KR20160138952A - Activated carbon for smoking articles - Google Patents

Abstract

The smoking article contains a smokable substance and an active carbon substance downstream of the smokable substance. The activated carbon material has a ratio of narrow micropore volume to total micropore volume of about 0.9 or less. The activated carbon material may be a carbon-on-tow configuration, a plug-space-plug configuration, or activated carbon in any other suitable configuration. The activated carbon material may have a ratio of total micropore volume to total pore volume of about 0.9 or greater. The activated carbon material may also contain surface oxygen at a concentration of about 5000 μmol / g or less. The activated carbon may have a BET of about 1100 m ² / g or more.

Description

{ACTIVATED CARBON FOR SMOKING ARTICLES}

The present disclosure relates to activated carbon suitable for smoking articles, filters containing such activated carbon, and related smoking articles.

Flammable smoking articles, such as cigarettes, have shredded tobacco (usually in the form of cut fillers) surrounded by paper wrappers forming a tobacco rod. A cigarette uses a cigarette load by burning the end of a cigarette. The smoker then aspirates into the mouth of the cigarette, usually at the opposite end or mouth of the cigarette containing the filter and accepts mainstream smoke into their mouths. The filter is arranged to capture some constituents of the mainstream smoke before the mainstream smoke is delivered to the smoker and may contain activated carbon to absorb the smoke constituents.

The pores of the activated carbon for use in smoking articles may have micropores (less than 2 nm) or heavy mesopores (less than 2 nm), as well as reports suggesting that increasing mesopore to micropore ratios may be desirable for adsorbing smoke. (2 nm to 50 nm). Recently, a micropore subset called narrow micropore has been described. The narrow micropores have a size of 0.7 nm or less. Some have suggested that the volume of narrow micropores needs to be maximized to optimize the adsorption capacity of activated carbon for volatile organic contaminants in industrial process gas streams at low concentrations.

One object of the present invention is to use activated carbon for the filter of the smoking article wherein the activated carbon is more effective at removing at least selected smoke components than the existing activated carbon used or proposed for use in smoking articles. Other objects of the present invention will become apparent to those skilled in the art upon reading and understanding the present disclosure, including the claims that follow and the accompanying drawings.

In aspects of the present invention, the smoking article comprises a smokable material and an activated carbon material downstream of the smokable material. The activated carbon material has a ratio of narrow micropore volume to total micropore volume of about 0.9 or less and has surface oxygen at a concentration of about 5000 μmol / g or less as determined by temperature-programmed desorption.

In aspects of the present invention, the method includes the steps of: (i) mixing activated carbon having a ratio of narrow microvoid volume to total microvoid volume of about 0.9 or less and having surface oxygen at a concentration less than about 5000 [mu] mol / g, Providing a material; (ii) providing a filter material for use in a smoking article; And (iii) combining the activated carbon material and the filter material to form a filter for the smoking article.

The various aspects of the filter and the smoking article of the present invention may have one or more advantages over currently available filters and smoking articles. For example, the improved efficiency of activated carbon to remove at least selected smoke constituents can reduce the amount of activated carbon material to be used, thereby reducing manufacturing costs. Using less activated carbon material can also reduce breakthrough. As a further example, the selective adsorption of smoke constituents can make the smoking experience even better. For example, enhanced flavor may be caused by the removal of optional ingredients rather than all ingredients including flavor ingredients. Additional advantages of the filter and one or more aspects of the smoking article described herein will be apparent to those skilled in the art upon reading and understanding the present disclosure.

Figures 1 and 2 are schematic perspective views of an embodiment of a partially unfolded smoking article.
3 is a graph of the N ₂ isotherm at -196 ° C for samples 1-7.
4 is a graph of percent reduction of benzene (for cigarettes without activated carbon) in cigarettes containing activated carbon of each of Samples 1-7.
5 is a graph of reduction rates of acrolein (for cigarettes without activated carbon) in cigarettes containing activated carbon of each of Samples 1-7.
6 is a graph of percent reduction of benzene (for cigarettes without activated carbon) in cigarettes containing activated carbon of each of Samples 11-14.
7 is a graph of the rate of reduction of acrolein (for cigarettes without activated carbon) in cigarettes containing activated carbon of each of Samples 11-14.

Activated carbon is a generic term used to describe a series of carbonaceous adsorbents with widely developed internal pore structures. Activated carbon can be made of carbonaceous materials such as wood, lignite, coal, coconut shell or shell, peat, pitch, polymer, cellulose fibers, polymer fibers and the like. The activated carbon may be produced by any suitable process such as physical activation or chemical activation. In physical activation, raw materials are developed as activated carbon using hot gases by carbonization, activation / oxidation or carbonization and activation / oxidation. The carbonization process includes pyrolyzing the raw material in the absence of oxygen at high temperature, generally within the range of about 600 ° C to about 900 ° C. The activation / oxidation includes exposing the carbide to an oxidizing atmosphere such as steam, carbon dioxide or oxygen at a temperature exceeding 250 ° C. The temperature of the activation / oxidation is generally in the range of about 600 ° C to about 1200 ° C.

Chemical activation involves impregnating the raw material with a specific chemical such as acid, base or salt, such as phosphoric acid, potassium hydroxide, sodium hydroxide, calcium chloride or zinc chloride. Then, the raw material is generally carbonized at a lower temperature than the physically activated carbonization. For example, the temperature of the chemically activated carbonization may range from about 450 ° C to about 900 ° C. Carbonization and activation can be done simultaneously.

For the purposes of this disclosure, the carbonaceous feedstock can be activated via any suitable process. For example, the activation process may include chemical activation, which may include shorter activation times and lower temperatures than physical activation. Alternatively, physical activation may be used.

The pore size and surface properties can be varied according to known techniques, which can affect the efficiency with which activated charcoal can remove selected smoke components such as 1,2-propadiene, 1,3 -Butadiene, isoprene, benzene, 1,2-pentadiene, 1,3-cyclopentadiene, 2,4-hexadiene, 1,3-cyclohexadiene, methyl-1,3- cyclopentadiene, benzene, toluene but are not limited to, ethylene, propylene, butylene, propylene, isobutylene, isobutylene, isobutylene, isobutylene, isobutylene, Ketone, diacetyl, methyl ethyl ketone, methyl propyl ketone, methyl 2-furyl ketone, hydrogen cyanide and acrylonitrile. The activated carbon for use in the filter and the smoking article of the present invention preferably desorbs benzene, acrolein or both benzene and acrolein efficiently, but also efficiently removes one or more other smoke components.

The activated carbon for use in the filters or smoking articles of the present invention preferably has a medium to medium volume for a total pore volume of about 10% or less. The mesopore is a pore having a size of 2 nm to 50 nm. More preferably, the mesoporous volume to total pore volume is less than about 5%.

Activated carbon for use in the filter or smoking article of the present invention preferably has a ratio of micropore volume to total pore volume of at least about 90%. Micropores are pores having a size of 2 nm or less. More preferably, the micropore volume for the total pore volume is greater than about 95%. More preferably, the micropore volume for the total pore volume is at least about 96% or at least about 98%.

Activated carbon for use in the filter or smoking article of the present invention preferably has a ratio of narrow micropores to total micropores of about 0.9% or less. The narrow micropores are pores having a size of 0.7 nm or less. More preferably, the ratio of narrow micropores to total micropores is about 0.85 or less. More preferably, the ratio of narrow micropores to total micropores is less than or equal to about 0.8. More preferably, the ratio of narrow micropores to total micropores is about 0.75 or less.

Activated carbon for use in the filter or smoking article of the present invention preferably contains a surface oxygen concentration of about 5000 μmol / g or less. More preferably, the surface oxygen concentration is about 4000 mol / g or less. More preferably, the surface oxygen concentration is about 3000 占 퐉 ol / g or less. More preferably, the surface oxygen concentration is about 2000 占 퐉 ol / g or less.

Activated carbon for use in the filters or smoking articles of the present invention preferably has a specific surface area (BET) of at least about 1100 m ² / g. Generally, activated carbon will have a BET of less than or equal to about 2500 m ² / g. Preferably, the activated carbon has a BET of about 1600 m ² / g.

In some preferred embodiments, the activated carbon for use in the filter or smoking article of the present invention has a narrow microvoid volume to total microvoid volume ratio of about 0.75 or less and a ratio of total microvoid volume to total pore volume of about 0.9 or greater I have. In these embodiments, the activated carbon may have any suitable BET, which may often be less than about 2500 m ² / g. Preferably, the BET is greater than or equal to about 1100 m ² / g. Preferably, the BET is about 1600 m ² / g.

In some preferred embodiments, the activated carbon for use in the filter or smoking article of the present invention has a surface oxygen concentration of about 2000 μmol / g or less and a ratio of total micropore volume to total pore volume of about 0.95 or greater. In these embodiments, the activated carbon may have any suitable BET, which may often be less than about 2500 m ² / g. Preferably, the BET is greater than or equal to about 1100 m ² / g. Preferably, the BET is about 1600 m2 / g.

In some preferred embodiments, the activated carbon for use in the filter or smoking article of the present invention has a ratio of narrow microvoid volume to total microvoid volume of about 0.75 or less; A surface oxygen concentration of about 2000 μmol / g or less; And a ratio of total micropore volume to total pore volume of about 0.95 or greater. In these embodiments, the activated carbon may have any suitable BET, which may often be less than about 2500 m ² / g. Preferably, the BET is greater than or equal to about 1100 m ² / g. Preferably, the BET is about 1600 m ² / g.

As described above, the pore size distribution and surface properties of activated carbon, such as the ability to control surface oxygen concentration, are well known in the art. For example: (i) WO 2010/103323 A1, entitled METHODS FOR INCREASING MESOPORES INTO MICROPOROUS CARBON; (ii) Behavior of activated carbons with different pore size distributions and surface oxygen groups for benzene and toluene by Lillo-Rodenas et al. (2005) Carbon 43: 1758-1767; And (iii) Spherically activated carbon for low concentration toluene adsorption by Romero-Anaya et al. (2010), Carbon 48: 2625-2633. In general, the pore size distribution and surface properties can be easily changed by adjusting the activation atmosphere (O ₂ , CO ₂ or steam) and the activation time and temperature. For example, an additional treatment in an inert atmosphere may be performed to change the surface oxygen content without altering the porosity. Those skilled in the art can easily adjust the activation parameters to achieve activated carbon for use in the filters and smoking articles of the present invention. For evaluation criteria, activated carbon may be prepared as described in the examples set forth below or may be altered from the procedures set forth in the examples as appropriate to achieve the appropriate activated carbon material.

The pore size distribution can be determined in any suitable manner. For example, the micropore volume can be determined, for example, by Gregg SJ, Sing KSW; Adsorption, Surface Science and Porosity; Can be calculated from the N ₂ adsorption isotherm at -196 ° C using the Dubinin-Radushkevich equation as taught by Academic Press, New York, 1982. The narrow micropore volume is (i) determined by Cazorla-Amoros et al., Langmuir 1996; 12: 2820-24; (ii) by Cazorla-Amoros et al., Langmuir 1998; 14: 4589-96; And (iii) it can be calculated from the CO ₂ adsorption at 0 ℃ as described in due _{Cazorla-Amoros, Usefulness of CO 2} adsorpotion at 273K for the characterization of porous carbons. Carbon 2004; 42: 1233-42. The total pore volume is, for example, Gregg SJ, Sing KSW. Adsorption, Surface Science and Porosity. Can be determined by N ₂ isotherm at -196 ° C by calculating the adsorption volume of nitrogen at P / P 0 = 0.95 according to the method of Academic Press, New York, 1982. As an evaluation criterion, the total pore volume, the micropore volume, and the narrow micropore volume can be determined as described below in the Examples.

When the total pore volume, micropore volume, and narrow micropore volume are determined, the ratio of the narrow micropore volume to the total micropore volume, the ratio of the total micropore volume to the total pore volume, etc. can be easily calculated.

The surface oxygen concentration can be determined in any suitable manner. As an example, the surface oxygen concentration can be determined by a temperature elevation desorption (TPD) experiment using a Differential Scanning Calorimeter (DSC) -Thermal Weight Analyzer (TGA) coupled to a mass spectrophotometer, For example, (i) TPD and TPR characterization of carbonaceous supports and Pt / C catalysts, Carbon 31: 894-902 by Roman-Martinez et al. (1993); (ii) Characterization of oxygen-containing surface complexes by Otake Y. and Jenkins RG et al. (1993) on microporous carbon by air and nitric acid treatment, Carbon 31: 109-21; And (iii) Surface oxidized carbon fibers by Zielge et al. (1996) I. Surface structure and chemistry, Carbon 34: 983-98. In this TPD experiment, a 10 mg sample of activated carbon can be heated to 950 캜 at a heating rate of 20 캜 / min under a helium flow rate of 100 ml / min.

The activated carbon may be disposed in the filter for the smoking article in any suitable manner. For example, the activated carbon may be disposed in a combination that is mixed with the fibrous filter material, placed in an empty space within the filter, or mixed with the fibrous filter material and disposed in an empty space within the filter.

In an embodiment, activated carbon is provided in a filter of a plug-space-plug configuration in which activated carbon is present in a void space between two sections of filter plug material. Preferably, the plug of the filter section in the plug-space-plug filter configuration is a plug made of cellulose acetate tow. In an embodiment, activated carbon is provided in a carbon-on-tow configuration. Preferably, the tow is a cellulose acetate tow. Regardless of the filter construction, it may be desirable to include a white cellulose acetate tow section at the mouse end of the filter for aesthetic purposes or to meet consumer expectations.

In aspects of the present invention, a filter for a smoking article or a filter for a smoking article comprises the activated carbon described herein. The filter may comprise a filter material such as a cellulose acetate tow. In some preferred embodiments, the activated carbon is incorporated into or onto the cellulose acetate tow. In some preferred embodiments, the filter comprises first and second cellulose acetate tow elements, and the activated carbon material is disposed between the first and second cellulose acetate tow elements in a plug-space-plug configuration. In some plug-space plug configurations, activated carbon may be incorporated into one or both of the first and second cellulose acetate tow elements.

Any suitable smoking article may comprise a filter having activated carbon as described in this disclosure, wherein the filter is disposed downstream of the smoking article. The term " downstream " refers to the relative position of the components of the smoking article described in relation to the direction of the mainstream drawn from the smoking article to the mouth of the user.

The term " smoking article " includes cigarettes, cigars, cigarillas, and other articles that ignite and burn a smoking article, such as a cigarette, to produce smoke. The term " smoking article " is intended to encompass articles in which the smoking article is not to be burned, such as, but not limited to, a smoking article that directly or indirectly heats the smoking article, It also includes a smoking article that transfers nicotine or other substances from the smoking article.

As used herein, the term " smoke " is used to describe an aerosol generated by a smoking article. The aerosol produced by the smoking article may be, for example, smoke produced by a flammable smoking article such as a cigarette, or aerosol produced by a non-smoking article, such as a heated smoking article or a non-heated smoking article.

The activated carbon for use in the filter or smoking article of the present invention preferably desorbs one or more components from the smoke when the user is smoking the smoking article. Activated carbon may remove one or more components from the smoke by any suitable mechanism, such as binding, adsorption, adsorption, and the like. The activated carbon for use in the filter or smoking article of the present invention preferably removes both benzene, acrolein, benzene and acrolein.

All scientific and technical terms used herein have the meanings commonly used in the art unless otherwise specified. The definitions provided herein are intended to facilitate understanding of certain terms frequently used herein.

As used herein, the singular forms "a", "an", and "the" include implementations having a plurality of referents unless the context clearly dictates otherwise.

As used herein, the term " or " is generally used to mean " and / or ", unless the context clearly dictates otherwise. The term " and / or " means one or all of the listed elements, or any combination of two or more of the listed elements.

 As used herein, the terms "having," "having," "including," "including," "having", "having", and the like are used in an open sense and are generally " Not ". It will be understood that " consisting essentially of " or " consisting of "

The words " preferred " and " preferably " refer to implementations of the invention that may provide certain benefits under certain circumstances. However, other implementations may be desirable under the same or different circumstances. Moreover, the description of one or more preferred embodiments does not imply that other embodiments are not useful, nor is it intended to exclude other embodiments from the scope of the present invention including the claims.

The smoking article shown in Figs. 1 and 2 shows an embodiment of the aforementioned smoking article or constituent elements of the smoking article. The above schematics are not necessarily to scale and are provided for illustrative purposes and not for purposes of limitation. The drawings illustrate one or more aspects described herein. However, it is to be understood that other aspects not shown in the drawings are within the scope and spirit of the present invention.

Turning now to FIG. 1, a smoking article 10, in this case a cigarette, is shown. The smoking article 10 includes a rod 20, such as a tobacco rod, and a mouse-end filter 30. The filter 30 includes a mouse distal segment 32, such as a white cellulose acetate tow segment, and a carbon on-the-top segment 34 upstream. The filter segments 32, 34 are shown as being separate for illustrative purposes, but may be bordering. Similarly, the filter segments 34 and the rods 20 are illustrated as being separated for illustrative purposes, but may also be bordering. The illustrated smoking article 10 includes a plug wrap 60, a cigarette paper 40 and a tipping paper 50. In the illustrated embodiment, the plug wrap 60 surrounds at least a portion of the filter 30. The cigarette paper (40) surrounds at least a portion of the rod (20). The tipping paper 50 or other suitable wrapper surrounds the plug wrap 60 and a portion 40 of the cigarette paper, as is generally known in the art.

Figure 2 shows an embodiment in which the filter 30 is a plug 32 -space 37-plug 35 structure. Activated carbon (not shown) may occupy the empty space 37 between the filter plugs 32 and 35. In Fig. 2, the filter segments 35 and the rods 20 are shown as being separated for illustrative purposes, but may also be bordering. In FIG. 2, the components denoted by the same reference numerals as the components shown in FIG. 1 are the same as or similar to those described above with reference to FIG. For those components not specifically described in connection with FIG. 2, reference is made to the above discussion with respect to FIG.

Now, non-limiting embodiments illustrating activated carbon and the filter and smoking article with such activated carbon as described above will be described.

Example

In the following examples, the characterization of the activated carbon made from various raw materials and the function of some activated carbon in the filter of the smoking article are explained.

Activated carbon was prepared as follows. Commercially available spherical activated carbon which functions as the precursor (obtained from the polymer) provided by Gun-Ei was selected as the starting material. To further improve its porosity, activated carbon was prepared by physical activation by CO ₂ using the experimental procedure described by Romero-Anaya et al. (2010), Carbon 48: 2625-2633. For physical activation by CO ₂ , a horizontal quartz furnace tube of 2 m length and 0.7 m diameter was used and the precursor was placed in the crucible. To prepare samples 2 to 6, a flow of CO _{2 at} 80 ml / min, heating at 10 ° C / min from room temperature to 880 ° C, and activation times of 3, 5, 10, 15, and 20 hours were used. The naming of these samples was chosen according to the degree of activation. Sample 7, a spherical commercial activated carbon provided by Gun-Ei, was also selected and studied.

Sample 11, a commercial granular activated carbon (WVA1100) from MeadWestvaco, was selected as the granular material. Since it has been proven that surface chemistry has a significant influence on the adsorption of organic compounds with a high degree of surface chemistry, it is necessary to modify the surface chemistry properties of the samples and to further study the influence of these parameters on the performance of these samples for smoking article applications A number of heat treatments in an inert atmosphere were performed on these samples. The heat treatment was carried out in a nitrogen atmosphere at a flow rate of 100 ml / min up to three different maximum temperatures of 300, 600 and 900 DEG C maintained for 1 hour. The cooling step was performed with the same nitrogen flow.

To ensure that these treatments do not have substantially modified porosity, the texture and surface chemistry of the heat treated activated carbon was characterized. The original WVA 1100 will be referred to as Sample 11, while the heat treated samples are referred to as Samples 12-14 and the numbers refer to the maximum heat treatment temperature in an inert atmosphere.

The properties of the activated carbon can be analyzed by routine methods to determine total pore volume, total micropore volume, and narrow micropore volume. The samples were characterized as follows. Characterization of all samples was performed using nitrogen (N ₂ ) adsorption at -196 ° C and CO ₂ adsorption at 0 ° C in a volumetric Autosorb-6B instrument from Quantachrome. Prior to analysis, the samples were degassed at 250 DEG C for 4 hours. The BET equation was applied to nitrogen adsorption data to obtain the apparent BET surface area (SBET) (Linares-Solano et al., Tanso 1998; 185: 316-325). The Dubinin-Radushkevich equation was applied to the nitrogen adsorption data to determine the total micropore volume (pore with <2 nm size) V-DR-N ₂ and the total pore volume (VN ₂ at P / P0 = 0.95). The Dubinin-Radushkevich equation was applied to carbon dioxide adsorption isotherms to determine a narrow micropore volume V-DR-CO ₂ (pore size <0.7 nm).

The surface oxygen content on the surface of the activated carbon can be determined by temperature increase desorption (TPD) under standard conditions. The surface oxygen content of the sample was determined as follows. Differential Scanning Calorimetry (DSC) and Thermogravimetric Analysis (TGA) coupled to a mass spectrometer (Balzers, OmniStar) to characterize the oxygen surface chemistry of all samples, including measurement of water, carbon monoxide and carbon dioxide content under an inert atmosphere, (TA Instruments, SDT 2960 Simultaneous). For example, (i) TPD and TPR characterization of carbonaceous supports and Pt / C catalysts, Carbon 31: 894-902 by Roman-Martinez et al. (1993); (ii) Characterization of oxygen-containing surface complexes by Otake Y. and Jenkins RG (1993) on microporous carbon by air and nitric acid treatment, Carbon 31: 109-21; And (iii) Surface oxidized carbon fibers by Zielge et al. (1996): I. Surface structure and chemistry, Carbon 34: 983-98. In these experiments, a 10 mg sample was heated to 950 캜 (heating rate 20 캜 / min) under a helium flow rate of 100 ml / min.

The layer density (also referred to as bulk, tap, or apparent density) of activated carbon can be defined as the weight of the porous solid per volume. This volume includes both the volume of the open pores and the closed pores, and the volume of space between the solid particles. This size was measured using an experimental procedure similar to that described by the D2854-89 ASTM method (Romero-Anaya et al., Carbon 2010; 48: 2625-2633). In our case, a density measurement was performed with 0.5 g of sample using a 10 ml measuring cylinder.

The model cigarettes were prepared as follows.

The filter in a plug-space-plug configuration with an 11 mm cellulose acetate plug and a 5 mm cavity was adjusted to a 54 mm long tobacco rod with a constant tobacco weight (about 600 mg) and attached with a tipping paper. The cavities were filled with 165 mg, 127 mg, 100 mg, 70 mg, 55 mg, 40 mg and 30 mg of samples 1 to 7, respectively, and a suitable amount of nonporous material such as cellulose beads to obtain a complete cavity fill. Approximately 67 m ² was maintained a BET surface in the sample 2 to sample 7, it is available for absorption in the respective filter. The cigarette was designed to maintain a constant pressure drop for the ventilated cigarette at about 140 mmWG.

In Table 2, we obtained about 108 m &lt; 2 &gt; by adding 60 mg of samples 11, 12 and 13 and 75 mg of sample 14.

The filter of the reference cigarette contained only non-porous material within the cavity.

The cigarettes were smoked according to the method described in WHO TobLabNet Official Method SOP01: "Standard operating procedure for intense smoking of cigarette". The method was applied to 10 smoking sticks per sample.

Benzen and acrolein were measured from cigarette smoke analysis and% reduction was calculated from cigarettes not containing activated carbon. For the smoking article using Sample 14, 75 mg of activated carbon was used to compensate for the smaller BET surface and smaller pore volume (see Table 2).

Table 1 below provides the characterization results for Samples 1-8, and Table 2 below provides the characterization results for Samples 11-14.

In general, the results show that, among other things, (i) a reduced ratio of narrow micropore volume to total micropore volume increases the adsorption of benzene and acrolein; (ii) the increased ratio of total micropore volume to total pore volume increases the adsorption of benzene and acrolein; And (iii) reduced surface oxygen concentration increases the adsorption of benzene and acrolein.

For example and referring to Figures 4-5 and Table 1, the rate of decrease in benzene and the rate of decrease in acrolein increase in samples 3 to 4 as the narrow micrometering increases. Note that in FIG. 5, the rate of reduction of acrolein in Sample 7 is lower than in Sample 6, although it has a high BET. Without being bound by theory, it is believed that the lower ratio of micropore volume to total pore volume in sample 7 (0.93 vs. 0.96) compared to sample 6 may be a factor in the reduced reduction of acrolein in sample 7.

Referring now to Figures 6-7 and Table 2, an increased rate of reduction of benzene and acrolein was observed as the surface oxygen content was reduced (from Sample 11 to Sample 14).

10: Smoking articles
20: Load
30: Mouse end filter
32,34,35: filter segments, filter plugs
37: Space
40: Cigarette paper
50: tipping paper
60: Plug wrap

Claims (14)

As a smoking article,
Smoking substances; And
Wherein the activated carbon material has a ratio of narrow microvoid volume to total microvoid volume of about 0.9 or less, wherein the concentration of the active carbon material at a concentration of less than or equal to about 5000 [mu] mol / g determined by thermal desorption Containing surface oxygen. The article of claim 1, wherein the activated carbon material has a ratio of narrow microvoid volume to total microvoid volume of about 0.8 or less. The article of claim 1 or 2, wherein the activated carbon material has a BET surface area of at least about 1100 m ² / g. The smoking article of claim 1 or 2, wherein the activated carbon material has a BET surface area of about 1600 m ² / g. 5. A smoking article according to any one of claims 1 to 4, wherein the activated carbon material has a ratio of total micropore volume to total pore volume of about 0.9 or more. 6. A smoking article according to any one of claims 1 to 5, wherein the activated carbon material has a ratio of total micropore volume to total pore volume of at least about 0.95. 7. A smoking article according to any one of claims 1 to 6, wherein the activated carbon material contains surface oxygen at a concentration of about 3000 占 퐉 ol / g or less as determined by elevated temperature desorption. 8. The article of claim 1, wherein the surface oxygen concentration is determined by heating the activated carbon to 950 占 폚 at a rate of 20 占 폚 / min under a helium flow rate of 100 ml / min. 9. A smoking article according to any one of claims 1 to 8, wherein the activated carbon material is present in the filter of the smoking article. 10. The article of claim 9, wherein the filter comprises a cellulose acetate tow. 11. The article of claim 10, wherein the activated carbon is incorporated into or onto the cellulose acetate tow. 11. The article of claim 10, wherein the filter comprises first and second cellulose acetate tow elements, wherein the activated carbon material is disposed between the first and second cellulose acetate tow elements. As a method,
Providing an activated carbon material having a ratio of narrow microvoids to total microvoids volume of about 0.9 or less and having surface oxygen at a concentration of about 5000 占 퐉 ol / g or less as determined by thermal desorption;
Providing a filter material for use in a smoking article; And
And combining the activated carbon material and the filter material to form a filter for a smoking article. 14. The method of claim 13, further comprising incorporating the filter into a smoking article.

Images