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Activated carbon

November 14, 2023

Activated carbon, also called activated charcoal, is a form of carbon commonly used to filter contaminants from water and air, among many other uses. It is processed (activated) to have small, low-volume pores that increase the surface area[1][2] available for adsorption (which is not the same as absorption) or chemical reactions.[3] Activation is analogous to making popcorn from dried corn kernels: popcorn is light, fluffy, and its kernels have a high surface-area-to-volume ratio. Activated is sometimes replaced by active.

Activated carbon

Due to its high degree of microporosity, one gram of activated carbon has a surface area in excess of 3,000 m2 (32,000 sq ft)[1][2][4] as determined by gas adsorption.[1][2][5] Charcoal, before activation, has a specific surface area in the range of 2.0–5.0 m2/g.[6][7] An activation level sufficient for useful application may be obtained solely from high surface area. Further chemical treatment often enhances adsorption properties.

Activated carbon is usually derived from waste products such as coconut husks; waste from paper mills has been studied as a source.[8] These bulk sources are converted into charcoal before being 'activated'. When derived from coal[1][2] it is referred to as activated coal. Activated coke is derived from coke.

Uses edit

Activated carbon is used in methane and hydrogen storage,[1][2] air purification,[9] capacitive deionization, supercapacitive swing adsorption, solvent recovery, decaffeination, gold purification, metal extraction, water purification, medicine, sewage treatment, air filters in respirators, filters in compressed air, teeth whitening, production of hydrogen chloride, edible electronics,[10] and many other applications.

Industrial edit

One major industrial application involves use of activated carbon in metal finishing for purification of electroplating solutions. For example, it is the main purification technique for removing organic impurities from bright nickel plating solutions. A variety of organic chemicals are added to plating solutions for improving their deposit qualities and for enhancing properties like brightness, smoothness, ductility, etc. Due to passage of direct current and electrolytic reactions of anodic oxidation and cathodic reduction, organic additives generate unwanted breakdown products in solution. Their excessive build up can adversely affect plating quality and physical properties of deposited metal. Activated carbon treatment removes such impurities and restores plating performance to the desired level.

Medical edit

Main article: Activated charcoal (medication)
 
Activated charcoal for medical use

Activated carbon is used to treat poisonings and overdoses following oral ingestion. Tablets or capsules of activated carbon are used in many countries as an over-the-counter drug to treat diarrhea, indigestion, and flatulence. However, activated charcoal shows no effect on intestinal gas and diarrhea, and is, ordinarily, medically ineffective if poisoning resulted from ingestion of corrosive agents, boric acid, or petroleum products, and is particularly ineffective against poisonings of strong acids or bases, cyanide, iron, lithium, arsenic, methanol, ethanol or ethylene glycol.[11] Activated carbon will not prevent these chemicals from being absorbed into the human body.[12] It is on the World Health Organization's List of Essential Medicines.[13]

Incorrect application (e.g. into the lungs) results in pulmonary aspiration, which can sometimes be fatal if immediate medical treatment is not initiated.[14]

Analytical chemistry edit

Activated carbon, in 50% w/w combination with celite, is used as stationary phase in low-pressure chromatographic separation of carbohydrates (mono-, di-, tri-saccharides) using ethanol solutions (5–50%) as mobile phase in analytical or preparative protocols.

Activated carbon is useful for extracting the direct oral anticoagulants (DOACs) such as dabigatran, apixaban, rivaroxaban and edoxaban from blood plasma samples.[15] For this purpose it has been made into "minitablets", each containing 5 mg activated carbon for treating 1ml samples of DOAC. Since this activated carbon has no effect on blood clotting factors, heparin or most other anticoagulants [16] this allows a plasma sample to be analyzed for abnormalities otherwise affected by the DOACs.

Environmental edit

 
Activated carbon is usually used in water filtration systems. In this illustration, the activated carbon is in the fourth level (counted from bottom).

Carbon adsorption has numerous applications in removing pollutants from air or water streams both in the field and in industrial processes such as:

During early implementation of the 1974 Safe Drinking Water Act in the US, EPA officials developed a rule that proposed requiring drinking water treatment systems to use granular activated carbon. Because of its high cost, the so-called GAC rule encountered strong opposition across the country from the water supply industry, including the largest water utilities in California. Hence, the agency set aside the rule.[18] Activated carbon filtration is an effective water treatment method due to its multi-functional nature. There are specific types of activated carbon filtration methods and equipment that are indicated – depending upon the contaminants involved.[19]

Activated carbon is also used for the measurement of radon concentration in air.

Agricultural edit

Activated carbon (charcoal) is an allowed substance used by organic farmers in both livestock production and wine making. In livestock production it is used as a pesticide, animal feed additive, processing aid, nonagricultural ingredient and disinfectant.[20] In organic winemaking, activated carbon is allowed for use as a processing agent to adsorb brown color pigments from white grape concentrates.[21] It is sometimes used as biochar.

Distilled alcoholic beverage purification edit

See also: Lincoln County Process

Activated carbon filters (AC filters) can be used to filter vodka and whiskey of organic impurities which can affect color, taste, and odor. Passing an organically impure vodka through an activated carbon filter at the proper flow rate will result in vodka with an identical alcohol content and significantly increased organic purity, as judged by odor and taste.[22]

Fuel storage edit

Research is being done testing various activated carbons' ability to store natural gas[1][2] and hydrogen gas.[1][2] The porous material acts like a sponge for different types of gases. The gas is attracted to the carbon material via Van der Waals forces. Some carbons have been able to achieve bonding energies of 5–10 kJ per mol. The gas may then be desorbed when subjected to higher temperatures and either combusted to do work or in the case of hydrogen gas extracted for use in a hydrogen fuel cell. Gas storage in activated carbons is an appealing gas storage method because the gas can be stored in a low pressure, low mass, low volume environment that would be much more feasible than bulky on-board pressure tanks in vehicles. The United States Department of Energy has specified certain goals to be achieved in the area of research and development of nano-porous carbon materials. All of the goals are yet to be satisfied but numerous institutions, including the ALL-CRAFT program,[1][2][23] are continuing to conduct work in this field.

Gas purification edit

Filters with activated carbon are usually used in compressed air and gas purification to remove oil vapors, odor, and other hydrocarbons from the air. The most common designs use a 1-stage or 2 stage filtration principle in which activated carbon is embedded inside the filter media.

Activated carbon filters are used to retain radioactive gases within the air vacuumed from a nuclear boiling water reactor turbine condenser. The large charcoal beds adsorb these gases and retain them while they rapidly decay to non-radioactive solid species. The solids are trapped in the charcoal particles, while the filtered air passes through.

Chemical purification edit

Activated carbon is commonly used on the laboratory scale to purify solutions of organic molecules containing unwanted colored organic impurities.

Filtration over activated carbon is used in large scale fine chemical and pharmaceutical processes for the same purpose. The carbon is either mixed with the solution then filtered off or immobilized in a filter.

Mercury scrubbing edit

Activated carbon, often infused with sulfur[24] or iodine, is widely used to trap mercury emissions from coal-fired power stations, medical incinerators, and from natural gas at the wellhead. However, despite its effectiveness, activated carbon is expensive to use. [25]

Since it is often not recycled, the mercury-laden activated carbon presents a disposal dilemma.[26] If the activated carbon contains less than 260 ppm mercury, United States federal regulations allow it to be stabilized (for example, trapped in concrete) for landfilling.[citation needed] However, waste containing greater than 260 ppm is considered to be in the high-mercury subcategory and is banned from landfilling (Land-Ban Rule).[citation needed] This material is now accumulating in warehouses and in deep abandoned mines at an estimated rate of 100 tons per year.[citation needed]

The problem of disposal of mercury-laden activated carbon is not unique to the United States. In the Netherlands, this mercury is largely recovered[citation needed] and the activated carbon is disposed of by complete burning, forming carbon dioxide (CO2).

Food additive edit

Activated, food-grade charcoal became a food trend in 2016, being used as an additive to impart a "slightly smoky" taste and a dark coloring to products including hotdogs, ice cream, pizza bases and bagels.[27] People taking medication, including birth control pills and antidepressants,[28] are advised to avoid novelty foods or drinks that use activated charcoal coloring, as it can render the medication ineffective.[29]

Structure of activated carbon edit

The structure of activated carbon has long been a subject of debate. In a book published in 2006,[30] Harry Marsh and Francisco Rodríguez-Reinoso considered more than 15 models for the structure, without coming to a definite conclusion about which was correct. Recent work using aberration-corrected transmission electron microscopy has suggested that activated carbons may have a structure related to that of the fullerenes, with pentagonal and heptagonal carbon rings.[31]

Production edit

Activated carbon is carbon produced from carbonaceous source materials such as bamboo, coconut husk, willow peat, wood, coir, lignite, coal, and petroleum pitch. It can be produced (activated) by one of the following processes:

  1. Physical activation: The source material is developed into activated carbon using hot gases. Air is then introduced to burn out the gasses, creating a graded, screened and de-dusted form of activated carbon. This is generally done by using one or more of the following processes:
    • Carbonization: Material with carbon content is pyrolyzed at temperatures in the range 600–900 °C, usually in an inert atmosphere with gases such as argon or nitrogen
    • Activation/oxidation: Raw material or carbonized material is exposed to oxidizing atmospheres (oxygen or steam) at temperatures above 250 °C, usually in the temperature range of 600–1200 °C. The activation is performed by heating the sample for 1 h in a muffle furnace at 450 °C in the presence of air.[25]
  2. Chemical activation: The carbon material is impregnated with certain chemicals. The chemical is typically an acid, strong base,[1][2] or a salt[32] (phosphoric acid 25%, potassium hydroxide 5%, sodium hydroxide 5%, potassium carbonate 5%,[33] calcium chloride 25%, and zinc chloride 25%). The carbon is then subjected to high temperatures (250–600 °C). It is believed that the temperature activates the carbon at this stage by forcing the material to open up and have more microscopic pores. Chemical activation is preferred to physical activation owing to the lower temperatures, better quality consistency, and shorter time needed for activating the material.[34]

The Dutch company Norit NV, part of the Cabot Corporation, is the largest producer of activated carbon in the world. Haycarb, a Sri Lankan coconut shell-based company controls 16% of the global market share.[35]

Classification edit

Activated carbons are complex products which are difficult to classify on the basis of their behaviour, surface characteristics and other fundamental criteria. However, some broad classification is made for general purposes based on their size, preparation methods, and industrial applications.

Powdered activated carbon (PAC) edit

See also: Powdered activated carbon treatment
 
A micrograph of activated charcoal (R 1) under bright field illumination on a light microscope. Notice the fractal-like shape of the particles hinting at their enormous surface area. Each particle in this image, despite being only around 0.1 mm across, can have a surface area of several square centimeters. The entire image covers a region of approximately 1.1 by 0.7 mm, and the full resolution version is at a scale of 6.236 pixels/μm.

Normally, activated carbons (R 1) are made in particulate form as powders or fine granules less than 1.0 mm in size with an average diameter between 0.15 and 0.25 mm. Thus they present a large surface to volume ratio with a small diffusion distance. Activated carbon (R 1) is defined as the activated carbon particles retained on a 50-mesh sieve (0.297 mm).

Powdered activated carbon (PAC) material is finer material. PAC is made up of crushed or ground carbon particles, 95–100% of which will pass through a designated mesh sieve. The ASTM classifies particles passing through an 80-mesh sieve (0.177 mm) and smaller as PAC. It is not common to use PAC in a dedicated vessel, due to the high head loss that would occur. Instead, PAC is generally added directly to other process units, such as raw water intakes, rapid mix basins, clarifiers, and gravity filters.

Granular activated carbon (GAC) edit

 
A micrograph of activated charcoal (GAC) under scanning electron microscope

Granular activated carbon (GAC) has a relatively larger particle size compared to powdered activated carbon and consequently, presents a smaller external surface. Diffusion of the adsorbate is thus an important factor. These carbons are suitable for adsorption of gases and vapors, because gaseous substances diffuse rapidly. Granulated carbons are used for air filtration and water treatment, as well as for general deodorization and separation of components in flow systems and in rapid mix basins. GAC can be obtained in either granular or extruded form. GAC is designated by sizes such as 8×20, 20×40, or 8×30 for liquid phase applications and 4×6, 4×8 or 4×10 for vapor phase applications. A 20×40 carbon is made of particles that will pass through a U.S. Standard Mesh Size No. 20 sieve (0.84 mm) (generally specified as 85% passing) but be retained on a U.S. Standard Mesh Size No. 40 sieve (0.42 mm) (generally specified as 95% retained). AWWA (1992) B604 uses the 50-mesh sieve (0.297 mm) as the minimum GAC size. The most popular aqueous-phase carbons are the 12×40 and 8×30 sizes because they have a good balance of size, surface area, and head loss characteristics.

Extruded activated carbon (EAC) edit

Extruded activated carbon (EAC) combines powdered activated carbon with a binder, which are fused together and extruded into a cylindrical shaped activated carbon block with diameters from 0.8 to 130 mm. These are mainly used for gas phase applications because of their low pressure drop, high mechanical strength and low dust content. Also sold as CTO filter (Chlorine, Taste, Odor).

Bead activated carbon (BAC) edit

Bead activated carbon (BAC) is made from petroleum pitch and supplied in diameters from approximately 0.35 to 0.80 mm. Similar to EAC, it is also noted for its low pressure drop, high mechanical strength and low dust content, but with a smaller grain size. Its spherical shape makes it preferred for fluidized bed applications such as water filtration.

Impregnated carbon edit

Porous carbons containing several types of inorganic impregnate such as iodine and silver. Cations such as aluminium, manganese, zinc, iron, lithium, and calcium have also been prepared for specific application in air pollution control especially in museums and galleries. Due to its antimicrobial and antiseptic properties, silver loaded activated carbon is used as an adsorbent for purification of domestic water. Drinking water can be obtained from natural water by treating the natural water with a mixture of activated carbon and aluminium hydroxide (Al(OH)3), a flocculating agent. Impregnated carbons are also used for the adsorption of hydrogen sulfide (H2S) and thiols. Adsorption rates for H2S as high as 50% by weight have been reported.[citation needed]

Polymer coated carbon edit

 
Woven activated carbon cloth

This is a process by which a porous carbon can be coated with a biocompatible polymer to give a smooth and permeable coat without blocking the pores. The resulting carbon is useful for hemoperfusion. Hemoperfusion is a treatment technique in which large volumes of the patient's blood are passed over an adsorbent substance in order to remove toxic substances from the blood.

Woven carbon edit

There is a technology of processing technical rayon fiber into activated carbon cloth for carbon filtering. Adsorption capacity of activated cloth is greater than that of activated charcoal (BET theory) surface area: 500–1500 m2/g, pore volume: 0.3–0.8 cm3/g)[citation needed]. Thanks to the different forms of activated material, it can be used in a wide range of applications (supercapacitors, [Odor Absorbers [1], CBRN-defense industry etc.).

Properties edit

A gram of activated carbon can have a surface area in excess of 500 m2 (5,400 sq ft), with 3,000 m2 (32,000 sq ft) being readily achievable.[2][4][5] Carbon aerogels, while more expensive, have even higher surface areas, and are used in special applications.

Under an electron microscope, the high surface-area structures of activated carbon are revealed. Individual particles are intensely convoluted and display various kinds of porosity; there may be many areas where flat surfaces of graphite-like material run parallel to each other,[2] separated by only a few nanometers or so. These micropores provide superb conditions for adsorption to occur, since adsorbing material can interact with many surfaces simultaneously. Tests of adsorption behaviour are usually done with nitrogen gas at 77 K under high vacuum, but in everyday terms activated carbon is perfectly capable of producing the equivalent, by adsorption from its environment, liquid water from steam at 100 °C (212 °F) and a pressure of 1/10,000 of an atmosphere.

James Dewar, the scientist after whom the Dewar (vacuum flask) is named, spent much time studying activated carbon and published a paper regarding its adsorption capacity with regard to gases.[36] In this paper, he discovered that cooling the carbon to liquid nitrogen temperatures allowed it to adsorb significant quantities of numerous air gases, among others, that could then be recollected by simply allowing the carbon to warm again and that coconut based carbon was superior for the effect. He uses oxygen as an example, wherein the activated carbon would typically adsorb the atmospheric concentration (21%) under standard conditions, but release over 80% oxygen if the carbon was first cooled to low temperatures.

Physically, activated carbon binds materials by van der Waals force[34] or London dispersion force.

Activated carbon does not bind well to certain chemicals, including alcohols, diols, strong acids and bases, metals and most inorganics, such as lithium, sodium, iron, lead, arsenic, fluorine, and boric acid.

Activated carbon adsorbs iodine very well. The iodine capacity, mg/g, (ASTM D28 Standard Method test) may be used as an indication of total surface area.

Carbon monoxide is not well adsorbed by activated carbon. This should be of particular concern to those using the material in filters for respirators, fume hoods or other gas control systems as the gas is undetectable to the human senses, toxic to metabolism and neurotoxic.

Substantial lists of the common industrial and agricultural gases adsorbed by activated carbon can be found online.[37]

Activated carbon can be used as a substrate for the application of various chemicals to improve the adsorptive capacity for some inorganic (and problematic organic) compounds such as hydrogen sulfide (H2S), ammonia (NH3), formaldehyde (HCOH), mercury (Hg) and radioactive iodine-131(131I). This property is known as chemisorption.

Iodine number edit

Many carbons preferentially adsorb small molecules. Iodine number is the most fundamental parameter used to characterize activated carbon performance. It is a measure of activity level (higher number indicates higher degree of activation[38]) often reported in mg/g (typical range 500–1200 mg/g). It is a measure of the micropore content of the activated carbon (0 to 20 Å, or up to 2 nm) by adsorption of iodine from solution. It is equivalent to surface area of carbon between 900 and 1100 m2/g. It is the standard measure for liquid-phase applications.

Iodine number is defined as the milligrams of iodine adsorbed by one gram of carbon when the iodine concentration in the residual filtrate is at a concentration of 0.02 normal (i.e. 0.02N). Basically, iodine number is a measure of the iodine adsorbed in the pores and, as such, is an indication of the pore volume available in the activated carbon of interest. Typically, water-treatment carbons have iodine numbers ranging from 600 to 1100. Frequently, this parameter is used to determine the degree of exhaustion of a carbon in use. However, this practice should be viewed with caution, as chemical interactions with the adsorbate may affect the iodine uptake, giving false results. Thus, the use of iodine number as a measure of the degree of exhaustion of a carbon bed can only be recommended if it has been shown to be free of chemical interactions with adsorbates and if an experimental correlation between iodine number and the degree of exhaustion has been determined for the particular application.

Molasses edit

Some carbons are more adept at adsorbing large molecules. Molasses number or molasses efficiency is a measure of the mesopore content of the activated carbon (greater than 20 Å, or larger than 2 nm) by adsorption of molasses from solution. A high molasses number indicates a high adsorption of big molecules (range 95–600). Caramel dp (decolorizing performance) is similar to molasses number. Molasses efficiency is reported as a percentage (range 40%–185%) and parallels molasses number (600 = 185%, 425 = 85%). The European molasses number (range 525–110) is inversely related to the North American molasses number.

Molasses Number is a measure of the degree of decolorization of a standard molasses solution that has been diluted and standardized against standardized activated carbon. Due to the size of color bodies, the molasses number represents the potential pore volume available for larger adsorbing species. As all of the pore volume may not be available for adsorption in a particular waste water application, and as some of the adsorbate may enter smaller pores, it is not a good measure of the worth of a particular activated carbon for a specific application. Frequently, this parameter is useful in evaluating a series of active carbons for their rates of adsorption. Given two active carbons with similar pore volumes for adsorption, the one having the higher molasses number will usually have larger feeder pores resulting in more efficient transfer of adsorbate into the adsorption space.

Tannin edit

Tannins are a mixture of large and medium size molecules. Carbons with a combination of macropores and mesopores adsorb tannins. The ability of a carbon to adsorb tannins is reported in parts per million concentration (range 200 ppm–362 ppm).

Methylene blue edit

Some carbons have a mesopore (20 Å to 50 Å, or 2 to 5 nm) structure which adsorbs medium size molecules, such as the dye methylene blue. Methylene blue adsorption is reported in g/100g (range 11–28 g/100g).[39]

Dechlorination edit

Some carbons are evaluated based on the dechlorination half-life length, which measures the chlorine-removal efficiency of activated carbon. The dechlorination half-value length is the depth of carbon required to reduce the chlorine concentration by 50%. A lower half-value length indicates superior performance.[40]

Apparent density edit

The solid or skeletal density of activated carbons will typically range between 2000 and 2100 kg/m3 (125–130 lbs./cubic foot). However, a large part of an activated carbon sample will consist of air space between particles, and the actual or apparent density will therefore be lower, typically 400 to 500 kg/m3 (25–31 lbs./cubic foot).[41]

Higher density provides greater volume activity and normally indicates better-quality activated carbon. ASTM D 2854 -09 (2014) is used to determine the apparent density of activated carbon.

Hardness/abrasion number edit

It is a measure of the activated carbon's resistance to attrition. It is an important indicator of activated carbon to maintain its physical integrity and withstand frictional forces. There are large differences in the hardness of activated carbons, depending on the raw material and activity levels (porosity).

Ash content edit

Ash reduces the overall activity of activated carbon and reduces the efficiency of reactivation: the amount is exclusively dependent on the base raw material used to produce the activated carbon (e.g. coconut, wood, coal, etc.). The metal oxides (Fe2O3) can leach out of activated carbon resulting in discoloration. Acid/water-soluble ash content is more significant than total ash content. Soluble ash content can be very important for aquarists, as ferric oxide can promote algal growths. A carbon with a low soluble ash content should be used for marine, freshwater fish and reef tanks to avoid heavy metal poisoning and excess plant/algal growth. ASTM (D2866 Standard Method test) is used to determine the ash content of activated carbon.

Carbon tetrachloride activity edit

Measurement of the porosity of an activated carbon by the adsorption of saturated carbon tetrachloride vapour.

Particle size distribution edit

The finer the particle size of an activated carbon, the better the access to the surface area and the faster the rate of adsorption kinetics. In vapour phase systems this needs to be considered against pressure drop, which will affect energy cost. Careful consideration of particle size distribution can provide significant operating benefits. However, in the case of using activated carbon for adsorption of minerals such as gold, the particle size should be in the range of 3.35–1.4 millimetres (0.132–0.055 in). Activated carbon with particle size less than 1 mm would not be suitable for elution (the stripping of mineral from an activated carbon).

Modification of properties and reactivity edit

Acid-base, oxidation-reduction and specific adsorption characteristics are strongly dependent on the composition of the surface functional groups.[42]

The surface of conventional activated carbon is reactive, capable of oxidation by atmospheric oxygen and oxygen plasma[43][44][45][46][47][48][49][50] steam,[51][52][53] and also carbon dioxide[47] and ozone.[54][55][56]

Oxidation in the liquid phase is caused by a wide range of reagents (HNO3, H2O2, KMnO4).[57][58][59]

Through the formation of a large number of basic and acidic groups on the surface of oxidized carbon to sorption and other properties can differ significantly from the unmodified forms.[42]

Activated carbon can be nitrogenated by natural products or polymers[60][61] or processing of carbon with nitrogenating reagents.[62][63][64]

Activated carbon can interact with chlorine,[65][66] bromine[67] and fluorine.[68]

Surface of activated carbon, like other carbon materials can be fluoralkylated by treatment with (per)fluoropolyether peroxide[69] in a liquid phase, or with wide range of fluoroorganic substances by CVD-method.[70] Such materials combine high hydrophobicity and chemical stability with electrical and thermal conductivity and can be used as electrode material for super capacitors.[71]

Sulfonic acid functional groups can be attached to activated carbon to give "starbons" which can be used to selectively catalyse the esterification of fatty acids.[72] Formation of such activated carbons from halogenated precursors gives a more effective catalyst which is thought to be a result of remaining halogens improving stability.[73] It is reported about synthesis of activated carbon with chemically grafted superacid sites –CF2SO3H.[74]

Some of the chemical properties of activated carbon have been attributed to presence of the surface active carbon double bond.[56][75]

The Polyani adsorption theory is a popular method for analyzing adsorption of various organic substances to their surface.

Examples of adsorption edit

Heterogeneous catalysis edit

The most commonly encountered form of chemisorption in industry, occurs when a solid catalyst interacts with a gaseous feedstock, the reactant/s. The adsorption of reactant/s to the catalyst surface creates a chemical bond, altering the electron density around the reactant molecule and allowing it to undergo reactions that would not normally be available to it.

Reactivation and regeneration edit

 
World's largest reactivation plant located in Feluy, Belgium.
 
Activated carbon reactivation center in Roeselare, Belgium.

The reactivation or the regeneration of activated carbons involves restoring the adsorptive capacity of saturated activated carbon by desorbing adsorbed contaminants on the activated carbon surface.

Thermal reactivation edit

The most common regeneration technique employed in industrial processes is thermal reactivation.[76] The thermal regeneration process generally follows three steps:[77]

  • Adsorbent drying at approximately 105 °C (221 °F)
  • High temperature desorption and decomposition (500–900 °C (932–1,652 °F)) under an inert atmosphere
  • Residual organic gasification by a non-oxidising gas (steam or carbon dioxide) at elevated temperatures (800 °C (1,470 °F))

The heat treatment stage utilises the exothermic nature of adsorption and results in desorption, partial cracking and polymerization of the adsorbed organics. The final step aims to remove charred organic residue formed in the porous structure in the previous stage and re-expose the porous carbon structure regenerating its original surface characteristics. After treatment the adsorption column can be reused. Per adsorption-thermal regeneration cycle between 5–15 wt% of the carbon bed is burnt off resulting in a loss of adsorptive capacity.[78] Thermal regeneration is a high energy process due to the high required temperatures making it both an energetically and commercially expensive process.[77] Plants that rely on thermal regeneration of activated carbon have to be of a certain size before it is economically viable to have regeneration facilities onsite. As a result, it is common for smaller waste treatment sites to ship their activated carbon cores to specialised facilities for regeneration.[79]

Other regeneration techniques edit

Current concerns with the high energy/cost nature of thermal regeneration of activated carbon has encouraged research into alternative regeneration methods to reduce the environmental impact of such processes. Though several of the regeneration techniques cited have remained areas of purely academic research, some alternatives to thermal regeneration systems have been employed in industry. Current alternative regeneration methods are:

See also edit

References edit

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  2. ^ a b c d e f g h i j k Soo, Yuchoong; Chada, Nagaraju; Beckner, Matthew; Romanos, Jimmy; Burress, Jacob; Pfeifer, Peter (2013-03-20). "Adsorbed Methane Film Properties in Nanoporous Carbon Monoliths". Bulletin of the American Physical Society. 58 (1). M38.001. Bibcode:2013APS..MARM38001S.
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External links edit

 
Wikimedia Commons has media related to Activated carbon.
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November 14, 2023
activated, carbon, also, called, activated, charcoal, form, carbon, commonly, used, filter, contaminants, from, water, among, many, other, uses, processed, activated, have, small, volume, pores, that, increase, surface, area, available, adsorption, which, same. Activated carbon also called activated charcoal is a form of carbon commonly used to filter contaminants from water and air among many other uses It is processed activated to have small low volume pores that increase the surface area 1 2 available for adsorption which is not the same as absorption or chemical reactions 3 Activation is analogous to making popcorn from dried corn kernels popcorn is light fluffy and its kernels have a high surface area to volume ratio Activated is sometimes replaced by active Activated carbonDue to its high degree of microporosity one gram of activated carbon has a surface area in excess of 3 000 m2 32 000 sq ft 1 2 4 as determined by gas adsorption 1 2 5 Charcoal before activation has a specific surface area in the range of 2 0 5 0 m2 g 6 7 An activation level sufficient for useful application may be obtained solely from high surface area Further chemical treatment often enhances adsorption properties Activated carbon is usually derived from waste products such as coconut husks waste from paper mills has been studied as a source 8 These bulk sources are converted into charcoal before being activated When derived from coal 1 2 it is referred to as activated coal Activated coke is derived from coke Contents 1 Uses 1 1 Industrial 1 2 Medical 1 3 Analytical chemistry 1 4 Environmental 1 5 Agricultural 1 6 Distilled alcoholic beverage purification 1 7 Fuel storage 1 8 Gas purification 1 9 Chemical purification 1 10 Mercury scrubbing 1 11 Food additive 2 Structure of activated carbon 3 Production 4 Classification 4 1 Powdered activated carbon PAC 4 2 Granular activated carbon GAC 4 3 Extruded activated carbon EAC 4 4 Bead activated carbon BAC 4 5 Impregnated carbon 4 6 Polymer coated carbon 4 7 Woven carbon 5 Properties 5 1 Iodine number 5 2 Molasses 5 3 Tannin 5 4 Methylene blue 5 5 Dechlorination 5 6 Apparent density 5 7 Hardness abrasion number 5 8 Ash content 5 9 Carbon tetrachloride activity 5 10 Particle size distribution 6 Modification of properties and reactivity 7 Examples of adsorption 7 1 Heterogeneous catalysis 8 Reactivation and regeneration 8 1 Thermal reactivation 8 2 Other regeneration techniques 9 See also 10 References 11 External linksUses editActivated carbon is used in methane and hydrogen storage 1 2 air purification 9 capacitive deionization supercapacitive swing adsorption solvent recovery decaffeination gold purification metal extraction water purification medicine sewage treatment air filters in respirators filters in compressed air teeth whitening production of hydrogen chloride edible electronics 10 and many other applications Industrial edit One major industrial application involves use of activated carbon in metal finishing for purification of electroplating solutions For example it is the main purification technique for removing organic impurities from bright nickel plating solutions A variety of organic chemicals are added to plating solutions for improving their deposit qualities and for enhancing properties like brightness smoothness ductility etc Due to passage of direct current and electrolytic reactions of anodic oxidation and cathodic reduction organic additives generate unwanted breakdown products in solution Their excessive build up can adversely affect plating quality and physical properties of deposited metal Activated carbon treatment removes such impurities and restores plating performance to the desired level Medical edit Main article Activated charcoal medication nbsp Activated charcoal for medical useActivated carbon is used to treat poisonings and overdoses following oral ingestion Tablets or capsules of activated carbon are used in many countries as an over the counter drug to treat diarrhea indigestion and flatulence However activated charcoal shows no effect on intestinal gas and diarrhea and is ordinarily medically ineffective if poisoning resulted from ingestion of corrosive agents boric acid or petroleum products and is particularly ineffective against poisonings of strong acids or bases cyanide iron lithium arsenic methanol ethanol or ethylene glycol 11 Activated carbon will not prevent these chemicals from being absorbed into the human body 12 It is on the World Health Organization s List of Essential Medicines 13 Incorrect application e g into the lungs results in pulmonary aspiration which can sometimes be fatal if immediate medical treatment is not initiated 14 Analytical chemistry edit Activated carbon in 50 w w combination with celite is used as stationary phase in low pressure chromatographic separation of carbohydrates mono di tri saccharides using ethanol solutions 5 50 as mobile phase in analytical or preparative protocols Activated carbon is useful for extracting the direct oral anticoagulants DOACs such as dabigatran apixaban rivaroxaban and edoxaban from blood plasma samples 15 For this purpose it has been made into minitablets each containing 5 mg activated carbon for treating 1ml samples of DOAC Since this activated carbon has no effect on blood clotting factors heparin or most other anticoagulants 16 this allows a plasma sample to be analyzed for abnormalities otherwise affected by the DOACs Environmental edit nbsp Activated carbon is usually used in water filtration systems In this illustration the activated carbon is in the fourth level counted from bottom Carbon adsorption has numerous applications in removing pollutants from air or water streams both in the field and in industrial processes such as Spill cleanup Groundwater remediation Drinking water filtration Wastewater treatment Air purification Volatile organic compounds capture from painting dry cleaning gasoline dispensing operations and other processes Volatile organic compounds recovery SRU Solvent Recovery Unit SRP Solvent Recovery Plant SRS Solvent Recovery System from flexible packaging converting coating and other processes 17 During early implementation of the 1974 Safe Drinking Water Act in the US EPA officials developed a rule that proposed requiring drinking water treatment systems to use granular activated carbon Because of its high cost the so called GAC rule encountered strong opposition across the country from the water supply industry including the largest water utilities in California Hence the agency set aside the rule 18 Activated carbon filtration is an effective water treatment method due to its multi functional nature There are specific types of activated carbon filtration methods and equipment that are indicated depending upon the contaminants involved 19 Activated carbon is also used for the measurement of radon concentration in air Agricultural edit Activated carbon charcoal is an allowed substance used by organic farmers in both livestock production and wine making In livestock production it is used as a pesticide animal feed additive processing aid nonagricultural ingredient and disinfectant 20 In organic winemaking activated carbon is allowed for use as a processing agent to adsorb brown color pigments from white grape concentrates 21 It is sometimes used as biochar Distilled alcoholic beverage purification edit See also Lincoln County Process Activated carbon filters AC filters can be used to filter vodka and whiskey of organic impurities which can affect color taste and odor Passing an organically impure vodka through an activated carbon filter at the proper flow rate will result in vodka with an identical alcohol content and significantly increased organic purity as judged by odor and taste 22 Fuel storage edit Research is being done testing various activated carbons ability to store natural gas 1 2 and hydrogen gas 1 2 The porous material acts like a sponge for different types of gases The gas is attracted to the carbon material via Van der Waals forces Some carbons have been able to achieve bonding energies of 5 10 kJ per mol The gas may then be desorbed when subjected to higher temperatures and either combusted to do work or in the case of hydrogen gas extracted for use in a hydrogen fuel cell Gas storage in activated carbons is an appealing gas storage method because the gas can be stored in a low pressure low mass low volume environment that would be much more feasible than bulky on board pressure tanks in vehicles The United States Department of Energy has specified certain goals to be achieved in the area of research and development of nano porous carbon materials All of the goals are yet to be satisfied but numerous institutions including the ALL CRAFT program 1 2 23 are continuing to conduct work in this field Gas purification edit Filters with activated carbon are usually used in compressed air and gas purification to remove oil vapors odor and other hydrocarbons from the air The most common designs use a 1 stage or 2 stage filtration principle in which activated carbon is embedded inside the filter media Activated carbon filters are used to retain radioactive gases within the air vacuumed from a nuclear boiling water reactor turbine condenser The large charcoal beds adsorb these gases and retain them while they rapidly decay to non radioactive solid species The solids are trapped in the charcoal particles while the filtered air passes through Chemical purification edit Activated carbon is commonly used on the laboratory scale to purify solutions of organic molecules containing unwanted colored organic impurities Filtration over activated carbon is used in large scale fine chemical and pharmaceutical processes for the same purpose The carbon is either mixed with the solution then filtered off or immobilized in a filter Mercury scrubbing edit Activated carbon often infused with sulfur 24 or iodine is widely used to trap mercury emissions from coal fired power stations medical incinerators and from natural gas at the wellhead However despite its effectiveness activated carbon is expensive to use 25 Since it is often not recycled the mercury laden activated carbon presents a disposal dilemma 26 If the activated carbon contains less than 260 ppm mercury United States federal regulations allow it to be stabilized for example trapped in concrete for landfilling citation needed However waste containing greater than 260 ppm is considered to be in the high mercury subcategory and is banned from landfilling Land Ban Rule citation needed This material is now accumulating in warehouses and in deep abandoned mines at an estimated rate of 100 tons per year citation needed The problem of disposal of mercury laden activated carbon is not unique to the United States In the Netherlands this mercury is largely recovered citation needed and the activated carbon is disposed of by complete burning forming carbon dioxide CO2 Food additive edit Activated food grade charcoal became a food trend in 2016 being used as an additive to impart a slightly smoky taste and a dark coloring to products including hotdogs ice cream pizza bases and bagels 27 People taking medication including birth control pills and antidepressants 28 are advised to avoid novelty foods or drinks that use activated charcoal coloring as it can render the medication ineffective 29 Structure of activated carbon editThe structure of activated carbon has long been a subject of debate In a book published in 2006 30 Harry Marsh and Francisco Rodriguez Reinoso considered more than 15 models for the structure without coming to a definite conclusion about which was correct Recent work using aberration corrected transmission electron microscopy has suggested that activated carbons may have a structure related to that of the fullerenes with pentagonal and heptagonal carbon rings 31 Production editActivated carbon is carbon produced from carbonaceous source materials such as bamboo coconut husk willow peat wood coir lignite coal and petroleum pitch It can be produced activated by one of the following processes Physical activation The source material is developed into activated carbon using hot gases Air is then introduced to burn out the gasses creating a graded screened and de dusted form of activated carbon This is generally done by using one or more of the following processes Carbonization Material with carbon content is pyrolyzed at temperatures in the range 600 900 C usually in an inert atmosphere with gases such as argon or nitrogen Activation oxidation Raw material or carbonized material is exposed to oxidizing atmospheres oxygen or steam at temperatures above 250 C usually in the temperature range of 600 1200 C The activation is performed by heating the sample for 1 h in a muffle furnace at 450 C in the presence of air 25 Chemical activation The carbon material is impregnated with certain chemicals The chemical is typically an acid strong base 1 2 or a salt 32 phosphoric acid 25 potassium hydroxide 5 sodium hydroxide 5 potassium carbonate 5 33 calcium chloride 25 and zinc chloride 25 The carbon is then subjected to high temperatures 250 600 C It is believed that the temperature activates the carbon at this stage by forcing the material to open up and have more microscopic pores Chemical activation is preferred to physical activation owing to the lower temperatures better quality consistency and shorter time needed for activating the material 34 The Dutch company Norit NV part of the Cabot Corporation is the largest producer of activated carbon in the world Haycarb a Sri Lankan coconut shell based company controls 16 of the global market share 35 Classification editActivated carbons are complex products which are difficult to classify on the basis of their behaviour surface characteristics and other fundamental criteria However some broad classification is made for general purposes based on their size preparation methods and industrial applications Powdered activated carbon PAC edit See also Powdered activated carbon treatment nbsp A micrograph of activated charcoal R 1 under bright field illumination on a light microscope Notice the fractal like shape of the particles hinting at their enormous surface area Each particle in this image despite being only around 0 1 mm across can have a surface area of several square centimeters The entire image covers a region of approximately 1 1 by 0 7 mm and the full resolution version is at a scale of 6 236 pixels mm Normally activated carbons R 1 are made in particulate form as powders or fine granules less than 1 0 mm in size with an average diameter between 0 15 and 0 25 mm Thus they present a large surface to volume ratio with a small diffusion distance Activated carbon R 1 is defined as the activated carbon particles retained on a 50 mesh sieve 0 297 mm Powdered activated carbon PAC material is finer material PAC is made up of crushed or ground carbon particles 95 100 of which will pass through a designated mesh sieve The ASTM classifies particles passing through an 80 mesh sieve 0 177 mm and smaller as PAC It is not common to use PAC in a dedicated vessel due to the high head loss that would occur Instead PAC is generally added directly to other process units such as raw water intakes rapid mix basins clarifiers and gravity filters Granular activated carbon GAC edit nbsp A micrograph of activated charcoal GAC under scanning electron microscopeGranular activated carbon GAC has a relatively larger particle size compared to powdered activated carbon and consequently presents a smaller external surface Diffusion of the adsorbate is thus an important factor These carbons are suitable for adsorption of gases and vapors because gaseous substances diffuse rapidly Granulated carbons are used for air filtration and water treatment as well as for general deodorization and separation of components in flow systems and in rapid mix basins GAC can be obtained in either granular or extruded form GAC is designated by sizes such as 8 20 20 40 or 8 30 for liquid phase applications and 4 6 4 8 or 4 10 for vapor phase applications A 20 40 carbon is made of particles that will pass through a U S Standard Mesh Size No 20 sieve 0 84 mm generally specified as 85 passing but be retained on a U S Standard Mesh Size No 40 sieve 0 42 mm generally specified as 95 retained AWWA 1992 B604 uses the 50 mesh sieve 0 297 mm as the minimum GAC size The most popular aqueous phase carbons are the 12 40 and 8 30 sizes because they have a good balance of size surface area and head loss characteristics Extruded activated carbon EAC edit Extruded activated carbon EAC combines powdered activated carbon with a binder which are fused together and extruded into a cylindrical shaped activated carbon block with diameters from 0 8 to 130 mm These are mainly used for gas phase applications because of their low pressure drop high mechanical strength and low dust content Also sold as CTO filter Chlorine Taste Odor Bead activated carbon BAC edit Bead activated carbon BAC is made from petroleum pitch and supplied in diameters from approximately 0 35 to 0 80 mm Similar to EAC it is also noted for its low pressure drop high mechanical strength and low dust content but with a smaller grain size Its spherical shape makes it preferred for fluidized bed applications such as water filtration Impregnated carbon edit Porous carbons containing several types of inorganic impregnate such as iodine and silver Cations such as aluminium manganese zinc iron lithium and calcium have also been prepared for specific application in air pollution control especially in museums and galleries Due to its antimicrobial and antiseptic properties silver loaded activated carbon is used as an adsorbent for purification of domestic water Drinking water can be obtained from natural water by treating the natural water with a mixture of activated carbon and aluminium hydroxide Al OH 3 a flocculating agent Impregnated carbons are also used for the adsorption of hydrogen sulfide H2S and thiols Adsorption rates for H2S as high as 50 by weight have been reported citation needed Polymer coated carbon edit nbsp Woven activated carbon clothThis is a process by which a porous carbon can be coated with a biocompatible polymer to give a smooth and permeable coat without blocking the pores The resulting carbon is useful for hemoperfusion Hemoperfusion is a treatment technique in which large volumes of the patient s blood are passed over an adsorbent substance in order to remove toxic substances from the blood Woven carbon edit There is a technology of processing technical rayon fiber into activated carbon cloth for carbon filtering Adsorption capacity of activated cloth is greater than that of activated charcoal BET theory surface area 500 1500 m2 g pore volume 0 3 0 8 cm3 g citation needed Thanks to the different forms of activated material it can be used in a wide range of applications supercapacitors Odor Absorbers 1 CBRN defense industry etc Properties editA gram of activated carbon can have a surface area in excess of 500 m2 5 400 sq ft with 3 000 m2 32 000 sq ft being readily achievable 2 4 5 Carbon aerogels while more expensive have even higher surface areas and are used in special applications Under an electron microscope the high surface area structures of activated carbon are revealed Individual particles are intensely convoluted and display various kinds of porosity there may be many areas where flat surfaces of graphite like material run parallel to each other 2 separated by only a few nanometers or so These micropores provide superb conditions for adsorption to occur since adsorbing material can interact with many surfaces simultaneously Tests of adsorption behaviour are usually done with nitrogen gas at 77 K under high vacuum but in everyday terms activated carbon is perfectly capable of producing the equivalent by adsorption from its environment liquid water from steam at 100 C 212 F and a pressure of 1 10 000 of an atmosphere James Dewar the scientist after whom the Dewar vacuum flask is named spent much time studying activated carbon and published a paper regarding its adsorption capacity with regard to gases 36 In this paper he discovered that cooling the carbon to liquid nitrogen temperatures allowed it to adsorb significant quantities of numerous air gases among others that could then be recollected by simply allowing the carbon to warm again and that coconut based carbon was superior for the effect He uses oxygen as an example wherein the activated carbon would typically adsorb the atmospheric concentration 21 under standard conditions but release over 80 oxygen if the carbon was first cooled to low temperatures Physically activated carbon binds materials by van der Waals force 34 or London dispersion force Activated carbon does not bind well to certain chemicals including alcohols diols strong acids and bases metals and most inorganics such as lithium sodium iron lead arsenic fluorine and boric acid Activated carbon adsorbs iodine very well The iodine capacity mg g ASTM D28 Standard Method test may be used as an indication of total surface area Carbon monoxide is not well adsorbed by activated carbon This should be of particular concern to those using the material in filters for respirators fume hoods or other gas control systems as the gas is undetectable to the human senses toxic to metabolism and neurotoxic Substantial lists of the common industrial and agricultural gases adsorbed by activated carbon can be found online 37 Activated carbon can be used as a substrate for the application of various chemicals to improve the adsorptive capacity for some inorganic and problematic organic compounds such as hydrogen sulfide H2S ammonia NH3 formaldehyde HCOH mercury Hg and radioactive iodine 131 131I This property is known as chemisorption Iodine number edit Many carbons preferentially adsorb small molecules Iodine number is the most fundamental parameter used to characterize activated carbon performance It is a measure of activity level higher number indicates higher degree of activation 38 often reported in mg g typical range 500 1200 mg g It is a measure of the micropore content of the activated carbon 0 to 20 A or up to 2 nm by adsorption of iodine from solution It is equivalent to surface area of carbon between 900 and 1100 m2 g It is the standard measure for liquid phase applications Iodine number is defined as the milligrams of iodine adsorbed by one gram of carbon when the iodine concentration in the residual filtrate is at a concentration of 0 02 normal i e 0 02N Basically iodine number is a measure of the iodine adsorbed in the pores and as such is an indication of the pore volume available in the activated carbon of interest Typically water treatment carbons have iodine numbers ranging from 600 to 1100 Frequently this parameter is used to determine the degree of exhaustion of a carbon in use However this practice should be viewed with caution as chemical interactions with the adsorbate may affect the iodine uptake giving false results Thus the use of iodine number as a measure of the degree of exhaustion of a carbon bed can only be recommended if it has been shown to be free of chemical interactions with adsorbates and if an experimental correlation between iodine number and the degree of exhaustion has been determined for the particular application Molasses edit Some carbons are more adept at adsorbing large molecules Molasses number or molasses efficiency is a measure of the mesopore content of the activated carbon greater than 20 A or larger than 2 nm by adsorption of molasses from solution A high molasses number indicates a high adsorption of big molecules range 95 600 Caramel dp decolorizing performance is similar to molasses number Molasses efficiency is reported as a percentage range 40 185 and parallels molasses number 600 185 425 85 The European molasses number range 525 110 is inversely related to the North American molasses number Molasses Number is a measure of the degree of decolorization of a standard molasses solution that has been diluted and standardized against standardized activated carbon Due to the size of color bodies the molasses number represents the potential pore volume available for larger adsorbing species As all of the pore volume may not be available for adsorption in a particular waste water application and as some of the adsorbate may enter smaller pores it is not a good measure of the worth of a particular activated carbon for a specific application Frequently this parameter is useful in evaluating a series of active carbons for their rates of adsorption Given two active carbons with similar pore volumes for adsorption the one having the higher molasses number will usually have larger feeder pores resulting in more efficient transfer of adsorbate into the adsorption space Tannin edit Tannins are a mixture of large and medium size molecules Carbons with a combination of macropores and mesopores adsorb tannins The ability of a carbon to adsorb tannins is reported in parts per million concentration range 200 ppm 362 ppm Methylene blue edit Some carbons have a mesopore 20 A to 50 A or 2 to 5 nm structure which adsorbs medium size molecules such as the dye methylene blue Methylene blue adsorption is reported in g 100g range 11 28 g 100g 39 Dechlorination edit Some carbons are evaluated based on the dechlorination half life length which measures the chlorine removal efficiency of activated carbon The dechlorination half value length is the depth of carbon required to reduce the chlorine concentration by 50 A lower half value length indicates superior performance 40 Apparent density edit The solid or skeletal density of activated carbons will typically range between 2000 and 2100 kg m3 125 130 lbs cubic foot However a large part of an activated carbon sample will consist of air space between particles and the actual or apparent density will therefore be lower typically 400 to 500 kg m3 25 31 lbs cubic foot 41 Higher density provides greater volume activity and normally indicates better quality activated carbon ASTM D 2854 09 2014 is used to determine the apparent density of activated carbon Hardness abrasion number edit It is a measure of the activated carbon s resistance to attrition It is an important indicator of activated carbon to maintain its physical integrity and withstand frictional forces There are large differences in the hardness of activated carbons depending on the raw material and activity levels porosity Ash content edit Ash reduces the overall activity of activated carbon and reduces the efficiency of reactivation the amount is exclusively dependent on the base raw material used to produce the activated carbon e g coconut wood coal etc The metal oxides Fe2O3 can leach out of activated carbon resulting in discoloration Acid water soluble ash content is more significant than total ash content Soluble ash content can be very important for aquarists as ferric oxide can promote algal growths A carbon with a low soluble ash content should be used for marine freshwater fish and reef tanks to avoid heavy metal poisoning and excess plant algal growth ASTM D2866 Standard Method test is used to determine the ash content of activated carbon Carbon tetrachloride activity edit Measurement of the porosity of an activated carbon by the adsorption of saturated carbon tetrachloride vapour Particle size distribution edit The finer the particle size of an activated carbon the better the access to the surface area and the faster the rate of adsorption kinetics In vapour phase systems this needs to be considered against pressure drop which will affect energy cost Careful consideration of particle size distribution can provide significant operating benefits However in the case of using activated carbon for adsorption of minerals such as gold the particle size should be in the range of 3 35 1 4 millimetres 0 132 0 055 in Activated carbon with particle size less than 1 mm would not be suitable for elution the stripping of mineral from an activated carbon Modification of properties and reactivity editAcid base oxidation reduction and specific adsorption characteristics are strongly dependent on the composition of the surface functional groups 42 The surface of conventional activated carbon is reactive capable of oxidation by atmospheric oxygen and oxygen plasma 43 44 45 46 47 48 49 50 steam 51 52 53 and also carbon dioxide 47 and ozone 54 55 56 Oxidation in the liquid phase is caused by a wide range of reagents HNO3 H2O2 KMnO4 57 58 59 Through the formation of a large number of basic and acidic groups on the surface of oxidized carbon to sorption and other properties can differ significantly from the unmodified forms 42 Activated carbon can be nitrogenated by natural products or polymers 60 61 or processing of carbon with nitrogenating reagents 62 63 64 Activated carbon can interact with chlorine 65 66 bromine 67 and fluorine 68 Surface of activated carbon like other carbon materials can be fluoralkylated by treatment with per fluoropolyether peroxide 69 in a liquid phase or with wide range of fluoroorganic substances by CVD method 70 Such materials combine high hydrophobicity and chemical stability with electrical and thermal conductivity and can be used as electrode material for super capacitors 71 Sulfonic acid functional groups can be attached to activated carbon to give starbons which can be used to selectively catalyse the esterification of fatty acids 72 Formation of such activated carbons from halogenated precursors gives a more effective catalyst which is thought to be a result of remaining halogens improving stability 73 It is reported about synthesis of activated carbon with chemically grafted superacid sites CF2SO3H 74 Some of the chemical properties of activated carbon have been attributed to presence of the surface active carbon double bond 56 75 The Polyani adsorption theory is a popular method for analyzing adsorption of various organic substances to their surface Examples of adsorption editHeterogeneous catalysis edit The most commonly encountered form of chemisorption in industry occurs when a solid catalyst interacts with a gaseous feedstock the reactant s The adsorption of reactant s to the catalyst surface creates a chemical bond altering the electron density around the reactant molecule and allowing it to undergo reactions that would not normally be available to it Reactivation and regeneration edit nbsp World s largest reactivation plant located in Feluy Belgium nbsp Activated carbon reactivation center in Roeselare Belgium The reactivation or the regeneration of activated carbons involves restoring the adsorptive capacity of saturated activated carbon by desorbing adsorbed contaminants on the activated carbon surface Thermal reactivation edit The most common regeneration technique employed in industrial processes is thermal reactivation 76 The thermal regeneration process generally follows three steps 77 Adsorbent drying at approximately 105 C 221 F High temperature desorption and decomposition 500 900 C 932 1 652 F under an inert atmosphere Residual organic gasification by a non oxidising gas steam or carbon dioxide at elevated temperatures 800 C 1 470 F The heat treatment stage utilises the exothermic nature of adsorption and results in desorption partial cracking and polymerization of the adsorbed organics The final step aims to remove charred organic residue formed in the porous structure in the previous stage and re expose the porous carbon structure regenerating its original surface characteristics After treatment the adsorption column can be reused Per adsorption thermal regeneration cycle between 5 15 wt of the carbon bed is burnt off resulting in a loss of adsorptive capacity 78 Thermal regeneration is a high energy process due to the high required temperatures making it both an energetically and commercially expensive process 77 Plants that rely on thermal regeneration of activated carbon have to be of a certain size before it is economically viable to have regeneration facilities onsite As a result it is common for smaller waste treatment sites to ship their activated carbon cores to specialised facilities for regeneration 79 Other regeneration techniques edit Current concerns with the high energy cost nature of thermal regeneration of activated carbon has encouraged research into alternative regeneration methods to reduce the environmental impact of such processes Though several of the regeneration techniques cited have remained areas of purely academic research some alternatives to thermal regeneration systems have been employed in industry Current alternative regeneration methods are TSA thermal swing adsorption and or PSA pressure swing adsorption processes through convection heat transfer using steam 80 hot inert gas typically heated nitrogen 150 250 C 302 482 F 81 or vacuum T VSA or TVSA combining TSA and VSA processes 82 in situ regeneration MWR microwave regeneration 83 Chemical and solvent regeneration 84 Microbial regeneration 85 Electrochemical regeneration 86 Ultrasonic regeneration 87 Wet air oxidation 88 See also edit nbsp Medicine portal nbsp Chemistry portalActivated charcoal cleanse Biochar Bamboo charcoal Binchōtan Bone char Carbon filtering Carbocatalysis Conjugated microporous polymer Hydrogen storage Kvaerner process Onboard refueling vapor recoveryReferences edit a b c d e f g h i Chada Nagaraju Romanos Jimmy Hilton Ramsey Suppes Galen Burress Jacob Pfeifer Peter 2012 03 01 Activated carbon monoliths for methane storage Bulletin of the American Physical Society 57 1 W33 012 Bibcode 2012APS MARW33012C a b c d e f g h i j k Soo Yuchoong Chada Nagaraju Beckner Matthew Romanos Jimmy Burress Jacob Pfeifer Peter 2013 03 20 Adsorbed Methane Film Properties in Nanoporous Carbon Monoliths Bulletin of the American Physical Society 58 1 M38 001 Bibcode 2013APS MARM38001S Properties of Activated Carbon CPL Caron Link accessed 2008 05 02 Archived from the original on 19 June 2012 Retrieved 13 October 2014 a b Dillon Edward C Wilton John H Barlow Jared C Watson William A 1989 05 01 Large surface area activated charcoal and the inhibition of aspirin absorption Annals of Emergency Medicine 18 5 547 552 doi 10 1016 S0196 0644 89 80841 8 PMID 2719366 a b P J Paul Value Added Products from Gasification Activated Carbon PDF Bangalore The Combustion Gasification and Propulsion Laboratory CGPL at the Indian Institute of Science IISc Lehmann Joseph S 2009 Biochar for environmental management An introduction In Biochar for Environmental Management Science and Technology PDF Archived PDF from the original on 2021 07 06 Activated Charcoal Discover Magazine Retrieved 2022 01 18 Oliveira Goncalo Calisto Vania Santos Sergio M Otero Marta Esteves Valdemar I 2018 08 01 Paper pulp based adsorbents for the removal of pharmaceuticals from wastewater A novel approach towards diversification The Science of the Total Environment 631 632 1018 1028 Bibcode 2018ScTEn 631 1018O doi 10 1016 j scitotenv 2018 03 072 hdl 10773 25013 ISSN 1879 1026 PMID 29727928 S2CID 19141293 Carroll Gregory T Kirschman David L 2022 A Peripherally Located Air Recirculation Device Containing an Activated Carbon Filter Reduces VOC Levels in a Simulated Operating Room ACS Omega 7 50 46640 46645 doi 10 1021 acsomega 2c05570 ISSN 2470 1343 PMC 9774396 PMID 36570243 Cataldi Pietro Lamanna Leonardo Bertei Claudia Arena Federica Rossi Pietro Liu Mufeng Di Fonzo Fabio Papageorgiou Dimitrios G Luzio Alessandro Caironi Mario 26 February 2022 An Electrically Conductive Oleogel Paste for Edible Electronics Advanced Functional Materials 32 23 2113417 doi 10 1002 adfm 202113417 S2CID 247149736 Charcoal Activated The American Society of Health System Pharmacists Retrieved 23 April 2014 IBM Micromedex 1 February 2019 Charcoal Activated Oral Route Mayo Clinic Retrieved 15 February 2019 World Health Organization 2019 World Health Organization model list of essential medicines 21st list 2019 Geneva World Health Organization hdl 10665 325771 WHO MVP EMP IAU 2019 06 License CC BY NC SA 3 0 IGO Elliott CG Colby TV Kelly TM Hicks HG 1989 Charcoal lung Bronchiolitis obliterans after aspiration of activated charcoal Chest 96 3 672 674 doi 10 1378 chest 96 3 672 PMID 2766830 Exner T Michalopoulos N Pearce J Xavier R Ahuja M March 2018 Simple method for removing DOACs from plasma samples Thrombosis Research 163 117 122 doi 10 1016 j thromres 2018 01 047 PMID 29407622 Exner T Ahuja M Ellwood L 24 April 2019 Effect of an activated charcoal product DOAC Stop intended for extracting DOACs on various other APTT prolonging anticoagulants Clinical Chemistry and Laboratory Medicine 57 5 690 696 doi 10 1515 cclm 2018 0967 PMID 30427777 S2CID 53426892 Activated Carbon SRU Solvent Recovery Unit SRP Solvent Recovery Plant SRS Solvent Recovery System VOC Emission Control Systems DEC IMPIANTI Retrieved 2023 10 15 EPA Alumni Association Senior EPA officials discuss early implementation of the Safe Drinking Water Act of 1974 Video Transcript see pages 15 16 Activated Carbon SRU Solvent Recovery Unit SRP Solvent Recovery Plant SRS Solvent Recovery System VOC Emission Control Systems DEC IMPIANTI Retrieved 2023 10 15 Activated Charcoal Review Sheet permanent dead link USDA Organic Materials Review February 2002 Activated Carbon Petition permanent dead link USDA Organic Materials Review petition Canadaigua Wine May 2002 Activated carbon for purification of alcohol and some useful distillation trips PDF Gert Strand Malmoe Sweden 2001 pp 1 28 Alliance for Collaborative Research in Alternative Fuel Technology All craft missouri edu Archived from the original on 2011 07 20 Retrieved 2014 03 13 Bourke Marta 1989 Activated Carbon for Mercury Removal Archived from the original on 2013 08 03 Retrieved 2013 08 27 a b Mohan Dines Gupta V K Srivastava S K Chander S 2001 Kinetics of mercury adsorption from waste water using activated carbon derived from fertilizer waste Colloids and Surfaces A Physicochemical and Engineering Aspects 177 2 3 169 181 doi 10 1016 S0927 7757 00 00669 5 Tim Flannery Here On Earth A New Beginning Allen Lane 2011 p 186 It s in smoothies toothpaste and pizza is charcoal the new black the Guardian 28 June 2017 Retrieved 11 October 2021 Allan M Carrie 24 April 2017 Dangerous Drinks and How To Spot Them Imbibe Magazine Imbibe Magazine Retrieved 11 October 2021 McCarthy Amy 7 June 2017 Should You Be Eating Activated Charcoal Eater Retrieved 11 October 2021 H Marsh and F Rodriguez Reinoso Activated carbon Elsevier 2006 p 186 Allen CS Ghamouss F Boujibar O Harris PJF 2022 Aberration corrected transmission electron microscopy of a non graphitizing carbon Proc R Soc A 578 2258 20210580 Bibcode 2022RSPSA 47810580A doi 10 1098 rspa 2021 0580 S2CID 246828226 J Romanos et al 2012 Nanospace engineering of KOH activated carbon Nanotechnology 23 1 015401 Bibcode 2012Nanot 23a5401R doi 10 1088 0957 4484 23 1 015401 PMID 22156024 S2CID 20023779 Tripathi AK Murugavel S Singh RK 2021 Dead Ashoka Saraca asoca leaves derived porous activated carbons and flexible iongel polymer electrolyte for high energy density electric double layer capacitors Materials Today Sustainability 11 12 100062 doi 10 1016 j mtsust 2021 100062 S2CID 233931759 a b Nwankwo I H 2018 Production And Characterization Of Activated Carbon From Animal Bone PDF American Journal of Engineering Research AJER 7 7 335 341 Premium activated carbon range boosts Haycarb earnings echolon lk Echelon Media 6 July 2021 Retrieved 5 July 2022 The separation of the most volatile gases from air without liquefaction SentryAir SentryAir Retrieved 2014 03 13 Mianowski A Owczarek M Marecka A 24 May 2007 Surface Area of Activated Carbon Determined by the Iodine Adsorption Number Energy Sources Part A Recovery Utilization and Environmental Effects 29 9 839 850 doi 10 1080 00908310500430901 S2CID 95043547 Divens Jon Adsorption of methylene blue onto activated carbon www nepjol info Journal of the Institute 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14 2685 2691 doi 10 1016 s0008 6223 02 00182 3 a b Valdes H Sanchez Polo M Rivera Utrilla J Zaror C A 2002 Effect of Ozone Treatment on Surface Properties of Activated Carbon Langmuir 18 6 2111 2116 doi 10 1021 la010920a hdl 10533 173367 Pradhan B K Sandle N K 1999 Effect of different oxidizing agent treatments on the surface properties of activated carbons Carbon 37 8 1323 1332 doi 10 1016 s0008 6223 98 00328 5 Acedo Ramos M Gomez Serrano V Valenzuella Calahorro C Lopez Peinado A J 1993 Oxydation of activated carbon in liquid phase Study by FT IR Spectroscopy Letters 26 6 1117 1137 Bibcode 1993SpecL 26 1117A doi 10 1080 00387019308011598 Gomez Serrano V Acedo Ramos M Lopez Peinado A J Valenzuela Calahorro C 1991 Stability towards heating and outgassing of activated carbon oxidized in the liquid phase Thermochimica Acta 176 129 140 doi 10 1016 0040 6031 91 80268 n Stohr B Boehm H P Schlogl R 1991 Enhancement of the catalytic activity of activated carbons in oxidation reactions by 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B Halliop E Liang S MacDonald J A F 1998 The effect of chlorination on surface properties of activated carbon Carbon 36 11 1677 1682 doi 10 1016 S0008 6223 98 00165 1 Papirer E N Lacroix R Donnet J B Nanse G R Fioux P 1995 XPS study of the halogenation of carbon black Part 2 Chlorination Carbon 33 63 72 doi 10 1016 0008 6223 94 00111 C Papirer Eugene Lacroix Renaud Donnet Jean Baptiste Nanse Gerard Fioux Philippe 1994 XPS Study of the halogenation of carbon black part 1 Bromination Carbon 32 7 1341 1358 doi 10 1016 0008 6223 94 90121 X Nanse G Papirer E Fioux P Moguet F Tressaud A 1997 Fluorination of carbon blacks An X ray photoelectron spectroscopy study III Fluorination of different carbon blacks with gaseous fluorine at temperatures below 100 C influence of the morphology structure and physico chemical characteristics of the carbon black on the fluorine fixation Carbon 35 4 515 528 doi 10 1016 S0008 6223 97 00003 1 US 8648217 Modification of carbonaceous materials issued 2008 08 04 US 10000382 Method for carbon materials surface modification by the fluorocarbons and derivatives issued 2015 11 03 Zaderko Alexander N Shvets Roman Ya Grygorchak Ivan I Afonin Sergii Diyuk Vitaliy E Mariychuk Ruslan T Boldyrieva Olga Yu Kanuchova Maria Lisnyak Vladyslav V 2018 11 20 Fluoroalkylated Nanoporous Carbons Testing as a Supercapacitor Electrode Applied Surface Science 470 882 892 doi 10 1016 j apsusc 2018 11 141 ISSN 0169 4332 S2CID 105746451 Aldana Perez A Lartundo Rojas L Gomez R Nino Gomez M E 2012 Sulfonic groups anchored on mesoporous carbon Starbons 300 and its use for the esterification of oleic acid Fuel 100 128 138 doi 10 1016 j fuel 2012 02 025 Diyuk V E Zaderko A N Grishchenko L M Yatsymyrskiy A V Lisnyak V V 2012 Efficient carbon based acid catalysts for the propan 2 ol dehydration Catalysis Communications 27 33 37 doi 10 1016 j catcom 2012 06 018 WO18194533 METHOD FOR CHEMICAL MODIFICATION OF FLUORINATED CARBONS WITH SULFUR CONTAINING SUBSTANCE patentscope wipo int Retrieved 2018 11 24 Budarin V L Clark J H Tavener S J Wilson K 2004 Chemical reactions of double bonds in activated carbon Microwave and bromination methods Chemical Communications 23 2736 7 doi 10 1039 B411222A PMID 15568092 Bagreev A Rhaman H Bandosz T J 2001 Thermal regeneration of a spent activated carbon adsorbent previously used as hydrogen sulfide adsorbent Carbon 39 9 1319 1326 doi 10 1016 S0008 6223 00 00266 9 a b Sabio E Gonzalez E Gonzalez J F Gonzalez Garcia C M Ramiro A Ganan J 2004 Thermal regeneration of activated carbon saturated with p nitrophenol Carbon 42 11 2285 2293 doi 10 1016 j carbon 2004 05 007 Miguel GS Lambert SD Graham NJ 2001 The regeneration of field spent granular activated carbons Water Research 35 11 2740 2748 Bibcode 2001WatRe 35 2740S doi 10 1016 S0043 1354 00 00549 2 PMID 11456174 Alvarez PM Beltran FJ Gomez Serrano V Jaramillo J Rodriguez EM 2004 Comparison between thermal and ozone regenerations of spent activated carbon exhausted with phenol Water Research 38 8 2155 2165 Bibcode 2004WatRe 38 2155A doi 10 1016 j watres 2004 01 030 PMID 15087197 activated carbon steam regeneration DEC IMPIANTI Retrieved 2023 10 15 activated carbon inert gas nitrogen regeneration DEC IMPIANTI Retrieved 2023 10 15 activated carbon vacuum regeneration DEC IMPIANTI Retrieved 2023 10 15 Cherbanski R 2018 Regeneration of granular activated carbon loaded with toluene Comparison of microwave and conductive heating at the same active powers Chemical Engineering and Processing Process Intensification 123 January 2018 148 157 doi 10 1016 j cep 2017 11 008 Martin R J Wj N 1997 The repeated exhaustion and chemical regeneration of activated carbon Water Research 21 8 961 965 doi 10 1016 S0043 1354 87 80014 3 Aizpuru A Malhautier L Roux JC Fanlo JL 2003 Biofiltration of a mixture of volatile organic compounds on granular activated carbon Biotechnology and Bioengineering 83 4 479 488 doi 10 1002 bit 10691 PMID 12800142 S2CID 9980413 Narbaitz RM Karimi Jashni A 2009 Electrochemical regeneration of granular activated carbons loaded with phenol and natural organic matter Environmental Technology 30 1 27 36 doi 10 1080 09593330802422803 PMID 19213463 Lim JL Okada M 2005 Regeneration of granular activated carbon using ultrasound Ultrasonic Sono Chemistry 12 4 277 285 doi 10 1016 j ultsonch 2004 02 003 PMID 15501710 Shende RV Mahajani VV 2002 Wet oxidative regeneration of activated carbon loaded with reactive dye Waste Management 22 1 73 83 Bibcode 2002WaMan 22 73S doi 10 1016 S0956 053X 01 00022 8 PMID 11942707 External links edit nbsp Wikimedia Commons has media related to Activated carbon Imaging the atomic structure of activated carbon Journal of Physics Condensed Matter How Does Activated Carbon Work at Slate Worshiping the False Idols of Wellness on activated charcoal as a useless wellness practice at The New York Times Retrieved from https en wikipedia org w index php title Activated carbon amp oldid 1183523491, wikipedia, wiki, 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