped between adjacent carbon nanotubes, so that the carbon nanotube membrane has self-supporting properties and is a self-supporting structure. By "self-supporting" is meant that the carbon nanotube film retains its inherent shape without the support of a support. The plurality of carbon nanotube clusters are spaced apart in the second direction and are separated by the plurality of carbon nanotube lines. It can also be said that the plurality of carbon nanotube clusters located in the second direction are connected together by the plurality of carbon nanotube lines. The plurality of carbon nanotube clusters located in the second direction may be staggered and arranged in a row, whereby a non-linear conductive path is formed in the second direction by the plurality of carbon nanotube lines. The plurality of carbon nanotube clusters located in the second direction are aligned in a row, and a continuous linear conductive path is formed through the plurality of carbon nanotube lines. Preferably, the plurality of carbon nanotube clusters are arranged in an array in the carbon nanotube film. The second direction is disposed to intersect the first direction. Preferably, the second direction is perpendicular to the first direction. The length of each carbon nanotube cluster in the second direction is substantially equal to the spacing of the carbon nanotubes connected to the carbon nanotube cluster. Therefore, the carbon nanotube The length of the cluster in the second direction is preferably greater than 0.1 mm. In addition, the plurality of carbon nanotube clusters located between adjacent carbon nanotube lines are spaced apart, that is, the plurality of carbon nanotube clusters are spaced apart in the first direction. Preferably, the spacing of adjacent carbon nanotube clusters in the first direction is greater than or equal to 1 mm.
所述碳奈米管團簇包括複數第二碳奈米管,該複數第二碳奈米管通過凡得瓦爾力相互作用在一起。該複數第二碳奈米管的軸向可以基本平行於所述第一方向,即,該複數第二碳奈米管的軸向可以基本平行於所述碳奈米管線的軸向。該複數第二碳奈米管的軸向也可以與所述第一方向相交設置,因此,該碳奈米管團簇中的第二碳奈米管可以交叉設置形成網狀結構。 The carbon nanotube cluster includes a plurality of second carbon nanotubes that interact together by a van der Waals force. The axial direction of the plurality of second carbon nanotubes may be substantially parallel to the first direction, that is, the axial direction of the plurality of second carbon nanotubes may be substantially parallel to the axial direction of the carbon nanotube. The axial direction of the plurality of second carbon nanotubes may also be disposed to intersect the first direction, and therefore, the second carbon nanotubes in the carbon nanotube cluster may be disposed to form a network.
由此可見,所述奈米碳管膜包括複數碳奈米管,該複數碳奈米管分別形成所述複數碳奈米管線及複數碳奈米管團簇。優選地,該奈米碳管膜僅由碳奈米管組成。該奈米碳管膜還包括複數孔隙,該複數孔隙主要係由該奈米碳管膜中的複數碳奈米管線及複數碳奈米管團簇間隔設置形成的。所以,當該複數碳奈米管線及複數碳奈米管團簇有規律排列時,該複數孔隙也有規律排列。如,當所述複數碳奈米管團簇及碳奈米管線呈陣列排布時,該複數孔隙也會隨之呈陣列排布。該奈米碳管膜中的碳奈米管線與碳奈米管團簇的面積之和與所述複數孔隙的面積的比值大於0,且小於等於1:19。也可以說,該奈米碳管膜中的複數碳奈米管與所述複數孔隙的面積比大於0,且小於等於1:19。優選地,該奈米碳管膜中的碳奈米管的面積與該複數孔隙的面積比大於0,且小於等於1:49。所以,該奈米碳管膜的透光度大於等於95%,優選地,該奈米碳管膜的透光度大於等於98%。該複數碳奈米管線沿 第一方向延伸,從而使得該奈米碳管膜在第一方向上形成一第一導電通路;該複數碳奈米管團簇可以在第二方向上形成一第二導電通路;從而使得該奈米碳管膜為導電異向性膜,且在第一方向及第二方向上具有不同的導電異向性。該奈米碳管膜在第二方向上的電阻與其在第一方向上的電阻的比值大於等於10。優選地,該奈米碳管膜在第二方向上的電阻大於等於其在第一方向上的電阻的20倍。如,該奈米碳管膜在第二方向上的電阻可以高於其在第一方向上的電阻的50倍。另外,該奈米碳管膜中的碳奈米管線通過其中的碳奈米管團簇連接一起,從而使得該奈米碳管膜具有較好的強度及穩定性,不易破壞。 It can be seen that the carbon nanotube film comprises a plurality of carbon nanotubes, and the plurality of carbon nanotubes respectively form the plurality of carbon nanotubes and the plurality of carbon nanotube clusters. Preferably, the carbon nanotube membrane consists solely of carbon nanotubes. The carbon nanotube film further includes a plurality of pores formed mainly by a plurality of carbon nanotube lines and a plurality of carbon nanotube clusters in the carbon nanotube film. Therefore, when the plurality of carbon nanotubes and the plurality of carbon nanotube clusters are regularly arranged, the plurality of pores are also regularly arranged. For example, when the plurality of carbon nanotube clusters and carbon nanotube pipelines are arranged in an array, the plurality of pores are also arranged in an array. The ratio of the sum of the areas of the carbon nanotubes and the carbon nanotube clusters in the carbon nanotube membrane to the area of the plurality of pores is greater than 0 and less than or equal to 1:19. It can also be said that the area ratio of the plurality of carbon nanotubes in the carbon nanotube film to the plurality of pores is greater than 0 and less than or equal to 1:19. Preferably, the area ratio of the area of the carbon nanotubes in the carbon nanotube film to the complex pores is greater than 0 and less than or equal to 1:49. Therefore, the transmittance of the carbon nanotube film is 95% or more, and preferably, the transmittance of the carbon nanotube film is 98% or more. The plurality of carbon nanotube pipelines Extending in a first direction such that the carbon nanotube film forms a first conductive path in a first direction; the plurality of carbon nanotube clusters can form a second conductive path in a second direction; thereby The carbon nanotube film is a conductive anisotropic film and has different conductive anisotropies in the first direction and the second direction. The ratio of the electric resistance of the carbon nanotube film in the second direction to the electric resistance in the first direction is 10 or more. Preferably, the carbon nanotube film has a resistance in the second direction that is greater than or equal to 20 times its resistance in the first direction. For example, the carbon nanotube film may have a resistance in the second direction that is 50 times higher than its resistance in the first direction. In addition, the carbon nanotube pipelines in the carbon nanotube membrane are connected together by the carbon nanotube clusters therein, so that the carbon nanotube membrane has good strength and stability and is not easily damaged.
需要說明的係,該奈米碳管膜中的碳奈米管線及碳奈米管團簇的周圍還存在有少量的碳奈米管,但這些碳奈米管的存在基本上不會影響該奈米碳管膜的性質。 It should be noted that there are a small amount of carbon nanotubes around the carbon nanotube pipeline and the carbon nanotube cluster in the carbon nanotube membrane, but the presence of these carbon nanotubes does not substantially affect the The nature of the carbon nanotube film.
請參閱圖1,本發明上述奈米碳管膜之製備方法包括以下步驟:S10,提供一初始奈米碳管膜,該初始奈米碳管膜包括複數碳奈米管,該複數碳奈米管通過凡得瓦爾力首尾相連且沿第一方向擇優取向延伸;S20,圖案化所述初始奈米碳管膜,使所述初始奈米碳管膜在所述第一方向上形成至少一行通孔,且每行上至少有兩個間隔設置的通孔;以及S30,採用溶劑處理所述形成有至少一行通孔的初始奈米碳管膜,使該形成有至少一行通孔的初始奈米碳管膜收縮。 Referring to FIG. 1, a method for preparing the above carbon nanotube film of the present invention comprises the following steps: S10, providing an initial carbon nanotube film, the initial carbon nanotube film comprising a plurality of carbon nanotubes, the plurality of carbon nanotubes The tube is connected end to end by van der Waals force and extends in a preferred orientation in a first direction; S20, patterning the initial carbon nanotube film such that the initial carbon nanotube film forms at least one row in the first direction a hole, and at least two spaced-apart through holes in each row; and S30, treating the initial carbon nanotube film formed with at least one row of through holes with a solvent, so that the initial nanometer having at least one row of through holes is formed The carbon tube film shrinks.
請參閱圖2,步驟S10中的初始奈米碳管膜中的碳奈米管沿第一方 向擇優取向延伸。該初始奈米碳管膜可以通過從一碳奈米管陣列中拉伸而獲得。具體地,該初始奈米碳管膜之製備方法包括以下步驟:S11,提供一碳奈米管陣列,且該碳奈米管陣列包括複數彼此平行的碳奈米管;以及S12,從所述碳奈米管陣列中選定一定寬度的碳奈米管片段,並拉取該具有一定寬度的碳奈米管片段得到所述初始奈米碳管膜。 Referring to FIG. 2, the carbon nanotubes in the initial carbon nanotube film in step S10 are along the first side. Extend to the preferred orientation. The initial carbon nanotube film can be obtained by stretching from an array of carbon nanotubes. Specifically, the method for preparing the initial carbon nanotube film comprises the steps of: S11, providing a carbon nanotube array, and the carbon nanotube array comprises a plurality of carbon nanotubes parallel to each other; and S12, from A carbon nanotube tube segment of a certain width is selected in the carbon nanotube array, and the carbon nanotube tube segment having a certain width is pulled to obtain the initial carbon nanotube film.
其中,優選地,所述碳奈米管陣列為一超順排碳奈米管陣列,即該碳奈米管陣列包括複數基本相互平行的碳奈米管。該碳奈米管陣列形成於一基底,且該碳奈米管陣列中的碳奈米管基本垂直於該基底。在上述拉伸過程中,該碳奈米管陣列中的選定的碳奈米管在拉力作用下沿拉伸方向逐漸脫離基底的同時,由於凡得瓦爾力作用,該選定的碳奈米管分別與碳奈米管陣列中的其他碳奈米管通過凡得瓦爾力首尾相連地連續地被拉出形成所述初始奈米碳管膜。該初始奈米碳管膜中的碳奈米管的延伸方向基本平行於奈米碳管膜的拉伸方向。因此,該初始奈米碳管膜係由碳奈米管組成,且通過碳奈米管之間的凡得瓦爾力的作用,使得該初始奈米碳管膜具有自支撐特性,為一自支撐膜。該初始奈米碳管膜中的碳奈米管之間會形成複數微孔,該微孔的有效直徑小於100奈米。 Wherein, preferably, the carbon nanotube array is a super-sequential carbon nanotube array, that is, the carbon nanotube array comprises a plurality of carbon nanotubes substantially parallel to each other. The carbon nanotube array is formed on a substrate, and the carbon nanotubes in the carbon nanotube array are substantially perpendicular to the substrate. During the above stretching process, the selected carbon nanotubes in the carbon nanotube array are gradually separated from the substrate in the stretching direction under the tensile force, and the selected carbon nanotubes are respectively removed due to the van der Waals force. The initial carbon nanotube film is formed by continuously pulling out the other carbon nanotubes in the carbon nanotube array by end-to-end connection. The carbon nanotubes in the initial carbon nanotube film extend substantially parallel to the direction of stretching of the carbon nanotube film. Therefore, the initial carbon nanotube film system is composed of a carbon nanotube tube, and the initial carbon nanotube film has self-supporting property through a van der Waals force between the carbon nanotube tubes, which is a self-supporting property. membrane. A plurality of micropores are formed between the carbon nanotubes in the initial carbon nanotube film, and the effective diameter of the micropores is less than 100 nm.
所述步驟S20對初始奈米碳管膜進行圖案化處理的目的係在所述初始奈米碳管膜上沿第一方向上形成成行排列且間隔設置的通孔。該步驟可以採用雷射照射處理或電子束照射處理等方法在所述初始奈米碳管膜上形成所述複數通孔。當該步驟S20採用雷射照射法對該預製碳奈米管進行圖案化處理時,該步驟S20具體可以 包括以下分步驟:首先,提供一雷射器,該雷射器的雷射光束的照射路徑可通過電腦程式控制。其次,將所述待形成複數通孔的奈米碳管膜的形狀輸入電腦程式中,以便控制雷射器中的雷射光束的照射路徑,在所述初始奈米碳管膜上燒蝕形成複數通孔。然後,開啟雷射器,採用雷射光束照射所述初始奈米碳管膜,在該初始奈米碳管膜上形成所述複數通孔。可以理解,還可以通過固定雷射光束,移動所述初始奈米碳管膜使雷射光束照射該初始奈米碳管膜的表面,控制該初始奈米碳管膜的運動路徑,在該初始奈米碳管膜上燒蝕形成複數通孔。其中,所述雷射光束的功率密度為10000-100000瓦/平方毫米,掃描速度為800-1500毫米/秒。優選地,該雷射光束的功率密度為70000-80000瓦/平方毫米,掃描速度為1000-1200毫米/秒。 The step S20 of patterning the initial carbon nanotube film is performed to form through holes arranged in a row and spaced apart in the first direction on the initial carbon nanotube film. In this step, the plurality of via holes may be formed on the initial carbon nanotube film by a laser irradiation treatment or an electron beam irradiation treatment. When the pre-made carbon nanotube is patterned by the laser irradiation method in step S20, the step S20 may specifically The following sub-steps are included: First, a laser is provided, and the illumination path of the laser beam of the laser can be controlled by a computer program. Next, the shape of the carbon nanotube film to be formed into the plurality of through holes is input into a computer program to control the irradiation path of the laser beam in the laser, and ablation is formed on the initial carbon nanotube film. Multiple through holes. Then, the laser is turned on, and the initial carbon nanotube film is irradiated with a laser beam to form the plurality of through holes on the initial carbon nanotube film. It can be understood that, by fixing the laser beam, the initial carbon nanotube film is moved to irradiate the laser beam to the surface of the initial carbon nanotube film, and the movement path of the initial carbon nanotube film is controlled. The carbon nanotube film is ablated to form a plurality of through holes. Wherein, the laser beam has a power density of 10,000-100,000 watts/mm 2 and a scanning speed of 800-1500 mm/sec. Preferably, the laser beam has a power density of 70,000 to 80,000 watts per square millimeter and a scanning speed of 1000 to 1200 mm/second.
所述步驟S20中形成的通孔的形狀可以為四邊形、圓形、橢圓形或三角形等圖形。優選地,該四邊形具有至少一對平行邊,如,平行四邊形、梯形、長方形、菱形等。更優選地,該通孔的形成為長方形。當長方形的寬度比較小時,可以認為該長方形為一直線,即可以認為該通孔的形狀為直線形。所述通孔的有效直徑大於所述初始奈米碳管膜中的微孔的有效直徑。優選地,該通孔的有效直徑大於等於0.1毫米。相鄰的通孔之間的間距大於所述初始奈米碳管膜中的微孔的有效直徑。優選地,該相鄰通孔之間的間距大於等於0.1毫米。所述通孔的形狀、有效直徑以及相鄰的通孔之間的間距可以根據實際需要確定。 The shape of the through hole formed in the step S20 may be a quadrilateral, a circular shape, an elliptical shape or a triangular shape. Preferably, the quadrilateral has at least one pair of parallel sides, such as a parallelogram, a trapezoid, a rectangle, a diamond, or the like. More preferably, the through hole is formed in a rectangular shape. When the width of the rectangle is relatively small, the rectangle can be considered to be a straight line, that is, the shape of the through hole can be considered to be a straight line. The effective diameter of the through hole is larger than the effective diameter of the micro hole in the initial carbon nanotube film. Preferably, the through hole has an effective diameter of 0.1 mm or more. The spacing between adjacent through holes is greater than the effective diameter of the micro holes in the initial carbon nanotube film. Preferably, the spacing between the adjacent through holes is greater than or equal to 0.1 mm. The shape of the through hole, the effective diameter, and the spacing between adjacent through holes can be determined according to actual needs.
該步驟S20中對所述初始奈米碳管膜進行圖案化處理,在該初始奈米碳管膜上形成的通孔可以按照下面的幾種方式分佈: The initial carbon nanotube film is patterned in the step S20, and the through holes formed on the initial carbon nanotube film can be distributed in the following manners:
(1)請參閱圖3,在所述初始奈米碳管膜120上形成複數間隔設置的通孔122,該複數間隔設置的通孔122在該初始奈米碳管膜中沿所述第一方向X排列成一行。其中,該第一方向X基本平行於該初始奈米碳管膜120中的碳奈米管的軸向延伸方向。該複數通孔將該初始奈米碳管膜120分成複數連接部124以及兩個延伸部126,該初始奈米碳管膜的連接部124為同一行中相鄰的通孔122之間的部分,也就係說,該初始奈米碳管膜120的連接部124間隔設置且通過通孔122隔開,並與該複數通孔122交替排布。該初始奈米碳管膜120的兩個延伸部126指的係該初始奈米碳管膜120中除了所述連接部124外的其他部分,且分別位於所述複數連接部124的兩側。也可以說,在與第一方向X相交的第二方向Y上,該兩個延伸部126通過該複數連接部124隔開。所以,該複數連接部124與兩個延伸部126係一體結構,該兩個延伸部126通過該複數連接部124連接在一起。優選地,該第二方向Y垂直於第一方向X。每個延伸部126基本沿所述第一方向X連續延伸。 (1) Referring to FIG. 3, a plurality of spaced-apart vias 122 are formed in the initial carbon nanotube film 120, and the plurality of spaced-apart vias 122 are along the first in the initial carbon nanotube film. The directions X are arranged in a line. Wherein, the first direction X is substantially parallel to the axial extension direction of the carbon nanotubes in the initial carbon nanotube film 120. The plurality of through holes divide the initial carbon nanotube film 120 into a plurality of connecting portions 124 and two extending portions 126, and the connecting portions 124 of the initial carbon nanotube film are portions between adjacent through holes 122 in the same row. That is, the connecting portions 124 of the initial carbon nanotube film 120 are spaced apart and spaced apart by the through holes 122, and alternately arranged with the plurality of through holes 122. The two extensions 126 of the initial carbon nanotube film 120 refer to other portions of the initial carbon nanotube film 120 other than the connecting portion 124, and are located on both sides of the plurality of connecting portions 124, respectively. It can also be said that the two extensions 126 are separated by the plurality of connecting portions 124 in the second direction Y intersecting the first direction X. Therefore, the plurality of connecting portions 124 are integrally formed with the two extending portions 126, and the two extending portions 126 are connected together by the plurality of connecting portions 124. Preferably, the second direction Y is perpendicular to the first direction X. Each extension 126 extends substantially continuously along the first direction X.
(2)請參閱圖4,在所述初始奈米碳管膜120上形成複數通孔122,該複數通孔122沿所述第一方向X排列成多行,且位於同一行中的通孔122沿所述第一方向X間隔排列。該複數通孔122在所述第二方向Y上可以交錯設置。所謂“交錯設置”指的係,該複數通孔122在第二方向Y上沒有成列排布。可以理解,所述複數通孔122也可以沿該第二方向Y排列成多列,且位於同一列上的通孔122沿該第二方向Y間隔排列,所以,該複數通孔122呈陣列狀,行列排布。即,該複數通孔122在該初始奈米碳管膜120上排列成多行多列。 (2) Referring to FIG. 4, a plurality of through holes 122 are formed in the initial carbon nanotube film 120, and the plurality of through holes 122 are arranged in a plurality of rows along the first direction X, and the through holes are in the same row. 122 are spaced apart along the first direction X. The plurality of through holes 122 may be staggered in the second direction Y. By "staggered arrangement" is meant that the plurality of through holes 122 are not arranged in a row in the second direction Y. It can be understood that the plurality of through holes 122 may be arranged in a plurality of columns along the second direction Y, and the through holes 122 on the same column are arranged along the second direction Y. Therefore, the plurality of through holes 122 are arranged in an array. , ranks and ranks. That is, the plurality of through holes 122 are arranged in a plurality of rows and columns on the initial carbon nanotube film 120.
該複數通孔122將該初始奈米碳管膜120分成複數連接部124及複數延伸部126。該複數連接部124位於同一行中相鄰的通孔122之間,該複數連接部124的排列方式與該複數通孔122的排列方式相同,同一行的連接部124沿第一方向X間隔設置,並通過同一行的通孔122隔開。每個連接部124在第二方向Y上的長度等於其相鄰的通孔122在第二方向Y上的長度,每個連接部124沿第一方向上的長度基本等於與其位於同一行並與其相鄰的兩個通孔122之間的間距。所述複數延伸部126在第一方向X上係一連續的整體,且位於相鄰行的通孔122及所述初始奈米碳管膜120的連接部124之間。每個延伸部126在第二方向Y上的長度為其相鄰兩行的通孔122在第二方向Y上的間距,且將與其相鄰的兩行中的複數連接部124隔開。同樣地,該複數連接部124與該複數延伸部126為一體結構,該複數延伸部126通過該複數連接部124連接在一起。優選地,每個通孔122在第一方向X上的有效長度大於其相鄰的通孔122在第二方向Y上的間距。 The plurality of through holes 122 divide the initial carbon nanotube film 120 into a plurality of connecting portions 124 and a plurality of extending portions 126. The plurality of connecting portions 124 are located between adjacent through holes 122 in the same row. The plurality of connecting portions 124 are arranged in the same manner as the plurality of through holes 122. The connecting portions 124 of the same row are arranged along the first direction X. And separated by through holes 122 in the same row. The length of each connecting portion 124 in the second direction Y is equal to the length of its adjacent through hole 122 in the second direction Y, and the length of each connecting portion 124 in the first direction is substantially equal to the same line and The spacing between adjacent two through holes 122. The plurality of extensions 126 are continuous in a first direction X and are located between the through holes 122 of adjacent rows and the connecting portion 124 of the initial carbon nanotube film 120. The length of each of the extensions 126 in the second direction Y is the spacing of the adjacent two rows of through holes 122 in the second direction Y, and will separate the plurality of connections 124 in the two rows adjacent thereto. Similarly, the plurality of connecting portions 124 and the plurality of extending portions 126 are integrally formed, and the plurality of extending portions 126 are connected together by the plurality of connecting portions 124. Preferably, the effective length of each of the through holes 122 in the first direction X is greater than the spacing of the adjacent through holes 122 in the second direction Y.
需要說明的係,本文所謂的“位於同一行的通孔”指的係至少有一條基本平行於所述第一方向X的直線可以同時貫穿該位於同一行中的通孔;本文中所謂的“位於同一列中的通孔”指的係至少有一條基本平行於所述第二方向Y的直線可以同時貫穿該位於同一列中的通孔。所述初始奈米碳管膜120中的連接部124的排列方式與該初始奈米碳管膜中的通孔的排列方式基本相同。由於受到製備工藝的影響,每個通孔的周圍可能會有少量碳奈米管毛刺存在,從而使得通孔的邊緣存在參差不齊的現象。 It should be noted that the term "through holes in the same row" as used herein means that at least one straight line substantially parallel to the first direction X can penetrate through the through holes in the same row at the same time; The through holes in the same column mean that at least one straight line substantially parallel to the second direction Y can simultaneously penetrate the through holes in the same column. The arrangement of the connecting portions 124 in the initial carbon nanotube film 120 is substantially the same as the arrangement of the through holes in the initial carbon nanotube film. Due to the influence of the preparation process, a small amount of carbon nanotube burrs may exist around each through hole, so that the edges of the through holes are jagged.
在步驟S30中,所述圖案化的初始奈米碳管膜優選地懸空設置。 該步驟S30可以為,將所述溶劑滴落或噴灑在懸空設置的形成有複數通孔的初始奈米碳管膜的表面,以浸潤該具有至少一行通孔的初始奈米碳管膜,使該具有至少一行通孔的初始奈米碳管膜收縮。由於該初始奈米碳管膜中的每個延伸部中的碳奈米管首尾相鄰且基本沿第一方向排列,且每個延伸部在第一方向上為一個連續的整體,所以,在表面張力的作用下,該初始奈米碳管膜中的複數延伸部收縮分別形成複數碳奈米管線,也就係說,該初始奈米碳管膜的每個延伸部向其中心收縮形成一個碳奈米管線,同時使得位於該延伸部兩側的通孔的有效直徑增大,從而形成複數間隔設置的碳奈米管線。同時,每個延伸部在收縮成碳奈米管線的過程中會對其鄰近的連接部產生一個拉力,使得該連接部形成所述碳奈米管團簇,從而形成所述奈米碳管膜,使得該奈米碳管膜包括複數間隔的碳奈米管線,及被該複數碳奈米管線隔開的複數碳奈米管團簇。因此,該奈米碳管膜中相鄰的碳奈米管線之間的間距大於其對應的初始奈米碳管膜上相鄰的延伸部之間夾持的通孔在第二方向上的長度,大於0.1毫米;且每個碳奈米管線由複數通過凡得瓦爾力首尾相連且基本沿同一方向延伸的碳奈米管構成,該複數碳奈米管基本沿第一方向延伸。該複數碳奈米管團簇將相鄰的碳奈米管線通過凡得瓦爾力連接在一起形成所述奈米碳管膜。 In step S30, the patterned initial carbon nanotube film is preferably suspended. The step S30 may be that the solvent is dripped or sprayed on the surface of the initial carbon nanotube film formed with a plurality of through holes, so as to infiltrate the initial carbon nanotube film having at least one row of through holes, so that The initial carbon nanotube film having at least one row of through holes shrinks. Since the carbon nanotubes in each of the initial carbon nanotube films are adjacent to each other and are arranged substantially in the first direction, and each of the extensions is a continuous whole in the first direction, Under the action of surface tension, the multiple extensions in the initial carbon nanotube film respectively form a plurality of carbon nanotubes, that is, each extension of the initial carbon nanotube film shrinks toward its center to form a The carbon nanotube line simultaneously increases the effective diameter of the through holes on both sides of the extension to form a plurality of carbon nanotube lines disposed at intervals. At the same time, each extension portion generates a tensile force to its adjacent connection portion during contraction into the carbon nanotube line, so that the connection portion forms the carbon nanotube cluster to form the carbon nanotube film. The carbon nanotube membrane comprises a plurality of spaced carbon nanotube lines and a plurality of carbon nanotube clusters separated by the plurality of carbon nanotube lines. Therefore, the spacing between adjacent carbon nanotube lines in the carbon nanotube film is greater than the length of the through hole between the adjacent extensions on the corresponding initial carbon nanotube film in the second direction. , greater than 0.1 mm; and each carbon nanotube line is composed of a plurality of carbon nanotubes that are connected end to end by van der Waals and extend substantially in the same direction, and the plurality of carbon nanotubes extend substantially in the first direction. The plurality of carbon nanotube clusters connect adjacent carbon nanotube lines together by van der Waals to form the carbon nanotube membrane.
根據所述溶劑的揮發性的不同,該溶劑對所述初始奈米碳管膜的表面張力也不同,該初始奈米碳管膜的延伸部在收縮成碳奈米管線的過程中對其相鄰的連接部產生的拉力的大小也不同,從而使得該初始奈米碳管膜的連接部中的碳奈米管的排列方式不同,進而使得所述碳奈米管團簇的結構也不同。 Depending on the volatility of the solvent, the surface tension of the solvent to the initial carbon nanotube film is also different, and the extension of the initial carbon nanotube film is in the process of shrinking into a carbon nanotube line. The magnitude of the tensile force generated by the adjacent connecting portions is also different, so that the arrangement of the carbon nanotubes in the joint portion of the initial carbon nanotube film is different, and the structure of the carbon nanotube cluster is also different.
當所述溶劑為有機溶劑,乙醇、甲醇、丙酮、二氯乙烷或氯仿等具有較高揮發性的溶劑時,對該初始奈米碳管膜的表面張力就比較大,該初始奈米碳管膜的延伸部在收縮成碳奈米管線的過程中對其相鄰的連接部產生的拉力就比較大,可以使得該連接部中的碳奈米管的由基本沿第一方向延伸轉變為與該第一方向相交的方向延伸,形成第二碳奈米管;同時在表面張力的作用下,每個連接部中的碳奈米管會收縮形成一網狀結構,該網狀結構即為所述碳奈米管團簇。所以,該複數連接部形成複數具有網狀結構的碳奈米管團簇。優選地,該第二碳奈米管的軸向與所述第一方向具有較大的第一夾角,且該第一夾角大於等於45度,且小於等於90度。 When the solvent is an organic solvent, a solvent having a higher volatility such as ethanol, methanol, acetone, dichloroethane or chloroform, the surface tension of the initial carbon nanotube film is relatively large, and the initial nanocarbon is used. The extension of the tubular film is relatively large in the process of contracting into the carbon nanotube pipeline, and the tensile force generated by the extension of the tubular portion in the connecting portion can be changed from the first direction to the first direction. Extending in a direction intersecting the first direction to form a second carbon nanotube; and under the action of surface tension, the carbon nanotubes in each joint shrink to form a network structure, and the mesh structure is The carbon nanotube cluster. Therefore, the plurality of connecting portions form a plurality of carbon nanotube clusters having a network structure. Preferably, the axial direction of the second carbon nanotube has a larger first angle with the first direction, and the first angle is greater than or equal to 45 degrees and less than or equal to 90 degrees.
當所述溶劑為水,或具有一定濃度的水與有機溶劑的混合溶液時,該溶劑對該初始奈米碳管膜的表面張力相對比較小,該初始奈米碳管膜的延伸部在收縮成碳奈米管線的過程中對其相鄰的連接部產生的拉力相對比較小,對該初始奈米碳管膜的連接部中的碳奈米管的拉力就比較小,從而使得該複數連接部中的碳奈米管的軸向基本不發生改變或改變較小,形成複數碳奈米管團簇,此時,該碳奈米管團簇中的碳奈米管的軸向基本平行於所述碳奈米管線中的碳奈米管的軸向及所述第一方向,或該碳奈米管團簇中的碳奈米管的軸向與該碳奈米管線中的碳奈米管及第一方向具有較小的第二夾角,且該第二夾角小於等於30度。優選地,該夾角小於等於15度。如,當溶劑為水時,所述初始奈米碳管膜的連接部中的碳奈米管的排列方向基本不發生改變,從而使得該碳奈米管團簇中的碳奈米管的排列方向基本平行於所述第一方向。 When the solvent is water, or has a certain concentration of a mixed solution of water and an organic solvent, the surface tension of the solvent to the initial carbon nanotube film is relatively small, and the extension of the initial carbon nanotube film is shrinking. The tensile force generated by the adjacent connecting portion in the process of forming the carbon nanotube line is relatively small, and the pulling force of the carbon nanotube in the joint portion of the initial carbon nanotube film is relatively small, thereby making the plural connection The axial direction of the carbon nanotubes in the portion is substantially unchanged or changed little to form a plurality of carbon nanotube clusters. At this time, the axial direction of the carbon nanotubes in the carbon nanotube clusters is substantially parallel to The axial direction of the carbon nanotubes in the carbon nanotube line and the first direction, or the axial direction of the carbon nanotubes in the carbon nanotube cluster and the carbon nanotubes in the carbon nanotube pipeline The tube and the first direction have a smaller second angle, and the second angle is less than or equal to 30 degrees. Preferably, the angle is less than or equal to 15 degrees. For example, when the solvent is water, the arrangement direction of the carbon nanotubes in the joint portion of the initial carbon nanotube film is substantially unchanged, thereby arranging the carbon nanotubes in the carbon nanotube cluster. The direction is substantially parallel to the first direction.
可以理解,當步驟S20中的通孔呈多行排布時,在所述奈米碳管膜中,由所述初始奈米碳管膜的延伸部形成的複數碳奈米管線基本平行設置。另,當該初始奈米碳管膜中的通孔呈多行多列排布時,所述初始奈米碳管膜中的複數延伸部會形成複數碳奈米管線,該複數碳奈米管線沿第一方向軸向延伸,且沿第二方向相互平行且間隔設置;且該初始奈米碳管膜中的複數連接部會形成複數碳奈米管團簇,該碳奈米管團簇會沿著所述第二方向通過所述碳奈米管線搭接在一起,且沿第一方向間隔設置。所以,此時,該奈米碳管膜中的複數碳奈米管線相互平行地沿第一方向延伸且沿第二方向間隔設置,形成複數間隔設置的第一導電通路;該奈米碳管膜中的複數碳奈米管團簇沿所述第一方向間隔設置,並沿所述第二方向通過碳奈米管線連接形成所述複數間隔設置的第二導電通路。 It can be understood that when the through holes in step S20 are arranged in a plurality of rows, in the carbon nanotube film, the plurality of carbon nanotube lines formed by the extension of the initial carbon nanotube film are arranged substantially in parallel. In addition, when the through holes in the initial carbon nanotube film are arranged in a plurality of rows and columns, the plurality of extensions in the initial carbon nanotube film form a plurality of carbon nanotubes, and the plurality of carbon nanotubes Extending axially along the first direction and parallel and spaced apart from each other in the second direction; and the plurality of junctions in the initial carbon nanotube film form a plurality of carbon nanotube clusters, the carbon nanotube clusters The carbon nanotubes are lapped together along the second direction and spaced apart in a first direction. Therefore, at this time, the plurality of carbon nanotube lines in the carbon nanotube film extend parallel to each other in the first direction and are spaced apart in the second direction to form a plurality of first conductive paths disposed at intervals; the carbon nanotube film The plurality of carbon nanotube clusters are spaced apart in the first direction, and connected in the second direction through the carbon nanotube line to form the plurality of second conductive paths disposed at intervals.
可以理解,通過控制沿第二方向排列的通孔之間的間距以及通孔的形狀可以控制所述碳奈米管線的直徑;通過控制位於第二方向上的相鄰通孔之間的間距以及通孔的寬度可以控制相鄰的碳奈米管線之間的間距。當所述通孔為長方形,該通孔的在第二方向的長度分別相等,且位於同一列上的相鄰通孔之間的間距相等時,所述複數碳奈米管線的直徑相等,且相鄰的碳奈米管線之間的間距也相等;進一步,當該複數通孔的在第一方向的長度分別相等,所述複數碳奈米管團簇基本沿第二方向排列,甚至該複數碳奈米管團簇的形狀基本相同。因此,本發明提供之奈米碳管膜之製備方法可以有效地、簡單地控制其中的碳奈米管線之間的間距及碳奈米管線的直徑。 It can be understood that the diameter of the carbon nanotube line can be controlled by controlling the spacing between the through holes arranged in the second direction and the shape of the through hole; by controlling the spacing between adjacent through holes in the second direction and The width of the through holes can control the spacing between adjacent carbon nanotube lines. When the through holes are rectangular, the lengths of the through holes in the second direction are equal, and the spacing between adjacent through holes on the same column is equal, the diameters of the plurality of carbon nanotubes are equal, and The spacing between adjacent carbon nanotube lines is also equal; further, when the lengths of the plurality of through holes are equal in the first direction, the plurality of carbon nanotube clusters are arranged substantially in the second direction, even the plural The shape of the carbon nanotube clusters is substantially the same. Therefore, the preparation method of the carbon nanotube film provided by the present invention can effectively and simply control the spacing between the carbon nanotube lines and the diameter of the carbon nanotube line.
在其他條件相同,在第一方向上的通孔數量基本不影響所述奈米碳管膜在第一方向上的電阻。在第一方向上的通孔數量越多,所述奈米碳管膜在第二方向上的電阻可能就越高;在第二方向上的通孔數量越少,該奈米碳管膜在第二方向上的電阻可能就越低。在其他條件相同,在第二方向上的通孔數量基本不影響該奈米碳管膜在第二方向上的電阻。在第二方向上的通孔數量越多,所述奈米碳管膜在第一方向上的電阻就越高;當第二方向上的通孔數量越少,所述奈米碳管膜在第一方向上的電阻就越低。因此,可以通過調整所述通孔的數量來改變所述奈米碳管膜的電阻,尤其係改變該奈米碳管膜的導電異向性,也就係說,可以根據對所述奈米碳管膜的電阻的需求來進行步驟S20。 Under otherwise identical conditions, the number of vias in the first direction does not substantially affect the resistance of the carbon nanotube film in the first direction. The more the number of through holes in the first direction, the higher the resistance of the carbon nanotube film in the second direction may be; the smaller the number of through holes in the second direction, the smaller the carbon nanotube film is The resistance in the second direction may be lower. Under otherwise identical conditions, the number of vias in the second direction does not substantially affect the resistance of the carbon nanotube film in the second direction. The more the number of through holes in the second direction, the higher the resistance of the carbon nanotube film in the first direction; and the smaller the number of through holes in the second direction, the carbon nanotube film is The lower the resistance in the first direction. Therefore, the resistance of the carbon nanotube film can be changed by adjusting the number of the through holes, in particular, the conductivity anisotropy of the carbon nanotube film is changed, that is, according to the pair of nanoparticles The demand for the resistance of the carbon tube film is performed in step S20.
需要說明的係,通孔的相關參數影響該奈米碳管膜的導電性。其中,假定所述初始奈米碳管膜上的通孔均勻分佈,且每個通孔為長方形,每個通孔在第一方向上的長度為a,每個通孔在第二方向上的長度為b,相鄰的通孔在第一方向上的間距為c,相鄰的通孔在第二方向上的間距為d。優選地,參數a大於參數d。其中,所述參數b相對於參數a相當小時,參數b可以認為係0,該通孔可以被認為為直線。具體地,通孔的相關參數對奈米碳管膜的電阻及導電異向性的影響如下: It should be noted that the relevant parameters of the through holes affect the conductivity of the carbon nanotube film. Wherein, it is assumed that the through holes on the initial carbon nanotube film are evenly distributed, and each of the through holes is rectangular, each of the through holes has a length a in the first direction, and each through hole is in the second direction The length is b, the spacing of adjacent through holes in the first direction is c, and the spacing of adjacent through holes in the second direction is d. Preferably, the parameter a is greater than the parameter d. Wherein, the parameter b is relatively small with respect to the parameter a, and the parameter b can be regarded as 0, and the through hole can be regarded as a straight line. Specifically, the influence of the relevant parameters of the through hole on the electrical resistance and the conductive anisotropy of the carbon nanotube film is as follows:
(1)當通孔的參數c和d固定,改變參數a和b時,該奈米碳管膜在第二方向與第一方向上的電阻的比值隨著參數a和b的比值(a/b)的增大而變大。也就係說,該奈米碳管膜的導電異向性與參數a和b的比值成正比。 (1) When the parameters c and d of the through hole are fixed, and the parameters a and b are changed, the ratio of the resistance of the carbon nanotube film in the second direction to the first direction is a function of the ratio of the parameters a and b (a/). b) increases and becomes larger. That is to say, the conductivity anisotropy of the carbon nanotube film is proportional to the ratio of the parameters a and b.
(2)當通孔的參數a和c固定,改變參數b和d時,該奈米碳管膜 在第一方向的電阻基本隨著參數b與d的比值(b/d)的增大而變大。 (2) When the parameters a and c of the through hole are fixed and the parameters b and d are changed, the carbon nanotube film The resistance in the first direction substantially increases as the ratio (b/d) of the parameters b and d increases.
(3)當通孔的參數b和d固定,改變參數a和c時,該奈米碳管膜在第二方向上的電阻隨著參數a與參數c的比值(a/c)增大而增大;另,可以通過減小參數a與c的比值的方法來提高該奈米碳管膜的導電異向性。 (3) When the parameters b and d of the through hole are fixed, and the parameters a and c are changed, the resistance of the carbon nanotube film in the second direction increases with the ratio of the parameter a to the parameter c (a/c). Increasing; alternatively, the conductivity anisotropy of the carbon nanotube film can be improved by reducing the ratio of the parameters a to c.
可以理解,所述步驟S20中的初始奈米碳管膜在圖案化處理之前,應該事先固定該初始奈米碳管膜,優選地,將該初始奈米碳管膜係懸空設置的。如,當該初始奈米碳管膜直接從一碳奈米管陣列中拉取獲得時,可以先固定該初始奈米碳管膜遠離該碳奈米管陣列的一端於一固定體,然後再圖案化處理該初始奈米碳管膜形成所述複數通孔,之後再用有機溶劑處理該圖案化的初始奈米碳管膜。另外,當收集該奈米碳管膜時,尤其係採用一可轉動的收集軸收集該奈米碳管膜時,轉動該收集軸,可以一邊將製備好的奈米碳管膜收集在該收集軸上,一邊不斷的從所述碳奈米管陣列中拉取獲得所述預製的奈米碳管膜,從而可以實現自動化生產所述奈米碳管膜。 It can be understood that the initial carbon nanotube film in the step S20 should be fixed in advance before the patterning process, and the initial carbon nanotube film is preferably suspended. For example, when the initial carbon nanotube film is directly drawn from a carbon nanotube array, the initial carbon nanotube film may be fixed away from the end of the carbon nanotube array in a fixed body, and then The initial carbon nanotube film is patterned to form the plurality of vias, and then the patterned initial carbon nanotube film is treated with an organic solvent. In addition, when collecting the carbon nanotube film, especially when collecting the carbon nanotube film by using a rotatable collecting shaft, rotating the collecting shaft, the prepared carbon nanotube film can be collected at the collection. The preformed carbon nanotube film is continuously obtained from the carbon nanotube array on the shaft, thereby enabling automated production of the carbon nanotube film.
下面將以具體實施例進一步說明本發明提供之奈米碳管膜及其製備方法。 The carbon nanotube film provided by the present invention and a method for preparing the same will be further described below by way of specific examples.
請參閱圖5,本發明第一實施例提供一奈米碳管膜10,該奈米碳管膜10為一自支撐結構,且包括複數碳奈米管線12以及複數碳奈米管團簇14,該複數碳奈米管團簇14通過凡得瓦爾力搭接於相鄰的碳奈米管線12之間,且該複數碳奈米管線12隔開。 Referring to FIG. 5, a first embodiment of the present invention provides a carbon nanotube film 10 which is a self-supporting structure and includes a plurality of carbon nanotube lines 12 and a plurality of carbon nanotube clusters 14 The plurality of carbon nanotube clusters 14 are overlapped between adjacent carbon nanotube lines 12 by van der Waals force, and the plurality of carbon nanotube lines 12 are separated.
該複數碳奈米管線12沿第二方向Y基本相互平行且並排間隔設置,該複數碳奈米管線12的軸向基本沿第一方向X延伸,形成一第一導電通路。其中,第二方向Y垂直於第一方向X。每個碳奈米管線12由複數通過凡得瓦爾力首尾相連且沿第一方向X排列的碳奈米管構成。每個碳奈米管線12的直徑大約為10微米。且相鄰的碳奈米管線12之間的間距大於1毫米。 The plurality of carbon nanotube lines 12 are substantially parallel to each other and spaced apart from each other in the second direction Y. The axial direction of the plurality of carbon nanotube lines 12 extends substantially in the first direction X to form a first conductive path. The second direction Y is perpendicular to the first direction X. Each of the carbon nanotube lines 12 is composed of a plurality of carbon nanotubes which are connected end to end by a van der Waals force and arranged in a first direction X. Each carbon nanotube line 12 has a diameter of approximately 10 microns. And the spacing between adjacent carbon nanotube lines 12 is greater than 1 mm.
該複數碳奈米管團簇14呈陣列排列。具體地,該複數碳奈米管團簇14沿第一方向X間隔設置,且在第二方向Y上成行整齊排列並通過該複數碳奈米管線12連接形成直線形第二導電通路。每個碳奈米管團簇14中的碳奈米管交叉設置形成網狀結構。每個碳奈米管團簇中的碳奈米管的軸向延伸方向與第一方向X相交,且夾角大於等於60度,且小於等於90度。 The plurality of carbon nanotube clusters 14 are arranged in an array. Specifically, the plurality of carbon nanotube clusters 14 are disposed at intervals in the first direction X, and are aligned in the second direction Y and connected by the plurality of carbon nanotube lines 12 to form a linear second conductive path. The carbon nanotubes in each of the carbon nanotube clusters 14 are arranged to form a network. The axial direction of the carbon nanotubes in each carbon nanotube cluster intersects the first direction X, and the angle is greater than or equal to 60 degrees and less than or equal to 90 degrees.
另,在第一方向上相鄰的碳奈米管團簇14之間以及碳奈米管線12的周圍都存在少量的碳奈米管。也就係說,該奈米碳管膜10中也存在有少量的無規則排列的碳奈米管。 In addition, a small amount of carbon nanotubes are present between adjacent carbon nanotube clusters 14 in the first direction and around the carbon nanotubes 12. That is to say, a small amount of randomly arranged carbon nanotubes are also present in the carbon nanotube film 10.
由此可見,該奈米碳管膜10在第一方向X及第二方向Y上的性質不同,尤其係其該兩個方向上具有較好的導電異向性。該奈米碳管膜10在第二方向Y上的電阻大約為其在第一方向X上的電阻的50倍。該奈米碳管膜10也具有較高的透光度,其透光度在可見光區達到98.43%。 It can be seen that the properties of the carbon nanotube film 10 in the first direction X and the second direction Y are different, in particular, they have better conductivity anisotropy in the two directions. The carbon nanotube film 10 has a resistance in the second direction Y of about 50 times its resistance in the first direction X. The carbon nanotube film 10 also has a high transmittance, and its transmittance reaches 98.43% in the visible light region.
可以理解,本發明提供之奈米碳管膜10中的碳奈米管團簇14在第二方向上也可以交錯排列,如圖6所示。 It can be understood that the carbon nanotube clusters 14 in the carbon nanotube film 10 provided by the present invention can also be staggered in the second direction, as shown in FIG.
請參閱圖7,本發明第一實施例提供上述奈米碳管膜10的製備方 法,該奈米碳管膜10的製備方法包括以下步驟:提供一碳奈米管陣列110,該碳奈米管陣列110生長於一基底112,採用一膠帶114從該碳奈米管陣列110中拉伸出一初始奈米碳管膜120,該初始奈米碳管膜120包括複數碳奈米管,該複數碳奈米管通過凡得瓦爾力首尾相連且沿同一方向排列。其中,該初始奈米碳管膜120中的碳奈米管的延伸方向為第一方向X。 Referring to FIG. 7, a first embodiment of the present invention provides a preparation method of the above carbon nanotube film 10. The method for preparing the carbon nanotube film 10 comprises the steps of: providing a carbon nanotube array 110, the carbon nanotube array 110 being grown on a substrate 112, using a tape 114 from the carbon nanotube array 110 An initial carbon nanotube film 120 is stretched out, and the initial carbon nanotube film 120 includes a plurality of carbon nanotubes which are connected end to end by van der Waals force and arranged in the same direction. The extending direction of the carbon nanotubes in the initial carbon nanotube film 120 is the first direction X.
移除所述膠帶114,並將所述初始奈米碳管膜120遠離所述碳奈米管陣列110的一端於一固定體128,同時,保證位於該固定體128及碳奈米管陣列110之間的初始奈米碳管膜120懸空設置;然後,採用功率密度大約為70000瓦/平方毫米,掃描速度大約為1100毫米/秒的雷射光束對該初始奈米碳管膜120進行圖案化處理,在該初始奈米碳管膜120上形成複數長方形的通孔122,該複數通孔122均勻分佈且排列成多行多列,並將該初始奈米碳管膜120分成複數連接部124及複數延伸部126,如圖8及圖9所示。該複數連接部124的排列方式基本與所述複數通孔122的排列方式一樣,呈陣列狀、多行多列排布。其中,該複數通孔122沿第一方向X及第二方向Y上的間距均為1毫米,每個通孔122沿第一方向X的長度大約為3毫米,每個通孔122沿第二方向Y的長度大約為1毫米;該複數通孔122的參數a、b、c、d分別為3毫米、1毫米、1毫米、1毫米。因此,該初始奈米碳管膜120的連接部124沿第二方向Y的長度基本為1毫米,沿第一方向X的長度基本為1毫米。該初始奈米碳管膜120的延伸部126沿第二方向Y的長度等於位於同一列上的相鄰的兩個通孔122在第二方向Y上的長度,所以,該延伸部126沿第二方向Y上的長度基本為1毫米。 The tape 114 is removed, and the initial carbon nanotube film 120 is separated from one end of the carbon nanotube array 110 to a fixed body 128, and at the same time, the fixed body 128 and the carbon nanotube array 110 are secured. The initial carbon nanotube film 120 is suspended between the openings; then, the initial carbon nanotube film 120 is patterned using a laser beam having a power density of about 70,000 watts/mm 2 and a scanning speed of about 1100 mm/sec. Processing, a plurality of rectangular through holes 122 are formed on the initial carbon nanotube film 120, the plurality of through holes 122 are evenly distributed and arranged in a plurality of rows and columns, and the initial carbon nanotube film 120 is divided into a plurality of connecting portions 124. And the plurality of extensions 126 are as shown in FIGS. 8 and 9. The arrangement of the plurality of connecting portions 124 is substantially the same as the arrangement of the plurality of through holes 122, and is arranged in an array, in a plurality of rows and in a plurality of rows. The distance between the plurality of through holes 122 in the first direction X and the second direction Y is 1 mm, the length of each of the through holes 122 in the first direction X is about 3 mm, and each of the through holes 122 is along the second. The length of the direction Y is approximately 1 mm; the parameters a, b, c, and d of the plurality of through holes 122 are 3 mm, 1 mm, 1 mm, and 1 mm, respectively. Therefore, the length of the connecting portion 124 of the initial carbon nanotube film 120 in the second direction Y is substantially 1 mm, and the length in the first direction X is substantially 1 mm. The length of the extension portion 126 of the initial carbon nanotube film 120 in the second direction Y is equal to the length of the adjacent two through holes 122 on the same column in the second direction Y. Therefore, the extension portion 126 is along the first The length in the two directions Y is substantially 1 mm.
將一滴瓶130放置於所述經過雷射處理的初始奈米碳管膜120的上方,乙醇132從該滴瓶130滴落於該經過雷射處理的初始奈米碳管膜120的表面。在表面張力的作用下,所述初始奈米碳管膜120的每個延伸部126在其中間位置形成碳奈米管線12。同時,該初始奈米碳管膜120的延伸部126的收縮會對該連接部124產生一拉力,使得該連接部124中的大部分碳奈米管由沿第一方向排列變為沿與該第一方向相交的方向排列;同時在該複數連接部124自身的表面張力的作用下,該複數連接部124形成複數碳奈米管團簇14,且該複數碳奈米管團簇14沿第二方向通過所述複數碳奈米管線連接,且沿第一方向間隔設置。由此形成所述奈米碳管膜10。 A drop of the bottle 130 is placed over the laser-treated initial carbon nanotube film 120 from which the ethanol 132 is dropped onto the surface of the laser-treated initial carbon nanotube film 120. Each extension 126 of the initial carbon nanotube film 120 forms a carbon nanotube line 12 at its intermediate position under the effect of surface tension. At the same time, the contraction of the extension portion 126 of the initial carbon nanotube film 120 generates a pulling force on the connecting portion 124, so that most of the carbon nanotubes in the connecting portion 124 are changed from being aligned along the first direction to The first direction intersects in the direction of intersection; at the same time, under the action of the surface tension of the plurality of connecting portions 124 themselves, the plurality of connecting portions 124 form a plurality of carbon nanotube clusters 14, and the plurality of carbon nanotube clusters 14 The two directions are connected by the plurality of carbon nanotube lines and are spaced apart in the first direction. The carbon nanotube film 10 is thus formed.
由於雷射在處理初始奈米碳管膜120形成通孔122的過程中,該初始奈米碳管膜120中的通孔122的邊緣受雷射自身條件的限制,該通孔122的邊緣可能會參差不齊。所以,經過溶劑處理後,得到的奈米碳管膜10中的碳奈米管線12及碳奈米管團簇14的周圍可能有少量的不規則排列的碳奈米管存在,如,圖10所示的該奈米碳管膜10的顯微鏡照片。 Since the laser is in the process of processing the initial carbon nanotube film 120 to form the through hole 122, the edge of the through hole 122 in the initial carbon nanotube film 120 is limited by the laser self condition, and the edge of the through hole 122 may be It will be uneven. Therefore, after the solvent treatment, there may be a small amount of irregularly arranged carbon nanotubes around the carbon nanotube line 12 and the carbon nanotube cluster 14 in the obtained carbon nanotube film 10, for example, FIG. A micrograph of the carbon nanotube film 10 is shown.
可以理解,當所述通孔如圖4所示的在第二方向Y上交錯排列時,最終製備得到的奈米碳管膜中的碳奈米管團簇也會交錯排列,就如同圖6所示的奈米碳管膜。 It can be understood that when the through holes are staggered in the second direction Y as shown in FIG. 4, the carbon nanotube clusters in the finally prepared carbon nanotube film are also staggered, just like FIG. The carbon nanotube film shown.
該奈米碳管膜10具有較好的透光度及電導率。本實施例通過測量樣品1-初始奈米碳管膜120、樣品2-雷射處理的初始奈米碳管膜120(雷射處理的初始奈米碳管膜指的係上述經過雷射處理形成有複數通孔122的初始奈米碳管膜120)、樣品3-酒精處理的初始奈米碳管膜120以及樣品4-所述奈米碳管膜10的透光度以及 用他們在第一方向X及第二方向Y上的電阻來表示各個樣品的導電各向異性。該奈米碳管膜10的電阻及各個波長下的透光度,具體如下表所示。其中,下表1中的各個樣品的電阻係通過將各個樣品固定在PET片上並製成3毫米×3毫米的方塊而測得的,其中並未測定樣品3的電阻,且各個樣品係通過將體積比為1:1的UV膠與乙酸丁酯的混合溶液塗覆在PET片上來實現固定在PET片上的。各個樣品的透光度在各個樣品在懸空狀態下測得的。 The carbon nanotube film 10 has good light transmittance and electrical conductivity. In the present embodiment, the sample 1 - initial carbon nanotube film 120, sample 2 - laser treated initial carbon nanotube film 120 (the laser treated initial carbon nanotube film refers to the above-mentioned laser treatment) The initial carbon nanotube film 120) having a plurality of through holes 122, the sample 3-alcohol treated initial carbon nanotube film 120, and the transmittance of the sample 4 - the carbon nanotube film 10 and The electrical anisotropy of each sample was expressed by their resistance in the first direction X and the second direction Y. The electric resistance of the carbon nanotube film 10 and the transmittance at each wavelength are as shown in the following table. Here, the resistance of each sample in the following Table 1 was measured by fixing each sample on a PET sheet and making a square of 3 mm × 3 mm, in which the resistance of the sample 3 was not measured, and each sample was passed through a volume. A mixed solution of UV glue and butyl acetate of 1:1 ratio was coated on the PET sheet to be fixed on the PET sheet. The transmittance of each sample was measured in each of the samples in a suspended state.
從上表可以看出所述奈米碳管膜10在各個方向上的電阻雖然比所述初始奈米碳管膜120及雷射處理過的初始奈米碳管膜的電阻大,但該奈米碳管膜10仍係一個導電異向性膜,且其在兩個方向上的電阻仍相差50倍以上。請參閱圖11及上表1,樣品4在各個波長下的透光度均大於樣品2及樣品3的透光度,所以所述奈米碳管膜10在各個波長下的透光度均優於所述初始奈米碳管膜120及雷射處理過的初始奈米碳管膜的透光度。另,在各個波長下,樣品4的透光度接近樣品1的透光度,這說明該奈米碳管膜10具有比較高的透光度。經過分析計算,可以發現,該奈米碳管膜10在可見光區的透光度可以達到98%以上。 It can be seen from the above table that although the electric resistance of the carbon nanotube film 10 in various directions is larger than that of the initial carbon nanotube film 120 and the laser-treated initial carbon nanotube film, the The carbon nanotube film 10 is still a conductive anisotropic film, and its resistance in both directions still differs by more than 50 times. Referring to FIG. 11 and Table 1 above, the transmittance of the sample 4 at each wavelength is greater than the transmittance of the sample 2 and the sample 3, so that the carbon nanotube film 10 has excellent transmittance at each wavelength. The transmittance of the initial carbon nanotube film 120 and the laser-treated initial carbon nanotube film. In addition, at each wavelength, the transmittance of the sample 4 is close to that of the sample 1, which indicates that the carbon nanotube film 10 has a relatively high transmittance. After analysis and calculation, it can be found that the transmittance of the carbon nanotube film 10 in the visible light region can reach 98% or more.
請參閱圖12,本發明第二實施例提供一奈米碳管膜20,該奈米碳管膜20包括複數碳奈米管線12及複數碳奈米管團簇24。該複數碳奈米管線12及複數碳奈米管團簇24呈陣列排列。該奈米碳管膜20的結構與第一實施例提供之奈米碳管膜10的結構基本相同,不同之處在於:每個碳奈米管團簇24包括複數第二碳奈米管242,該複數第二碳奈米管242的軸向延伸方向基本平行於所述碳奈米管線12的延伸方向。也就係說,該奈米碳管膜20中的碳奈米管基本沿同一方向擇優取向排列。由於該奈米碳管膜20在製備過程中存在誤差,所以該奈米碳管膜20的碳奈米管線12及碳奈米管團簇24的周圍有少量的碳奈米管存在。該奈米碳管膜20的具體結構可參見圖13所示的顯微鏡照片。 Referring to FIG. 12, a second embodiment of the present invention provides a carbon nanotube film 20 comprising a plurality of carbon nanotube lines 12 and a plurality of carbon nanotube clusters 24. The plurality of carbon nanotube lines 12 and the plurality of carbon nanotube tubes 24 are arranged in an array. The structure of the carbon nanotube film 20 is substantially the same as that of the carbon nanotube film 10 provided in the first embodiment, except that each carbon nanotube cluster 24 includes a plurality of second carbon nanotubes 242. The axial extension direction of the plurality of second carbon nanotubes 242 is substantially parallel to the extending direction of the carbon nanotube line 12. That is to say, the carbon nanotubes in the carbon nanotube film 20 are arranged in a preferred orientation in substantially the same direction. Since the carbon nanotube film 20 has an error in the preparation process, a small amount of carbon nanotubes are present around the carbon nanotube line 12 and the carbon nanotube cluster 24 of the carbon nanotube film 20. The specific structure of the carbon nanotube film 20 can be seen in the micrograph shown in FIG.
該奈米碳管膜20的製備方法與第一實施例提供之奈米碳管膜10的製備方法基本相同,不同之處在於:該奈米碳管膜20係採用水作為溶劑來處理形成有通孔的初始奈米碳管膜的。 The preparation method of the carbon nanotube film 20 is basically the same as the preparation method of the carbon nanotube film 10 provided in the first embodiment, except that the carbon nanotube film 20 is treated with water as a solvent. Through hole of the initial carbon nanotube membrane.
由於形成在初始奈米碳管膜上的通孔的相關參數a、b、c和d對所述奈米碳管膜的各種性能有影響,上述各參數對所述奈米碳管膜的影響下面的實驗進行比較,下面的各實驗中,複數通孔呈陣列狀均勻分佈在所述初始奈米碳管膜的表面。 Since the relevant parameters a, b, c and d of the through holes formed on the initial carbon nanotube film have an influence on various properties of the carbon nanotube film, the influence of the above parameters on the carbon nanotube film The following experiments were compared. In each of the following experiments, a plurality of through holes were uniformly distributed in an array on the surface of the initial carbon nanotube film.
(一)在通孔的參數a和c固定的條件下,參數b和d對本發明提供之奈米碳管膜的影響 (1) The influence of parameters b and d on the carbon nanotube film provided by the present invention under the condition that the parameters a and c of the through hole are fixed
實驗條件為:首先,對所述初始奈米碳管膜進行不同的處理。然後,將6636與乙酸丁酯溶劑按照體積比為1:1的比例進行混合;再與UV膠進行混合形成一混合溶液;將該混合有UV膠的溶液塗覆在PET片上;然後,將經過不同處理的初始奈米碳管膜固定在 PET片上以得到本次實驗的樣品,並製成3毫米×3毫米的方塊,用於測量其電阻。其中,各樣品分別兩次測量其透光度。具體實驗條件及結果參見表2,表2中的透光度指的係各樣品在波長為550奈米時的透光度;平行電阻-各樣品平行於其中的碳奈米管的延伸方向上的電阻也就係第一方向上的電阻;垂直電阻即平行於其中的碳奈米管的延伸方向的電阻,也就係第二方向上的電阻。 The experimental conditions are as follows: First, the initial carbon nanotube film is treated differently. Then, mixing 6636 with butyl acetate solvent in a ratio of 1:1 by volume; mixing with UV glue to form a mixed solution; coating the solution mixed with UV glue on the PET sheet; then, passing Different treatments of the initial carbon nanotube film are fixed in PET samples were taken to obtain samples of this experiment, and 3 mm x 3 mm squares were made for measuring the electrical resistance. Among them, each sample was measured for its transmittance twice. The specific experimental conditions and results are shown in Table 2. The transmittance in Table 2 refers to the transmittance of each sample at a wavelength of 550 nm; the parallel resistance - each sample is parallel to the direction in which the carbon nanotubes extend. The resistance is also the resistance in the first direction; the vertical resistance is the resistance parallel to the direction in which the carbon nanotubes extend, that is, the resistance in the second direction.
注:固化有UV膠的PET片在波長為550奈米時的透光度為91.40%。 Note: The transparency of a PET sheet cured with UV glue at a wavelength of 550 nm is 91.40%.
表2可以證明:(1)所述初始奈米碳管膜在經過雷射處理之後,再經過溶劑收縮得到的所述奈米碳管膜,也就係本發明提供之奈米碳管膜,可以較大程度的提高奈米碳管膜的透光度。(2)在通孔的參數a和c固定,改變參數b和d時,樣品1-8的平行電阻隨著參數b與d的比值(b/d)的增大而變大,與樣品係否經過溶劑 收縮無關。優選地,參數b與d的比值小於等於2,且平行電阻大於等於1千歐。(3)在通孔的參數a和c固定,改變參數b和d時,本發明提供之奈米碳管膜由於受到溶劑收縮的影響,其垂直電阻相對於僅採用雷射處理的奈米碳管膜的垂直電阻有較大程度的降低,由此,使得本發明提供之奈米碳管膜的導電異向性相對於其他條件下的奈米碳管膜的導電異向性下降。(4)本發明提供之奈米碳管膜可在電阻最小程度的增加的情況下,提高其透光度。 Table 2 can prove that: (1) the carbon nanotube film obtained by the solvent shrinkage after the laser treatment of the initial carbon nanotube film is the carbon nanotube film provided by the present invention, The transmittance of the carbon nanotube film can be improved to a large extent. (2) When the parameters a and c of the through hole are fixed, and the parameters b and d are changed, the parallel resistance of the sample 1-8 becomes larger as the ratio of the parameter b to d (b/d) increases, and the sample system No solvent The contraction has nothing to do. Preferably, the ratio of the parameters b to d is less than or equal to 2, and the parallel resistance is greater than or equal to 1 kohm. (3) When the parameters a and c of the through hole are fixed, and the parameters b and d are changed, the carbon nanotube film provided by the present invention is affected by the shrinkage of the solvent, and its vertical resistance is relative to the carbon treated only by the laser. The vertical resistance of the tubular film is largely reduced, whereby the conductive anisotropy of the carbon nanotube film provided by the present invention is lowered relative to the conductive anisotropy of the carbon nanotube film under other conditions. (4) The carbon nanotube film provided by the present invention can increase the transmittance thereof with a minimum increase in electrical resistance.
(二)在通孔的參數b和d固定的條件下,參數a和c對本發明提供之奈米碳管膜的影響 (b) The influence of parameters a and c on the carbon nanotube film provided by the present invention under the condition that the parameters b and d of the through hole are fixed
實驗條件為:首先,對所述初始奈米碳管膜進行不同的處理。然後,將UV膠與乙酸丁酯溶劑按照體積比為1:1的比例進行混合形成一混合溶液;將該混合有UV膠的溶液塗覆在PET片上;然後,將經過不同處理的初始奈米碳管膜固定在PET片上以得到本次實驗的樣品,並製成3毫米×3毫米的方塊,用於測量其電阻。其中,各樣品分別兩次測量其透光度。具體實驗條件及結果參見表3,表3中的透光度指的係各樣品在波長為550奈米時的透光度;平行電阻-各樣品平行於其中的碳奈米管的延伸方向上的電阻也就係第一方向上的電阻;垂直電阻即平行於其中的碳奈米管的延伸方向的電阻,也就係第二方向上的電阻。 The experimental conditions are as follows: First, the initial carbon nanotube film is treated differently. Then, the UV glue and the butyl acetate solvent are mixed at a ratio of 1:1 by volume to form a mixed solution; the solution mixed with the UV glue is coated on the PET sheet; then, the initial treatment of the different treatments is performed. The carbon tube film was fixed on a PET sheet to obtain a sample of the experiment, and a square of 3 mm × 3 mm was prepared for measuring the electric resistance. Among them, each sample was measured for its transmittance twice. The specific experimental conditions and results are shown in Table 3. The transmittance in Table 3 refers to the transmittance of each sample at a wavelength of 550 nm; the parallel resistance - each sample is parallel to the direction in which the carbon nanotubes extend. The resistance is also the resistance in the first direction; the vertical resistance is the resistance parallel to the direction in which the carbon nanotubes extend, that is, the resistance in the second direction.
表3
注:固化有UV膠的PET片在波長為550奈米時的透光度為91.40%。 Note: The transparency of a PET sheet cured with UV glue at a wavelength of 550 nm is 91.40%.
表3可以證明:(1)在通孔的參數b和d固定,改變參數a和c時,樣品1-8的垂直電阻隨著參數a與參數c的比值(a/c)增大而增大,與樣品係否經過溶劑收縮無關。優選地,參數a與參數c的比值大於等於0.5,且小於等於4。垂直電阻優選地大於30千歐。(2)可以通過增大參數a與參數c的比值的方法提高本發明提供之奈米碳管膜的導電異向性。(3)溶劑收縮不利於提高奈米碳管膜的導電異向性。 Table 3 can prove: (1) When the parameters b and d of the through hole are fixed, and the parameters a and c are changed, the vertical resistance of the sample 1-8 increases as the ratio of the parameter a to the parameter c (a/c) increases. Large, regardless of whether the sample is subjected to solvent shrinkage. Preferably, the ratio of the parameter a to the parameter c is greater than or equal to 0.5 and less than or equal to 4. The vertical resistance is preferably greater than 30 kilohms. (2) The conductivity anisotropy of the carbon nanotube film provided by the present invention can be improved by increasing the ratio of the parameter a to the parameter c. (3) Solvent shrinkage is not conducive to improving the conductivity anisotropy of the carbon nanotube film.
(三)碳奈米管結構的強度比較 (III) Comparison of the strength of carbon nanotube structures
本文中各種碳奈米管結構能夠承受的最大拉力用“強度”表示。寬度大約為15毫米的初始奈米碳管膜的強度大約為150毫牛頓;雷射處理該寬度大約為15毫米的初始奈米碳管膜的強度大約為47毫牛頓;本發明提供之奈米碳管膜的強度大約為105毫牛頓,其 中,該奈米碳管膜係由寬度大約為15毫米的初始奈米碳管膜製備得來的。其中,雷射處理的初始奈米碳管膜及本發明提供之奈米碳管膜,在雷射雷射處理的過程中都使得所述初始奈米碳管膜上形成的通孔的參數a、b、c及d分別為3毫米、0.35毫米、0.8毫米及0.35毫米。優選地,當初始奈米碳管膜的寬度大約為15毫米時,本發明提供之奈米碳管膜的強度大於等於90毫牛頓。 The maximum tensile force that various carbon nanotube structures can withstand herein is expressed in terms of "strength." The initial carbon nanotube film having a width of about 15 mm has a strength of about 150 millinewtons; the laser treatment of the initial carbon nanotube film having a width of about 15 mm has an intensity of about 47 millinewtons; the nanometer provided by the present invention The carbon nanotube film has an intensity of about 105 millinewtons, The carbon nanotube film is prepared from an initial carbon nanotube film having a width of about 15 mm. Wherein, the laser-treated initial carbon nanotube film and the carbon nanotube film provided by the present invention cause parameters of the through hole formed in the initial carbon nanotube film during laser laser processing , b, c and d are 3 mm, 0.35 mm, 0.8 mm and 0.35 mm, respectively. Preferably, when the width of the initial carbon nanotube film is about 15 mm, the strength of the carbon nanotube film provided by the present invention is greater than or equal to 90 millinewtons.
由本發明實施例提供之奈米碳管膜之製備方法製備出的奈米碳管膜包括複數間隔設置的碳奈米管線及碳奈米管團簇,所以該奈米碳管膜具有較多的孔隙,從而使得該奈米碳管膜具有較高的透光度,且該奈米碳管膜的透光度在可見光區大於等於95%,甚至可以達到98%以上。該奈米碳管膜中的碳奈米管線沿第一方向延伸形成第一導電通路,且該奈米碳管膜中的碳奈米管團簇沿第二方向通過碳奈米管線連接形成第二導電通路;所以,該奈米碳管膜具有導電異向性,為導電異向性膜。該奈米碳管膜在第二方向及第一方向上的電阻可以相差50倍以上。另,該奈米碳管膜中的碳奈米管線通過複數碳奈米管團簇固定在一起,形成膜狀結構,使得該奈米碳管膜具有較好的強度及穩定性,不易破裂。 The carbon nanotube film prepared by the method for preparing a carbon nanotube film provided by the embodiment of the invention comprises a plurality of carbon nanotube pipelines and carbon nanotube clusters disposed at intervals, so the carbon nanotube membrane has more The pores, so that the carbon nanotube film has a high transmittance, and the transmittance of the carbon nanotube film is greater than or equal to 95% in the visible light region, and may even reach 98% or more. The carbon nanotube line in the carbon nanotube film extends in a first direction to form a first conductive path, and the carbon nanotube clusters in the carbon nanotube film are connected in a second direction through a carbon nanotube line to form a first The second conductive path; therefore, the carbon nanotube film has an anisotropic conductivity and is an electrically conductive anisotropic film. The resistance of the carbon nanotube film in the second direction and the first direction may differ by more than 50 times. In addition, the carbon nanotube pipeline in the carbon nanotube membrane is fixed together by a plurality of carbon nanotube clusters to form a membrane-like structure, so that the carbon nanotube membrane has good strength and stability and is not easily broken.
本發明實施例通過在該初始奈米碳管膜的表面形成至少一行通孔並結合溶劑處理該形成有通孔的初始奈米碳管膜的方法來製備所述奈米碳管膜,同時,還可以通過控制初始奈米碳管膜上的通孔相關參數來控制奈米碳管膜中的碳奈米管線的直徑以及相鄰的碳奈米管線之間的間距,即控制該奈米碳管膜的結構,進而可以控制該奈米碳管膜在各個方向上的電阻,因此該奈米碳管膜之製備方法比較簡單,易於控制該奈米碳管膜的電阻,有利於工業化生 產。另外,在製備奈米碳管膜的過程,所述通孔有規律地、規則地形成在所述初始奈米碳管膜中,使得由本發明實施例提供之方法製備的奈米碳管膜中的碳奈米管線及碳奈米管團簇有規律排列成多行多列,在具有較高透光度的同時還具有導電異向性。 In the embodiment of the present invention, the carbon nanotube film is prepared by forming at least one row of through holes on the surface of the initial carbon nanotube film and treating the initial carbon nanotube film formed with the through hole in combination with a solvent, and It is also possible to control the diameter of the carbon nanotube line in the carbon nanotube film and the spacing between adjacent carbon nanotube lines by controlling the through-hole related parameters on the initial carbon nanotube film, that is, controlling the nanocarbon The structure of the tubular membrane can further control the electrical resistance of the carbon nanotube membrane in various directions, so the preparation method of the carbon nanotube membrane is relatively simple, and it is easy to control the electrical resistance of the carbon nanotube membrane, which is beneficial to industrialization. Production. Further, in the process of preparing the carbon nanotube film, the through holes are regularly and regularly formed in the initial carbon nanotube film, so that the carbon nanotube film prepared by the method provided by the embodiment of the present invention is The carbon nanotube pipeline and the carbon nanotube cluster are regularly arranged in a plurality of rows and columns, and have a high transmittance and an anisotropic conductivity.
綜上所述,本發明確已符合發明專利之要件,遂依法提出專利申請。惟,以上所述者僅為本發明之較佳實施例,自不能以此限制本案之申請專利範圍。舉凡熟悉本案技藝之人士援依本發明之精神所作之等效修飾或變化,皆應涵蓋於以下申請專利範圍內。 In summary, the present invention has indeed met the requirements of the invention patent, and has filed a patent application according to law. However, the above description is only a preferred embodiment of the present invention, and it is not possible to limit the scope of the patent application of the present invention. Equivalent modifications or variations made by persons skilled in the art in light of the spirit of the invention are intended to be included within the scope of the following claims.
20‧‧‧奈米碳管膜 20‧‧‧Nano carbon nanotube film
12‧‧‧碳奈米管線 12‧‧‧Carbon Pipeline
24‧‧‧碳奈米管團簇 24‧‧‧Carbon nanotube clusters
242‧‧‧第二碳奈米管 242‧‧‧Second carbon nanotube
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