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Carbon black

February 16, 2024

For the climate forcing agent, see Black carbon. For the Carbon Black security company, see Carbon Black (company).

Carbon black (with subtypes acetylene black, channel black, furnace black, lamp black and thermal black) is a material produced by the incomplete combustion of coal tar, vegetable matter, or petroleum products, including fuel oil, fluid catalytic cracking tar, and ethylene cracking in a limited supply of air. Carbon black is a form of paracrystalline carbon that has a high surface-area-to-volume ratio, albeit lower than that of activated carbon. It is dissimilar to soot in its much higher surface-area-to-volume ratio and significantly lower (negligible and non-bioavailable) polycyclic aromatic hydrocarbon (PAH) content. However, carbon black can be used as a model compound for diesel soot to better understand how diesel soot behaves under various reaction conditions as carbon black and diesel soot have some similar properties such as particle sizes, densities, and copolymer adsorption abilities that contribute to them having similar behaviours under various reactions such as oxidation experiments.[2][3][better source needed] Carbon black is used as a colorant and reinforcing filler in tires and other rubber products; pigment and wear protection additive in plastics, paints, and ink pigment.[4] It is used in the EU as a food colorant when produced from vegetable matter (E153).

Carbon black
Names
Other names
Acetylene black; Channel black; Furnace black; Lamp black; Thermal black; C.I. Pigment Black 6
Identifiers
  • 1333-86-4 Y
3D model (JSmol)
  • Interactive image
ECHA InfoCard 100.014.191
EC Number
  • 215-609-9
E number E152 (colours)
UNII
  • 4XYU5U00C4 Y
  • DTXSID7051216
  • C
Properties
C
Molar mass 12.011 g·mol−1
Appearance Black solid
Density 1.8–2.1 g/cm3 (20 °C)[1]
Practically insoluble[1]
Hazards
Lethal dose or concentration (LD, LC):
> 15400 mg/kg (oral rat)[1]
3000 mg/kg (dermal, rabbit)[1]
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Worker at carbon black plant, 1942

The current International Agency for Research on Cancer (IARC) evaluation is that, "Carbon black is possibly carcinogenic to humans (Group 2B)".[5] Short-term exposure to high concentrations of carbon black dust may produce discomfort to the upper respiratory tract through mechanical irritation.

Common uses edit

The most common use (70%) of carbon black is as a pigment and reinforcing phase in automobile tires. Carbon black also helps conduct heat away from the tread and belt area of the tire, reducing thermal damage and increasing tire life. Its low cost makes it a common addition to cathodes and anodes and is considered a safe replacement to lithium metal in lithium-ion batteries.[6] About 20% of world production goes into belts, hoses, and other non-tire rubber goods. The remaining 10% use of carbon black comes from pigment in inks, coatings, and plastics, as well as being used as a conductive additive in lithium-ion batteries.[7]

Carbon black is added to polypropylene because it absorbs ultraviolet radiation, which otherwise causes the material to degrade. Carbon black particles are also employed in some radar absorbent materials, in photocopier and laser printer toner, and in other inks and paints. The high tinting strength and stability of carbon black has also provided use in coloring of resins and films.[8] Carbon black has been used in various applications for electronics. A good conductor of electricity, carbon black is used as a filler mixed in plastics, elastomer, films, adhesives, and paints.[8] It is used as an antistatic additive agent in automobile fuel caps and pipes.

Carbon black from vegetable origin is used as a food coloring, known in Europe as additive E153. It is approved for use as additive 153 (Carbon blacks or Vegetable carbon) in Australia and New Zealand[9] but has been banned in the US.[10] The color pigment carbon black has been widely used for many years in food and beverage packaging. It is used in multi-layer UHT milk bottles in the US, parts of Europe and Asia, and South Africa, and in items like microwavable meal trays and meat trays in New Zealand.

The Canadian Government's extensive review of carbon black in 2011 concluded that carbon black could continue to be used in products – including food packaging for consumers – in Canada. This was because "in most consumer products carbon black is bound in a matrix and unavailable for exposure, for example as a pigment in plastics and rubbers" and "it is proposed that carbon black is not entering the environment in a quantity or concentrations or under conditions that constitute or may constitute a danger in Canada to human life or health."[11]

Within Australasia, the color pigment carbon black in packaging must comply with the requirements of either the EU or US packaging regulations. If any colorant is used, it must meet European partial agreement AP(89)1.[12]

Total production was around 8,100,000 metric tons (8,900,000 short tons) in 2006.[13] Global consumption of carbon black, estimated at 13.2 million metric tons, valued at US$13.7 billion, in 2015, is expected to reach 13.9 million metric tons, valued at US$14.4 billion in 2016.

Global consumption is forecast to maintain a CAGR (compound annual growth rate) of 5.6% between 2016 and 2022, reaching 19.2 million metric tons, valued at US$20.4 billion, by 2022.[14]

Reinforcing carbon blacks edit

The highest volume use of carbon black is as a reinforcing filler in rubber products, especially tires. While a pure gum vulcanization of styrene-butadiene has a tensile strength of no more than 2 MPa and negligible abrasion resistance, compounding it with 50% carbon black by weight improves its tensile strength and wear resistance as shown in the table below. It is used often in the aerospace industry in elastomers for aircraft vibration control components such as engine mounts.

Certain types of carbon black used in tires, plastics and paints
Name Abbrev. ASTM
desig. 		Particle
Size
nm 		Tensile
strength
MPa 		Relative
laboratory
abrasion 		Relative
roadwear
abrasion
Super Abrasion Furnace SAF N110 20–25 25.2 1.35 1.25
Intermediate SAF ISAF N220 24–33 23.1 1.25 1.15
High Abrasion Furnace HAF N330 28–36 22.4 1.00 1.00
Easy Processing Channel EPC N300 30–35 21.7 0.80 0.90
Fast Extruding Furnace FEF N550 39–55 18.2 0.64 0.72
High Modulus Furnace HMF N660 49–73 16.1 0.56 0.66
Semi-Reinforcing Furnace SRF N770 70–96 14.7 0.48 0.60
Fine Thermal FT N880 180–200 12.6 0.22
Medium Thermal MT N990 250–350 9.8 0.18

Practically all rubber products where tensile and abrasion wear properties are important use carbon black, so they are black in color. Where physical properties are important but colors other than black are desired, such as white tennis shoes, precipitated or fumed silica has been substituted for carbon black. Silica-based fillers are also gaining market share in automotive tires because they provide better trade-off for fuel efficiency and wet handling due to a lower rolling loss. Traditionally silica fillers had worse abrasion wear properties, but the technology has gradually improved to a point where they can match carbon black abrasion performance.

Pigment edit

Carbon black (Color Index International, PBK-7) is the name of a common black pigment, traditionally produced from charring organic materials such as wood or bone. It appears black because it reflects very little light in the visible part of the spectrum, with an albedo near zero. The actual albedo varies depending on the source material and method of production. It is known by a variety of names, each of which reflects a traditional method for producing carbon black:

  • Ivory black was traditionally produced by charring ivory or bones (see bone char).
  • Vine black was traditionally produced by charring desiccated grape vines and stems.
  • Lamp black was traditionally produced by collecting soot from oil lamps.

All of these types of carbon black were used extensively as paint pigments since prehistoric times.[15] Rembrandt, Vermeer, Van Dyck, and more recently, Cézanne, Picasso and Manet[16] employed carbon black pigments in their paintings. A typical example is Manet's "Music in the Tuileries",[17] where the black dresses and the men's hats are painted in ivory black.[18]

Newer methods of producing carbon black have largely superseded these traditional sources. For artisanal purposes, carbon black produced by any means remains common.[8]

Surface and surface chemistry edit

All carbon blacks have chemisorbed oxygen complexes (i.e., carboxylic, quinonic, lactonic, phenolic groups and others) on their surfaces to varying degrees depending on the conditions of manufacture.[19] These surface oxygen groups are collectively referred to as volatile content. It is also known to be a non-conductive material due to its volatile content.

The coatings and inks industries prefer grades of carbon black that are acid-oxidized. Acid is sprayed in high-temperature dryers during the manufacturing process to change the inherent surface chemistry of the black. The amount of chemically-bonded oxygen on the surface area of the black is increased to enhance performance characteristics.

Use in lithium-ion batteries edit

 
The generic structure of carbon black.

Carbon black is a common conductive additive for lithium ion batteries as they have small particle sizes and large specific surface areas (SSA) which allow for the additive to be well distributed throughout the cathode or anode in addition to being cheap and long-lasting.[7][20] Unlike graphite, which is one of the other common materials used in chargeable batteries, carbon black consists of crystal lattices that are further apart and promotes Li+ intercalation because it allows more pathways for lithium storage.[20]

Carbon black has a low density that allows for a large volume of it to be dispersed so that its conductive effects are applied evenly throughout the battery.[21][22] Furthermore, its arrangement of randomly distributed graphite-like crystals improves battery stability because of the decrease in the potential barrier of lithium intercalation into graphite, which ultimately affects the performance of cathodes.[20]

While carbon black is lightweight and well dispersed throughout the battery and increases the conductive performance of batteries, it also contains oxygen containing hydrophilic functional groups that can cause side reactions to occur in the battery and lead to the decomposition of electrolyte. Graphitization (heating) of carbon black can thermally decompose the hydrophilic functional groups and thus increase the cycle life of the battery which maintains the conductive abilities of carbon black while mitigating the damage that can be caused to batteries by hydrophilic functional groups.

Half cells created with heavy graphitization, light graphitization, and no graphitization showed that the cell created with heavy graphitization had a stable cycle life of 320 cycles, the cell with light graphitization showed a stable cycle life of 200 cycles, and the cell with no graphitization showed a stable cycle life of 160 cycles.[7]

Safety edit

Carcinogenicity edit

Carbon black is considered possibly carcinogenic to humans and classified as a Group 2B carcinogen because there is sufficient evidence in experimental animals with inadequate evidence in human epidemiological studies.[5] The evidence of carcinogenicity in animal studies comes from two chronic inhalation studies and two intratracheal instillation studies in rats, which showed significantly elevated rates of lung cancer in exposed animals.[5] An inhalation study on mice did not show significantly elevated rates of lung cancer in exposed animals.[5] Epidemiologic data comes from three cohort studies of carbon black production workers. Two studies, from the United Kingdom and Germany, with over 1,000 workers in each study group showed elevated mortality from lung cancer.[5] A third study of over 5,000 carbon black workers in the United States did not show elevated mortality.[5] Newer findings of increased lung cancer mortality in an update from the UK study suggest that carbon black could be a late-stage carcinogen.[23][24] However, a more recent and larger study from Germany did not confirm this hypothesis.[25]

Occupational safety edit

There are strict guidelines available and in place to ensure employees who manufacture carbon black are not at risk of inhaling unsafe doses of carbon black in its raw form.[26] Respiratory personal protective equipment is recommended to properly protect workers from inhalation of carbon black. The recommended type of respiratory protection varies depending on the concentration of carbon black used.[27]

People can be exposed to carbon black in the workplace by inhalation and contact with the skin or eyes. The Occupational Safety and Health Administration (OSHA) has set the legal limit (Permissible exposure limit) for carbon black exposure in the workplace at 3.5 mg/m3 over an 8-hour workday. The National Institute for Occupational Safety and Health (NIOSH) has set a Recommended exposure limit (REL) of 3.5 mg/m3 over an 8-hour workday. At levels of 1750 mg/m3, carbon black is immediately dangerous to life and health.[28]

See also edit

References edit

  1. ^ a b c d Record in the GESTIS Substance Database of the Institute for Occupational Safety and Health
  2. ^ Growney, David J.; Mykhaylyk, Oleksandr O.; Middlemiss, Laurence; Fielding, Lee A.; Derry, Matthew J.; Aragrag, Najib; Lamb, Gordon D.; Armes, Steven P. (2015-09-29). "Is Carbon Black a Suitable Model Colloidal Substrate for Diesel Soot?". Langmuir. 31 (38): 10358–10369. doi:10.1021/acs.langmuir.5b02017. ISSN 0743-7463. PMID 26344920. S2CID 206670654.
  3. ^ "Experimental and kinetic study of the interaction of a commercial soot toward NO at high temperature" (PDF). (PDF) from the original on 2013-02-15. Retrieved 2012-04-25.
  4. ^ "Market Study: Carbon Black". Ceresana. Retrieved 2013-04-26.
  5. ^ a b c d e f Kuempel, Eileen D.; Sorahan, Tom (2010). "Identification of Research Needs to Resolve the Carcinogenicity of High-priority IARC Carcinogens" (PDF). Views and Expert Opinions of an IARC/NORA Expert Group Meeting, Lyon, France, 30 June – 2 July 2009. IARC Technical Publication No. 42. Lyon, France: International Agency for Research on Cancer. 42: 61–72. Retrieved August 30, 2012.
  6. ^ Gnanamuthu, RM.; Lee, Chang Woo (2011-11-01). "Electrochemical properties of Super P carbon black as an anode active material for lithium-ion batteries". Materials Chemistry and Physics. 130 (3): 831–834. doi:10.1016/j.matchemphys.2011.08.060. ISSN 0254-0584.
  7. ^ a b c Qi, Xin; Blizanac, Berislav; DuPasquier, Aurelien; Lal, Archit; Niehoff, Philip; Placke, Tobias; Oljaca, Miodrag; Li, Jie; Winter, Martin (2015). "Influence of Thermal Treated Carbon Black Conductive Additive on the Performance of High Voltage Spinel Cr-Doped LiNi 0.5 Mn 1.5 O 4 Composite Cathode Electrode". Journal of the Electrochemical Society. 162 (3): A339–A343. doi:10.1149/2.0401503jes. ISSN 0013-4651.
  8. ^ a b c "Application Examples of carbon black". Mitsubishi Chemical. Retrieved 2013-01-14.
  9. ^ Australia New Zealand Food Standards Code"Standard 1.2.4 – Labelling of ingredients". Retrieved 2011-10-27.
  10. ^ US FDA:"Color Additive Status List". Food and Drug Administration. Retrieved 2011-10-27.
  11. ^ "Draft Screening Assessment for the Challenge". 29 January 2010. Retrieved 2013-01-14.
  12. ^ . Archived from the original on 2012-12-20. Retrieved 2013-01-14.
  13. ^ . International carbon black Association. Archived from the original on 2009-04-01. Retrieved 2009-04-14.
  14. ^ Carbon Black - A Global Market Overview Jan 2016 • Industry Experts Report CP024 • 328 pages
  15. ^ Winter, J. and West FitzHugh, E., Pigments based on Carbon, in Berrie, B.H. Editor, Artists’ Pigments, A Handbook of Their History and Characteristics, Volume 4, pp. 1–37.
  16. ^ Bone black, ColourLex
  17. ^ Bomford D, Kirby J, Leighton, J., Roy A. Art in the Making: Impressionism. National Gallery Publications, London, 1990, pp. 112–119.
  18. ^ Édouard Manet, 'Music in the Tuileries Gardens', ColourLex
  19. ^ Hennion, Marie-Claire (July 2000). "Graphitized carbons for solid-phase extraction". Journal of Chromatography A. 885 (1–2): 73–95. doi:10.1016/S0021-9673(00)00085-6. PMID 10941668.
  20. ^ a b c Hu, Jingwei; Zhong, Shengwen; Yan, Tingting (2021-10-01). "Using carbon black to facilitate fast charging in lithium-ion batteries". Journal of Power Sources. 508: 230342. Bibcode:2021JPS...50830342H. doi:10.1016/j.jpowsour.2021.230342. ISSN 0378-7753.
  21. ^ Younesi, Reza; Christiansen, Ane Sælland; Scipioni, Roberto; Ngo, Duc-The; Simonsen, Søren Bredmose; Edström, Kristina; Hjelm, Johan; Norby, Poul (2015). "Analysis of the Interphase on Carbon Black Formed in High Voltage Batteries". Journal of the Electrochemical Society. 162 (7): A1289–A1296. doi:10.1149/2.0761507jes. ISSN 0013-4651. S2CID 53486824.
  22. ^ Dominko, Robert; Gaberscek, Miran; Drofenik, Jernej; Bele, Marjan; Pejovnik, Stane; Jamnik, Janko (2003-06-01). "The role of carbon black distribution in cathodes for Li ion batteries". Journal of Power Sources. Selected papers presented at the 11th International Meeting on Lithium Batteries. 119–121: 770–773. Bibcode:2003JPS...119..770D. doi:10.1016/S0378-7753(03)00250-7. ISSN 0378-7753.
  23. ^ Sorahan T, Harrington JM (2007). "A "lugged" analysis of lung cancer risks in UK carbon black production workers, 1951–2004". Am J Ind Med. 50 (8): 555–564. doi:10.1002/ajim.20481. PMID 17516558.
  24. ^ Ward EM, Schulte PA, Straif K, Hopf NB, Caldwell JC, Carreón T, DeMarini DM, Fowler BA, Goldstein BD, Hemminki K, Hines CJ, Pursiainen KH, Kuempel E, Lewtas J, Lunn RM, Lynge E, McElvenny DM, Muhle H, Nakajima T, Robertson LW, Rothman N, Ruder AM, Schubauer-Berigan MK, Siemiatycki J, Silverman D, Smith MT, Sorahan T, Steenland K, Stevens RG, Vineis P, Zahm SH, Zeise L, Cogliano VJ (2010). "Research recommendations for selected IARC-classified agents". Environmental Health Perspectives. 118 (10): 1355–62. doi:10.1289/ehp.0901828. PMC 2957912. PMID 20562050.
  25. ^ Morfeld P, McCunney RJ (2007). "Carbon black and lung cancer: Testing a new exposure metric in a German cohort". Am J Ind Med. 50 (8): 565–567. doi:10.1002/ajim.20491. PMID 17620319.
  26. ^ "Occupational Safety and Health Guidelines for carbon black: Potential Human Carcinogen, Centres of Disease Control and Prevention, National Institute for Occupational Safety and Health" (PDF). Retrieved 2013-01-14.
  27. ^ "Occupational Safety and Health Guideline for Carbon Black: Potential Human Carcinogen" (PDF). Centers of Disease Control and Prevention, National Institute for Occupational Safety and Health. Retrieved 11 January 2013.
  28. ^ "CDC – NIOSH Pocket Guide to Chemical Hazards – Carbon black". www.cdc.gov. Retrieved 2015-11-27.

Further reading edit

  • Doerner, Max. The Materials of the Artist and Their Use in Painting: With Notes on the Techniques of the Old Masters, Revised Edition. Harcourt (1984). ISBN 0-15-657716-X. This is a contemporary English language edition of a work originally published in German.
  • Meyer, Ralph. The Artist's Handbook of Materials and Techniques. Fifth Edition, Revised and Updated. Viking (1991) ISBN 0-670-83701-6
  • . Published by the International Carbon Black Association.

External links edit

 
Wikisource has the text of a 1920 Encyclopedia Americana article about Carbon black.
 
Wikimedia Commons has media related to Carbon black.
  • International Chemical Safety Card 0471
  • "Carbon black" – NIOSH Pocket Guide to Chemical Hazards, CDC website entry
  • "Carbon Black Industry" from the Handbook of Texas Online
  • International Carbon Black Association
  • Special Carbon Blacks - PentaCarbon GmbH

February 16, 2024
carbon, black, climate, forcing, agent, black, carbon, carbon, black, security, company, carbon, black, company, with, subtypes, acetylene, black, channel, black, furnace, black, lamp, black, thermal, black, material, produced, incomplete, combustion, coal, ve. For the climate forcing agent see Black carbon For the Carbon Black security company see Carbon Black company Carbon black with subtypes acetylene black channel black furnace black lamp black and thermal black is a material produced by the incomplete combustion of coal tar vegetable matter or petroleum products including fuel oil fluid catalytic cracking tar and ethylene cracking in a limited supply of air Carbon black is a form of paracrystalline carbon that has a high surface area to volume ratio albeit lower than that of activated carbon It is dissimilar to soot in its much higher surface area to volume ratio and significantly lower negligible and non bioavailable polycyclic aromatic hydrocarbon PAH content However carbon black can be used as a model compound for diesel soot to better understand how diesel soot behaves under various reaction conditions as carbon black and diesel soot have some similar properties such as particle sizes densities and copolymer adsorption abilities that contribute to them having similar behaviours under various reactions such as oxidation experiments 2 3 better source needed Carbon black is used as a colorant and reinforcing filler in tires and other rubber products pigment and wear protection additive in plastics paints and ink pigment 4 It is used in the EU as a food colorant when produced from vegetable matter E153 Carbon black NamesOther names Acetylene black Channel black Furnace black Lamp black Thermal black C I Pigment Black 6IdentifiersCAS Number 1333 86 4 Y3D model JSmol Interactive imageECHA InfoCard 100 014 191EC Number 215 609 9E number E152 colours UNII 4XYU5U00C4 YCompTox Dashboard EPA DTXSID7051216SMILES CPropertiesChemical formula CMolar mass 12 011 g mol 1Appearance Black solidDensity 1 8 2 1 g cm3 20 C 1 Solubility in water Practically insoluble 1 HazardsLethal dose or concentration LD LC LD50 median dose gt 15400 mg kg oral rat 1 3000 mg kg dermal rabbit 1 Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Infobox references Worker at carbon black plant 1942The current International Agency for Research on Cancer IARC evaluation is that Carbon black is possibly carcinogenic to humans Group 2B 5 Short term exposure to high concentrations of carbon black dust may produce discomfort to the upper respiratory tract through mechanical irritation Contents 1 Common uses 2 Reinforcing carbon blacks 3 Pigment 4 Surface and surface chemistry 5 Use in lithium ion batteries 6 Safety 6 1 Carcinogenicity 6 2 Occupational safety 7 See also 8 References 9 Further reading 10 External linksCommon uses editThe most common use 70 of carbon black is as a pigment and reinforcing phase in automobile tires Carbon black also helps conduct heat away from the tread and belt area of the tire reducing thermal damage and increasing tire life Its low cost makes it a common addition to cathodes and anodes and is considered a safe replacement to lithium metal in lithium ion batteries 6 About 20 of world production goes into belts hoses and other non tire rubber goods The remaining 10 use of carbon black comes from pigment in inks coatings and plastics as well as being used as a conductive additive in lithium ion batteries 7 Carbon black is added to polypropylene because it absorbs ultraviolet radiation which otherwise causes the material to degrade Carbon black particles are also employed in some radar absorbent materials in photocopier and laser printer toner and in other inks and paints The high tinting strength and stability of carbon black has also provided use in coloring of resins and films 8 Carbon black has been used in various applications for electronics A good conductor of electricity carbon black is used as a filler mixed in plastics elastomer films adhesives and paints 8 It is used as an antistatic additive agent in automobile fuel caps and pipes Carbon black from vegetable origin is used as a food coloring known in Europe as additive E153 It is approved for use as additive 153 Carbon blacks or Vegetable carbon in Australia and New Zealand 9 but has been banned in the US 10 The color pigment carbon black has been widely used for many years in food and beverage packaging It is used in multi layer UHT milk bottles in the US parts of Europe and Asia and South Africa and in items like microwavable meal trays and meat trays in New Zealand The Canadian Government s extensive review of carbon black in 2011 concluded that carbon black could continue to be used in products including food packaging for consumers in Canada This was because in most consumer products carbon black is bound in a matrix and unavailable for exposure for example as a pigment in plastics and rubbers and it is proposed that carbon black is not entering the environment in a quantity or concentrations or under conditions that constitute or may constitute a danger in Canada to human life or health 11 Within Australasia the color pigment carbon black in packaging must comply with the requirements of either the EU or US packaging regulations If any colorant is used it must meet European partial agreement AP 89 1 12 Total production was around 8 100 000 metric tons 8 900 000 short tons in 2006 13 Global consumption of carbon black estimated at 13 2 million metric tons valued at US 13 7 billion in 2015 is expected to reach 13 9 million metric tons valued at US 14 4 billion in 2016 Global consumption is forecast to maintain a CAGR compound annual growth rate of 5 6 between 2016 and 2022 reaching 19 2 million metric tons valued at US 20 4 billion by 2022 14 Reinforcing carbon blacks editThe highest volume use of carbon black is as a reinforcing filler in rubber products especially tires While a pure gum vulcanization of styrene butadiene has a tensile strength of no more than 2 MPa and negligible abrasion resistance compounding it with 50 carbon black by weight improves its tensile strength and wear resistance as shown in the table below It is used often in the aerospace industry in elastomers for aircraft vibration control components such as engine mounts Certain types of carbon black used in tires plastics and paints Name Abbrev ASTM desig Particle Size nm Tensile strength MPa Relative laboratory abrasion Relative roadwear abrasionSuper Abrasion Furnace SAF N110 20 25 25 2 1 35 1 25Intermediate SAF ISAF N220 24 33 23 1 1 25 1 15High Abrasion Furnace HAF N330 28 36 22 4 1 00 1 00Easy Processing Channel EPC N300 30 35 21 7 0 80 0 90Fast Extruding Furnace FEF N550 39 55 18 2 0 64 0 72High Modulus Furnace HMF N660 49 73 16 1 0 56 0 66Semi Reinforcing Furnace SRF N770 70 96 14 7 0 48 0 60Fine Thermal FT N880 180 200 12 6 0 22 Medium Thermal MT N990 250 350 9 8 0 18 Practically all rubber products where tensile and abrasion wear properties are important use carbon black so they are black in color Where physical properties are important but colors other than black are desired such as white tennis shoes precipitated or fumed silica has been substituted for carbon black Silica based fillers are also gaining market share in automotive tires because they provide better trade off for fuel efficiency and wet handling due to a lower rolling loss Traditionally silica fillers had worse abrasion wear properties but the technology has gradually improved to a point where they can match carbon black abrasion performance Pigment editCarbon black Color Index International PBK 7 is the name of a common black pigment traditionally produced from charring organic materials such as wood or bone It appears black because it reflects very little light in the visible part of the spectrum with an albedo near zero The actual albedo varies depending on the source material and method of production It is known by a variety of names each of which reflects a traditional method for producing carbon black Ivory black was traditionally produced by charring ivory or bones see bone char Vine black was traditionally produced by charring desiccated grape vines and stems Lamp black was traditionally produced by collecting soot from oil lamps All of these types of carbon black were used extensively as paint pigments since prehistoric times 15 Rembrandt Vermeer Van Dyck and more recently Cezanne Picasso and Manet 16 employed carbon black pigments in their paintings A typical example is Manet s Music in the Tuileries 17 where the black dresses and the men s hats are painted in ivory black 18 Newer methods of producing carbon black have largely superseded these traditional sources For artisanal purposes carbon black produced by any means remains common 8 Surface and surface chemistry editAll carbon blacks have chemisorbed oxygen complexes i e carboxylic quinonic lactonic phenolic groups and others on their surfaces to varying degrees depending on the conditions of manufacture 19 These surface oxygen groups are collectively referred to as volatile content It is also known to be a non conductive material due to its volatile content The coatings and inks industries prefer grades of carbon black that are acid oxidized Acid is sprayed in high temperature dryers during the manufacturing process to change the inherent surface chemistry of the black The amount of chemically bonded oxygen on the surface area of the black is increased to enhance performance characteristics Use in lithium ion batteries edit nbsp The generic structure of carbon black Carbon black is a common conductive additive for lithium ion batteries as they have small particle sizes and large specific surface areas SSA which allow for the additive to be well distributed throughout the cathode or anode in addition to being cheap and long lasting 7 20 Unlike graphite which is one of the other common materials used in chargeable batteries carbon black consists of crystal lattices that are further apart and promotes Li intercalation because it allows more pathways for lithium storage 20 Carbon black has a low density that allows for a large volume of it to be dispersed so that its conductive effects are applied evenly throughout the battery 21 22 Furthermore its arrangement of randomly distributed graphite like crystals improves battery stability because of the decrease in the potential barrier of lithium intercalation into graphite which ultimately affects the performance of cathodes 20 While carbon black is lightweight and well dispersed throughout the battery and increases the conductive performance of batteries it also contains oxygen containing hydrophilic functional groups that can cause side reactions to occur in the battery and lead to the decomposition of electrolyte Graphitization heating of carbon black can thermally decompose the hydrophilic functional groups and thus increase the cycle life of the battery which maintains the conductive abilities of carbon black while mitigating the damage that can be caused to batteries by hydrophilic functional groups Half cells created with heavy graphitization light graphitization and no graphitization showed that the cell created with heavy graphitization had a stable cycle life of 320 cycles the cell with light graphitization showed a stable cycle life of 200 cycles and the cell with no graphitization showed a stable cycle life of 160 cycles 7 Safety editCarcinogenicity edit Carbon black is considered possibly carcinogenic to humans and classified as a Group 2B carcinogen because there is sufficient evidence in experimental animals with inadequate evidence in human epidemiological studies 5 The evidence of carcinogenicity in animal studies comes from two chronic inhalation studies and two intratracheal instillation studies in rats which showed significantly elevated rates of lung cancer in exposed animals 5 An inhalation study on mice did not show significantly elevated rates of lung cancer in exposed animals 5 Epidemiologic data comes from three cohort studies of carbon black production workers Two studies from the United Kingdom and Germany with over 1 000 workers in each study group showed elevated mortality from lung cancer 5 A third study of over 5 000 carbon black workers in the United States did not show elevated mortality 5 Newer findings of increased lung cancer mortality in an update from the UK study suggest that carbon black could be a late stage carcinogen 23 24 However a more recent and larger study from Germany did not confirm this hypothesis 25 Occupational safety edit There are strict guidelines available and in place to ensure employees who manufacture carbon black are not at risk of inhaling unsafe doses of carbon black in its raw form 26 Respiratory personal protective equipment is recommended to properly protect workers from inhalation of carbon black The recommended type of respiratory protection varies depending on the concentration of carbon black used 27 People can be exposed to carbon black in the workplace by inhalation and contact with the skin or eyes The Occupational Safety and Health Administration OSHA has set the legal limit Permissible exposure limit for carbon black exposure in the workplace at 3 5 mg m3 over an 8 hour workday The National Institute for Occupational Safety and Health NIOSH has set a Recommended exposure limit REL of 3 5 mg m3 over an 8 hour workday At levels of 1750 mg m3 carbon black is immediately dangerous to life and health 28 See also editActivated carbon Biochar George Oenslager early use of carbon black in rubber Heavy metals Jean Baptiste Donnet carbon black pioneer Joseph C Krejci carbon black pioneer Kvaerner process production from hydrocarbons List of inorganic pigments Siegfried Wolff carbon black pioneer William B Wiegand carbon black pioneerReferences edit a b c d Record in the GESTIS Substance Database of the Institute for Occupational Safety and Health Growney David J Mykhaylyk Oleksandr O Middlemiss Laurence Fielding Lee A Derry Matthew J Aragrag Najib Lamb Gordon D Armes Steven P 2015 09 29 Is Carbon Black a Suitable Model Colloidal Substrate for Diesel Soot Langmuir 31 38 10358 10369 doi 10 1021 acs langmuir 5b02017 ISSN 0743 7463 PMID 26344920 S2CID 206670654 Experimental and kinetic study of the interaction of a commercial soot toward NO at high temperature PDF Archived PDF from the original on 2013 02 15 Retrieved 2012 04 25 Market Study Carbon Black Ceresana Retrieved 2013 04 26 a b c d e f Kuempel Eileen D Sorahan Tom 2010 Identification of Research Needs to Resolve the Carcinogenicity of High priority IARC Carcinogens PDF Views and Expert Opinions of an IARC NORA Expert Group Meeting Lyon France 30 June 2 July 2009 IARC Technical Publication No 42 Lyon France International Agency for Research on Cancer 42 61 72 Retrieved August 30 2012 Gnanamuthu RM Lee Chang Woo 2011 11 01 Electrochemical properties of Super P carbon black as an anode active material for lithium ion batteries Materials Chemistry and Physics 130 3 831 834 doi 10 1016 j matchemphys 2011 08 060 ISSN 0254 0584 a b c Qi Xin Blizanac Berislav DuPasquier Aurelien Lal Archit Niehoff Philip Placke Tobias Oljaca Miodrag Li Jie Winter Martin 2015 Influence of Thermal Treated Carbon Black Conductive Additive on the Performance of High Voltage Spinel Cr Doped LiNi 0 5 Mn 1 5 O 4 Composite Cathode Electrode Journal of the Electrochemical Society 162 3 A339 A343 doi 10 1149 2 0401503jes ISSN 0013 4651 a b c Application Examples of carbon black Mitsubishi Chemical Retrieved 2013 01 14 Australia New Zealand Food Standards Code Standard 1 2 4 Labelling of ingredients Retrieved 2011 10 27 US FDA Color Additive Status List Food and Drug Administration Retrieved 2011 10 27 Draft Screening Assessment for the Challenge 29 January 2010 Retrieved 2013 01 14 Australia New Zealand Food Standards Code Archived from the original on 2012 12 20 Retrieved 2013 01 14 What is carbon black International carbon black Association Archived from the original on 2009 04 01 Retrieved 2009 04 14 Carbon Black A Global Market Overview Jan 2016 Industry Experts Report CP024 328 pages Winter J and West FitzHugh E Pigments based on Carbon in Berrie B H Editor Artists Pigments A Handbook of Their History and Characteristics Volume 4 pp 1 37 Bone black ColourLex Bomford D Kirby J Leighton J Roy A Art in the Making Impressionism National Gallery Publications London 1990 pp 112 119 Edouard Manet Music in the Tuileries Gardens ColourLex Hennion Marie Claire July 2000 Graphitized carbons for solid phase extraction Journal of Chromatography A 885 1 2 73 95 doi 10 1016 S0021 9673 00 00085 6 PMID 10941668 a b c Hu Jingwei Zhong Shengwen Yan Tingting 2021 10 01 Using carbon black to facilitate fast charging in lithium ion batteries Journal of Power Sources 508 230342 Bibcode 2021JPS 50830342H doi 10 1016 j jpowsour 2021 230342 ISSN 0378 7753 Younesi Reza Christiansen Ane Saelland Scipioni Roberto Ngo Duc The Simonsen Soren Bredmose Edstrom Kristina Hjelm Johan Norby Poul 2015 Analysis of the Interphase on Carbon Black Formed in High Voltage Batteries Journal of the Electrochemical Society 162 7 A1289 A1296 doi 10 1149 2 0761507jes ISSN 0013 4651 S2CID 53486824 Dominko Robert Gaberscek Miran Drofenik Jernej Bele Marjan Pejovnik Stane Jamnik Janko 2003 06 01 The role of carbon black distribution in cathodes for Li ion batteries Journal of Power Sources Selected papers presented at the 11th International Meeting on Lithium Batteries 119 121 770 773 Bibcode 2003JPS 119 770D doi 10 1016 S0378 7753 03 00250 7 ISSN 0378 7753 Sorahan T Harrington JM 2007 A lugged analysis of lung cancer risks in UK carbon black production workers 1951 2004 Am J Ind Med 50 8 555 564 doi 10 1002 ajim 20481 PMID 17516558 Ward EM Schulte PA Straif K Hopf NB Caldwell JC Carreon T DeMarini DM Fowler BA Goldstein BD Hemminki K Hines CJ Pursiainen KH Kuempel E Lewtas J Lunn RM Lynge E McElvenny DM Muhle H Nakajima T Robertson LW Rothman N Ruder AM Schubauer Berigan MK Siemiatycki J Silverman D Smith MT Sorahan T Steenland K Stevens RG Vineis P Zahm SH Zeise L Cogliano VJ 2010 Research recommendations for selected IARC classified agents Environmental Health Perspectives 118 10 1355 62 doi 10 1289 ehp 0901828 PMC 2957912 PMID 20562050 Morfeld P McCunney RJ 2007 Carbon black and lung cancer Testing a new exposure metric in a German cohort Am J Ind Med 50 8 565 567 doi 10 1002 ajim 20491 PMID 17620319 Occupational Safety and Health Guidelines for carbon black Potential Human Carcinogen Centres of Disease Control and Prevention National Institute for Occupational Safety and Health PDF Retrieved 2013 01 14 Occupational Safety and Health Guideline for Carbon Black Potential Human Carcinogen PDF Centers of Disease Control and Prevention National Institute for Occupational Safety and Health Retrieved 11 January 2013 CDC NIOSH Pocket Guide to Chemical Hazards Carbon black www cdc gov Retrieved 2015 11 27 Further reading editDoerner Max The Materials of the Artist and Their Use in Painting With Notes on the Techniques of the Old Masters Revised Edition Harcourt 1984 ISBN 0 15 657716 X This is a contemporary English language edition of a work originally published in German Meyer Ralph The Artist s Handbook of Materials and Techniques Fifth Edition Revised and Updated Viking 1991 ISBN 0 670 83701 6 Carbon Black A users guide Published by the International Carbon Black Association External links edit nbsp Wikisource has the text of a 1920 Encyclopedia Americana article about Carbon black nbsp Wikimedia Commons has media related to Carbon black International Chemical Safety Card 0471 Carbon black NIOSH Pocket Guide to Chemical Hazards CDC website entry Carbon Black Industry from the Handbook of Texas Online International Carbon Black Association Special Carbon Blacks PentaCarbon GmbH Retrieved from https en wikipedia org w index php title Carbon black amp oldid 1189471388, wikipedia, wiki, book, books, library,

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