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Copper phthalocyanine

January 01, 1970

Copper phthalocyanine (CuPc), also called phthalocyanine blue, phthalo blue and many other names, is a bright, crystalline, synthetic blue pigment from the group of dyes based on phthalocyanines. Its brilliant blue is frequently used in paints and dyes. It is highly valued for its superior properties such as light fastness, tinting strength, covering power and resistance to the effects of alkalis and acids. It has the appearance of a blue powder, insoluble in most solvents including water.

Copper phthalocyanine
Names
IUPAC name
(29H,31H-phthalocyaninato(2−)-N29,N30,N31,N32)copper(II)
Other names
Copper(II) phthalocyanine
Monastral blue
Phthalocyanine blue
Phthalo blue
Thalo blue
Pigment Blue 15
Identifiers
  • 147-14-8 Y
3D model (JSmol)
  • Interactive image
ChEBI
  • CHEBI:155903
ChemSpider
  • 8631
ECHA InfoCard 100.005.169
  • 6531516
UNII
  • 3VEX9T7UT5 Y
  • DTXSID8027117
  • InChI=1S/C32H16N8.Cu/c1-2-10-18-17(9-1)25-33-26(18)38-28-21-13-5-6-14-22(21)30(35-28)40-32-24-16-8-7-15-23(24)31(36-32)39-29-20-12-4-3-11-19(20)27(34-29)37-25;/h1-16H;/q-2;+2
    Key: XCJYREBRNVKWGJ-UHFFFAOYSA-N
  • C1=CC=C2C(=C1)C3=NC4=NC(=NC5=C6C=CC=CC6=C([N-]5)N=C7C8=CC=CC=C8C(=N7)N=C2[N-]3)C9=CC=CC=C94.[Cu+2]
Properties
C32H16CuN8
Molar mass 576.082 g·mol−1
Appearance dark blue solid
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Phthalo blue
 
Phthalocyanine blue pigment powder
    Color coordinates
Hex triplet#000F89
sRGBB (r, g, b)(0, 15, 137)
HSV (h, s, v)(233°, 100%, 54%)
CIELChuv (L, C, h)(16, 61, 265°)
Source
ISCC–NBS descriptorVivid blue
B: Normalized to [0–255] (byte)
H: Normalized to [0–100] (hundred)

History edit

The discovery of metal phthalocyanines can be traced to the observation of intensely colored byproducts from reactions of phthalic acid (benzene-1,2-dicarboxylic acid) or its derivatives with sources of nitrogen and metals. CuPc (copper phthalocyanine) was first prepared in 1927 by the reaction of copper(I) cyanide and o-dibromobenzene, which mainly produces colorless phthalonitrile as well as an intensely blue by-product. A couple of years later, workers at Scottish Dyes observed the formation of traces of phthalocyanine dyes in the synthesis of phthalimide by the reaction of phthalic anhydride and ammonia in the presence of metallic iron. In 1937, DuPont started producing copper phthalocyanine blue in the USA under the trade name Monastral Blue after it had been previously launched in Great Britain (ICI) and Germany (I.G. Farbenindustrie) in 1935.[1]

Difficulty was experienced in forming stable dispersions with the first alpha forms, especially in mixtures with rutile titanium, where the blue pigment tended to flocculate. The beta form was more stable, as was the improved stabilized alpha form. Today, there are even more isomeric forms available.

Synonyms and trade names edit

The substance, IUPAC name (29H,31H-phthalocyaninato(2−)-N29,N30,N31,N32)copper(II), is known by many names[2] such as monastral blue, phthalo blue, helio blue,[3] thalo blue, Winsor blue,[4] phthalocyanine blue, C.I. Pigment Blue 15:2,[5][6] copper phthalocyanine blue,[7] copper tetrabenzoporphyrazine,[8] Cu-phthaloblue,[9] P.B.15.2,[10][11][12] C.I. 74160,[13][14][15] and British Rail Blue.[16] Numerous other trade names and synonyms exist.[17] The abbreviation "CuPc" is also used.[18]

Manufacture edit

Two manufacturing processes have gained commercial importance for the production of copper phthalocyanine:

Both approaches can be carried out either without (baking process) or with a solvent (solvent process). Higher yields may be achieved with the solvent process (> 95%) than with the baking process (70 to 80%), so that the solvent process has initially simulated more interest. However, recents trends show a reverse tendency for the baking process mainly on the grounds of economical and ecological concerns (solvent-free, shorter lead time).

Phthalonitrile process edit

This approach involves heating phthalonitrile with a copper salt, usually copper(I)chloride at 200°C to 240°C. The gross reaction equation from phthalonitrile may be written as follows:

 

Phthalic anhydride/urea process edit

The gross reaction equation from phthalic anhydride and urea may be written as follows:

 

Applications edit

 
AFM image of Fe and Co phthalocyanines

Catalysis edit

Metal phthalocyanines have long been examined as catalysts for redox reactions. Areas of interest are the oxygen reduction reaction and the sweetening of gas streams by removal of hydrogen sulfide.[citation needed]

Colorant edit

Due to its stability, phthalo blue is also used in inks, coatings, and many plastics. The pigment is insoluble and has no tendency to migrate in the material. It is a standard pigment used in printing ink and the packaging industry. Industrial production was of the order of 10,000 tonnes per annum in the 1980s and 1990s in Japan alone.[17] The pigment is the highest volume pigment produced.[19]

All major artists' pigment manufacturers produce variants of copper phthalocyanine, designated color index PB15 (blue) and color indexes PG7 and PG36 (green).

A common component on the artist's palette, phthalo blue is a cool blue with a bias towards green. It has intense tinting strength and easily overpowers the mix when combined with other colors. It is a transparent staining color and can be applied using glazing techniques.

It is present in a wide variety of products,[20] such as color deposition hair conditioner,[21] gel ink pens, eye patches, parfum, shampoo, skin-care products, soap, sunscreen, tattoo ink,[22] toothpaste,[23] and even turf colorants. [24]

Research edit

CuPc has often been investigated in the context of molecular electronics. It is potentially suited for organic solar cells because of its high chemical stability and uniform growth.[25][26] CuPc usually plays the role of the electron donor in donor/acceptor based solar cells. One of the most common donor/acceptor architectures is CuPc/C60 (buckminsterfullerene) which rapidly became a model system for the study of small organic molecules.[27][28] Photon to electron conversion efficiency in such system reaches approximately 5%.

CuPc has also been investigated as a component of organic field-effect transistors.[29] Copper Phthalocyanine (CuPc) has been suggested for data storage in quantum computing, due to the length of time its electrons can remain in superposition.[30] CuPc can be easily processed into a thin film for use in device fabrication, which makes it an attractive qubit candidate.[31]

Derivatives and related compounds edit

Approximately 25% of all artificial organic pigments are phthalocyanine derivatives.[32] Copper phthalocyanine dyes are produced by introducing solubilizing groups, such as one or more sulfonic acid functions. These dyes find extensive use in various areas of textile dyeing (Direct dyes for cotton), for spin dyeing and in the paper industry. Direct blue 86 is the sodium salt of CuPc-sulfonic acid, whereas direct blue 199 is the quaternary ammonium salt of the CuPc-sulfonic acid. The quaternary ammonium salts of these sulfonic acids are used as solvent dyes because of their solubility in organic solvents, such as Solvent Blue 38 and Solvent Blue 48. The dye derived from cobalt phthalocyanine and an amine is Phthalogen Dye IBN. 1,3-Diiminoisoindolene, the intermediate formed during phthalocyanine manufacture, used in combination with a copper salt affords the dye GK 161.

Copper phthalocyanine is also used as a source material for manufacture of Phthalocyanine Green G.

Other related and commercially available phthalocyanines blue pigments are:

  • Pigment Blue 16 – metal-free phthalocyanine
  • Pigment Blue 75 – cobalt phthalocyanine
  • Pigment Blue 79 – aluminum phthalocyanine

Structure, reactivity and properties edit

 
Portion of crystal structure of CuPc, highlighting its slipped-stack packing motif.[33]

Copper phthalocyanine is a complex of copper(II) with the conjugate base of phthalocyanine, i.e. Cu2+Pc2−. The description is analogous to that for copper porphyrins, which are also formally derived by double deprotonation of porphyrins. CuPc belongs to the D4h point group. It is paramagnetic with one unpaired electron per molecule.

The substance is practically insoluble in water (< 0.1 g/100 ml at 20 °C (68 °F)),[34] but soluble in concentrated sulfuric acid.[17] Density of the solid is ~1.6 g/cm3.[17] The color is due to a π–π* electronic transition, with λmax ≈ 610 nm.[35]

Crystalline phases edit

CuPc crystallizes in various forms (polymorphs). Five different polymorphs have been identified:[36][37][38][39] phases α, β, η, γ and χ. The two most common structures in CuPc are the β phase and the metastable α phase. Those phases can be distinguished by the overlap of their neighboring molecules. The α phase has a larger overlap and thus, a smaller Cu-Cu spacing (~3.8 Å) compared to the β phase (~4.8 Å).[40]

Toxicity and hazards edit

The compound is non-biodegradable, but not toxic to fish or plants.[17] No specific dangers have been associated with this compound.[41] Oral LD50 in mammals is estimated to be greater than 5 g per kg, with no ill effects found at that level of ingestion,[17] for chronic ingestion estimated dose of low concern was 0.2 mg/kg per day in rats.[17] No evidence indicates carcinogenic effects.[17] Sulfonated phthalocyanine has been found to cause neuroanatomical defects in developing chicken embryos when injected directly into incubating eggs.[42]

See also edit

References edit

  1. ^ Löbbert, Gerd (2000). "Phthalocyanines". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a20_213. ISBN 978-3527306732..
  2. ^ "Substance Information". ECHA. Retrieved 2021-11-18.
  3. ^ Toxic Substances Control Act Chemical Substance Inventory: volume 2
  4. ^ Spectroscopic Properties of Inorganic and Organometallic Compounds: volume 40
  5. ^ Chem Product Index by Friedrich W. Derz
  6. ^ Coloring of Plastics: Fundamentals, r. Robert A. Charvat
  7. ^ Paint and Coating Testing Manual, e. Joseph V. Koleske
  8. ^ User guide and indices to the initial inventory, substance name index, US EPA
  9. ^ Industrial Organic Pigments: Production, Crystal Structures, Properties, Applications by Klaus Hunger & Martin U. Schmidt
  10. ^ The Porphyrin Handbook: Applications of Phthalocyanines, e. Karl Kadish, Kevin M. Smith & Roger Guilard
  11. ^ Tattoo Inks: Analysis, Pigments, Legislation by Gerald Prior
  12. ^ Pigment + Füllstoff: Tabellen by Olaf Lückert
  13. ^ Material Safety Data Sheets Service 7:89, Information Handling Services
  14. ^ Coloring of Food, Drugs, and Cosmetics by Gisbert Otterstätter
  15. ^ Chemical Formulation: An Overview of Surfactant Based Chemical Preparations Used in Everyday Life by Anthony E. Hargreaves
  16. ^ Waterloo Station: A History of London's busiest terminus by Robert Lordan
  17. ^ a b c d e f g h COPPER PHTHALOCYANINE, CAS No.: 147-14-8 2017-05-16 at the Wayback Machine inchem.org
  18. ^ e.g. Structural and Transport Properties of Copper Phthalocyanine (CuPc) Thin Films 2012-03-05 at the Wayback Machine www.egmrs.org
  19. ^ Gregory, Peter (2000). "Industrial applications of phthalocyanines". Journal of Porphyrins and Phthalocyanines. 4 (4). worldscinet.com: 432–437. doi:10.1002/(SICI)1099-1409(200006/07)4:4<432::AID-JPP254>3.0.CO;2-N.
  20. ^ "Ci 74160 (With Product List)".
  21. ^ "Color Deposition Conditioner "Ultra Violet"".
  22. ^ Miranda, Michelle D. (2016) Forensic Analysis of Tattoos and Tattoo Inks. Routledge. ISBN 9780367778439 p. 163: Muddy Water Blue
  23. ^ "Dentalux Complex 7 Total Care Plus Zahncreme Inhaltsstoffe – Hautschutzengel".
  24. ^ "Vertmax Turf pigment and paint". 17 February 2022.
  25. ^ Szybowicz, M (October 2004). "High temperature study of FT-IR and Raman scattering spectra of vacuum deposited CuPc thin films". Journal of Molecular Structure. 704 (1–3): 107–113. Bibcode:2004JMoSt.704..107S. doi:10.1016/j.molstruc.2004.01.053.
  26. ^ Bala, M; Wojdyla, M; Rebarz, M; Szybowic, M; Drozdowski, M; Grodzicki, A; Piszczek, P (2009). "Influence of central metal atom in MPc (M = Cu, Zn, Mg, Co) on Raman, FT-IR, absorbance, reflectance, and photoluminescence spectra". J. Optoelectron. Adv. M. 11 (3): 264–269.
  27. ^ Jailaubekov, Askat E.; Willard, Adam P.; Tritsch, John R.; Chan, Wai-Lun; Sai, Na; Gearba, Raluca; Kaake, Loren G.; Williams, Kenrick J.; Leung, Kevin; Rossky, Peter J.; Zhu, X-Y. (2013). "Hot charge-transfer excitons set the time limit for charge separation at donor/acceptor interfaces in organic photovoltaics". Nature Materials. 12 (1): 66–73. Bibcode:2013NatMa..12...66J. doi:10.1038/nmat3500. PMID 23223125.
  28. ^ Xin, Li (January 2013). "CuPc/C60 bulk heterojunction photovoltaic cells with evidence of phase segregation". Organic Electronics. 14: 250–254. doi:10.1016/j.orgel.2012.10.041.
  29. ^ Chaidogiannos, G.; Petraki, F.; Glezos, N.; Kennou, S.; Nešpůrek, S. (2009). "Low voltage operating OFETs based on solution-processed metal phthalocyanines". Applied Physics A. 96 (3): 763. Bibcode:2009ApPhA..96..763C. doi:10.1007/s00339-009-5268-1. S2CID 98694166.
  30. ^ New material for quantum computing discovered out of the blue. phys.org. October 27, 2013
  31. ^ Quenqua, Douglas (November 4, 2013). "A Key to Quantum Computing, Close to Home". The New York Times.
  32. ^ Gerd Löbbert "Phthalocyanines" in Ullmann's Encyclopedia of Industrial Chemistry, 2002, Wiley-VCH, Weinheim. doi:10.1002/14356007.a20_213.
  33. ^ Erk, Peter; Hengelsberg, Heidi; Haddow, Mairi F.; Van Gelder, Richard (2004). "The innovative momentum of crystal engineering". CrystEngComm. 6 (78): 474. doi:10.1039/b409282a.
  34. ^ Copper phthalocyanine chemblink.com
  35. ^ Rzepa, H. S. Monastral: the colour of blue. .imperial.ac.uk 2020-09-21 at the Wayback Machine)
  36. ^ James H., Sharp; Martin, Abkowitz (1973). "Dimeric Structure of a Copper Phthalocyanine Polymorph". J. Phys. Chem. 77 (11): 477–481. doi:10.1021/j100623a012.
  37. ^ Jacques M., Assour (1965). "On the Polymorphic Modifications of Phthalocyanines". J. Phys. Chem. 69 (7): 2295–2299. doi:10.1021/j100891a026.
  38. ^ Hassan, A. K.; Gould, R. D. (2006). "Structural Studies of Thermally Evaporated Thin Films of Copper Phthalocyanine". Physica Status Solidi A. 132 (1): 91–101. Bibcode:1992PSSAR.132...91H. doi:10.1002/pssa.2211320110.
  39. ^ Hai, Wang; Soumaya, Mauthoor; Salahud, Din; Jules A., Gardener; Rio, Chang; Marc, Warner; Gabriel, Aeppli; David W., McComb; Mary P., Ryan; Wei, Wu; Andrew J., Fisher; Marshall, Stoneham; Sandrine, Heutz (June 7, 2010). "Ultralong Copper Phthalocyanine Nanowires with New Crystal Structure and Broad Optical Absorption". ACS Nano. 4 (7): 3921–3926. arXiv:1012.2141. doi:10.1021/nn100782w. PMID 20527798. S2CID 2209898.
  40. ^ Amy C, Cruickshank; Christian J, Dotzler; Salahud, Din; Sandrine, Heutz; Michael F, Toney; Mary P, Ryan (2012). "The crystalline structure of copper phthalocyanine films on ZnO(1100)". Journal of the American Chemical Society. 134 (35): 14302–14305. doi:10.1021/ja305760b. PMID 22897507.
  41. ^ Safety data sheet 2012-02-28 at the Wayback Machine cornelius.co.uk
  42. ^ Sandor, S; Prelipceanu, O; Checiu, I (1985). "Sulphonated phthalocyanine induced caudal malformative syndrome in the chick embryo". Morphol Embryol (Bucur). 31 (3): 173–81. PMID 2931590.

External links edit

  • [usurped] colorantshistory.org
  • Patrick Linstead talking about phthalocyanine Imperial College London, Chemistry department

January 01, 1970
copper, phthalocyanine, cupc, also, called, phthalocyanine, blue, phthalo, blue, many, other, names, bright, crystalline, synthetic, blue, pigment, from, group, dyes, based, phthalocyanines, brilliant, blue, frequently, used, paints, dyes, highly, valued, supe. Copper phthalocyanine CuPc also called phthalocyanine blue phthalo blue and many other names is a bright crystalline synthetic blue pigment from the group of dyes based on phthalocyanines Its brilliant blue is frequently used in paints and dyes It is highly valued for its superior properties such as light fastness tinting strength covering power and resistance to the effects of alkalis and acids It has the appearance of a blue powder insoluble in most solvents including water Copper phthalocyanine Names IUPAC name 29H 31H phthalocyaninato 2 N29 N30 N31 N32 copper II Other names Copper II phthalocyanineMonastral bluePhthalocyanine bluePhthalo blueThalo blue Pigment Blue 15 Identifiers CAS Number 147 14 8 Y 3D model JSmol Interactive image ChEBI CHEBI 155903 ChemSpider 8631 ECHA InfoCard 100 005 169 PubChem CID 6531516 UNII 3VEX9T7UT5 Y CompTox Dashboard EPA DTXSID8027117 InChI InChI 1S C32H16N8 Cu c1 2 10 18 17 9 1 25 33 26 18 38 28 21 13 5 6 14 22 21 30 35 28 40 32 24 16 8 7 15 23 24 31 36 32 39 29 20 12 4 3 11 19 20 27 34 29 37 25 h1 16H q 2 2Key XCJYREBRNVKWGJ UHFFFAOYSA N SMILES C1 CC C2C C1 C3 NC4 NC NC5 C6C CC CC6 C N 5 N C7C8 CC CC C8C N7 N C2 N 3 C9 CC CC C94 Cu 2 Properties Chemical formula C 32H 16Cu N 8 Molar mass 576 082 g mol 1 Appearance dark blue solid Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Infobox references Phthalo blue Phthalocyanine blue pigment powder Color coordinatesHex triplet 000F89sRGBB r g b 0 15 137 HSV h s v 233 100 54 CIELChuv L C h 16 61 265 SourceThe Mother of All HTML Colo u r ChartsISCC NBS descriptorVivid blueB Normalized to 0 255 byte H Normalized to 0 100 hundred Contents 1 History 2 Synonyms and trade names 3 Manufacture 3 1 Phthalonitrile process 3 2 Phthalic anhydride urea process 4 Applications 4 1 Catalysis 4 2 Colorant 5 Research 6 Derivatives and related compounds 7 Structure reactivity and properties 7 1 Crystalline phases 7 2 Toxicity and hazards 8 See also 9 References 10 External linksHistory editThe discovery of metal phthalocyanines can be traced to the observation of intensely colored byproducts from reactions of phthalic acid benzene 1 2 dicarboxylic acid or its derivatives with sources of nitrogen and metals CuPc copper phthalocyanine was first prepared in 1927 by the reaction of copper I cyanide and o dibromobenzene which mainly produces colorless phthalonitrile as well as an intensely blue by product A couple of years later workers at Scottish Dyes observed the formation of traces of phthalocyanine dyes in the synthesis of phthalimide by the reaction of phthalic anhydride and ammonia in the presence of metallic iron In 1937 DuPont started producing copper phthalocyanine blue in the USA under the trade name Monastral Blue after it had been previously launched in Great Britain ICI and Germany I G Farbenindustrie in 1935 1 Difficulty was experienced in forming stable dispersions with the first alpha forms especially in mixtures with rutile titanium where the blue pigment tended to flocculate The beta form was more stable as was the improved stabilized alpha form Today there are even more isomeric forms available Synonyms and trade names editThe substance IUPAC name 29H 31H phthalocyaninato 2 N29 N30 N31 N32 copper II is known by many names 2 such as monastral blue phthalo blue helio blue 3 thalo blue Winsor blue 4 phthalocyanine blue C I Pigment Blue 15 2 5 6 copper phthalocyanine blue 7 copper tetrabenzoporphyrazine 8 Cu phthaloblue 9 P B 15 2 10 11 12 C I 74160 13 14 15 and British Rail Blue 16 Numerous other trade names and synonyms exist 17 The abbreviation CuPc is also used 18 Manufacture editTwo manufacturing processes have gained commercial importance for the production of copper phthalocyanine The phthalonitrile process mainly used in Germany The phthalic anhydride urea process developed in Great Britain and in the USA Both approaches can be carried out either without baking process or with a solvent solvent process Higher yields may be achieved with the solvent process gt 95 than with the baking process 70 to 80 so that the solvent process has initially simulated more interest However recents trends show a reverse tendency for the baking process mainly on the grounds of economical and ecological concerns solvent free shorter lead time Phthalonitrile process edit This approach involves heating phthalonitrile with a copper salt usually copper I chloride at 200 C to 240 C The gross reaction equation from phthalonitrile may be written as follows 4 C 6 H 4 CN 2 Cu 2 2 e CuPc displaystyle ce 4 C6H4 CN 2 Cu 2 2e gt CuPc nbsp Phthalic anhydride urea process edit The gross reaction equation from phthalic anhydride and urea may be written as follows 4 C 6 H 4 CO 2 O 4 NH 2 2 CO Cu 2 2 e CuPc 8 H 2 O 4 CO 2 4 NH 3 displaystyle ce 4 C6H4 CO 2O 4 NH2 2CO Cu 2 2e gt CuPc 8H2O 4CO2 4NH3 nbsp Applications edit nbsp AFM image of Fe and Co phthalocyanines Catalysis edit Metal phthalocyanines have long been examined as catalysts for redox reactions Areas of interest are the oxygen reduction reaction and the sweetening of gas streams by removal of hydrogen sulfide citation needed Colorant edit Due to its stability phthalo blue is also used in inks coatings and many plastics The pigment is insoluble and has no tendency to migrate in the material It is a standard pigment used in printing ink and the packaging industry Industrial production was of the order of 10 000 tonnes per annum in the 1980s and 1990s in Japan alone 17 The pigment is the highest volume pigment produced 19 All major artists pigment manufacturers produce variants of copper phthalocyanine designated color index PB15 blue and color indexes PG7 and PG36 green A common component on the artist s palette phthalo blue is a cool blue with a bias towards green It has intense tinting strength and easily overpowers the mix when combined with other colors It is a transparent staining color and can be applied using glazing techniques It is present in a wide variety of products 20 such as color deposition hair conditioner 21 gel ink pens eye patches parfum shampoo skin care products soap sunscreen tattoo ink 22 toothpaste 23 and even turf colorants 24 Research editCuPc has often been investigated in the context of molecular electronics It is potentially suited for organic solar cells because of its high chemical stability and uniform growth 25 26 CuPc usually plays the role of the electron donor in donor acceptor based solar cells One of the most common donor acceptor architectures is CuPc C60 buckminsterfullerene which rapidly became a model system for the study of small organic molecules 27 28 Photon to electron conversion efficiency in such system reaches approximately 5 CuPc has also been investigated as a component of organic field effect transistors 29 Copper Phthalocyanine CuPc has been suggested for data storage in quantum computing due to the length of time its electrons can remain in superposition 30 CuPc can be easily processed into a thin film for use in device fabrication which makes it an attractive qubit candidate 31 Derivatives and related compounds editApproximately 25 of all artificial organic pigments are phthalocyanine derivatives 32 Copper phthalocyanine dyes are produced by introducing solubilizing groups such as one or more sulfonic acid functions These dyes find extensive use in various areas of textile dyeing Direct dyes for cotton for spin dyeing and in the paper industry Direct blue 86 is the sodium salt of CuPc sulfonic acid whereas direct blue 199 is the quaternary ammonium salt of the CuPc sulfonic acid The quaternary ammonium salts of these sulfonic acids are used as solvent dyes because of their solubility in organic solvents such as Solvent Blue 38 and Solvent Blue 48 The dye derived from cobalt phthalocyanine and an amine is Phthalogen Dye IBN 1 3 Diiminoisoindolene the intermediate formed during phthalocyanine manufacture used in combination with a copper salt affords the dye GK 161 Copper phthalocyanine is also used as a source material for manufacture of Phthalocyanine Green G Other related and commercially available phthalocyanines blue pigments are Pigment Blue 16 metal free phthalocyanine Pigment Blue 75 cobalt phthalocyanine Pigment Blue 79 aluminum phthalocyanineStructure reactivity and properties edit nbsp Portion of crystal structure of CuPc highlighting its slipped stack packing motif 33 Copper phthalocyanine is a complex of copper II with the conjugate base of phthalocyanine i e Cu2 Pc2 The description is analogous to that for copper porphyrins which are also formally derived by double deprotonation of porphyrins CuPc belongs to the D4h point group It is paramagnetic with one unpaired electron per molecule The substance is practically insoluble in water lt 0 1 g 100 ml at 20 C 68 F 34 but soluble in concentrated sulfuric acid 17 Density of the solid is 1 6 g cm3 17 The color is due to a p p electronic transition with lmax 610 nm 35 Crystalline phases edit CuPc crystallizes in various forms polymorphs Five different polymorphs have been identified 36 37 38 39 phases a b h g and x The two most common structures in CuPc are the b phase and the metastable a phase Those phases can be distinguished by the overlap of their neighboring molecules The a phase has a larger overlap and thus a smaller Cu Cu spacing 3 8 A compared to the b phase 4 8 A 40 Toxicity and hazards edit The compound is non biodegradable but not toxic to fish or plants 17 No specific dangers have been associated with this compound 41 Oral LD50 in mammals is estimated to be greater than 5 g per kg with no ill effects found at that level of ingestion 17 for chronic ingestion estimated dose of low concern was 0 2 mg kg per day in rats 17 No evidence indicates carcinogenic effects 17 Sulfonated phthalocyanine has been found to cause neuroanatomical defects in developing chicken embryos when injected directly into incubating eggs 42 See also editPhthalocyanine Green G British Rail corporate liveries Rail Blue use of the pigment as the standard livery for British Rail trains from 1965 onwards The Joy of Painting oil paint based on the pigment was frequently used on the show List of colorsReferences edit Lobbert Gerd 2000 Phthalocyanines Ullmann s Encyclopedia of Industrial Chemistry Weinheim Wiley VCH doi 10 1002 14356007 a20 213 ISBN 978 3527306732 Substance Information ECHA Retrieved 2021 11 18 Toxic Substances Control Act Chemical Substance Inventory volume 2 Spectroscopic Properties of Inorganic and Organometallic Compounds volume 40 Chem Product Index by Friedrich W Derz Coloring of Plastics Fundamentals r Robert A Charvat Paint and Coating Testing Manual e Joseph V Koleske User guide and indices to the initial inventory substance name index US EPA Industrial Organic Pigments Production Crystal Structures Properties Applications by Klaus Hunger amp Martin U Schmidt The Porphyrin Handbook Applications of Phthalocyanines e Karl Kadish Kevin M Smith amp Roger Guilard Tattoo Inks Analysis Pigments Legislation by Gerald Prior Pigment Fullstoff Tabellen by Olaf Luckert Material Safety Data Sheets Service 7 89 Information Handling Services Coloring of Food Drugs and Cosmetics by Gisbert Otterstatter Chemical Formulation An Overview of Surfactant Based Chemical Preparations Used in Everyday Life by Anthony E Hargreaves Waterloo Station A History of London s busiest terminus by Robert Lordan a b c d e f g h COPPER PHTHALOCYANINE CAS No 147 14 8 Archived 2017 05 16 at the Wayback Machine inchem org e g Structural and Transport Properties of Copper Phthalocyanine CuPc Thin Films Archived 2012 03 05 at the Wayback Machine www egmrs org Gregory Peter 2000 Industrial applications of phthalocyanines Journal of Porphyrins and Phthalocyanines 4 4 worldscinet com 432 437 doi 10 1002 SICI 1099 1409 200006 07 4 4 lt 432 AID JPP254 gt 3 0 CO 2 N Ci 74160 With Product List Color Deposition Conditioner Ultra Violet Miranda Michelle D 2016 Forensic Analysis of Tattoos and Tattoo Inks Routledge ISBN 9780367778439 p 163 Muddy Water Blue Dentalux Complex 7 Total Care Plus Zahncreme Inhaltsstoffe Hautschutzengel Vertmax Turf pigment and paint 17 February 2022 Szybowicz M October 2004 High temperature study of FT IR and Raman scattering spectra of vacuum deposited CuPc thin films Journal of Molecular Structure 704 1 3 107 113 Bibcode 2004JMoSt 704 107S doi 10 1016 j molstruc 2004 01 053 Bala M Wojdyla M Rebarz M Szybowic M Drozdowski M Grodzicki A Piszczek P 2009 Influence of central metal atom in MPc M Cu Zn Mg Co on Raman FT IR absorbance reflectance and photoluminescence spectra J Optoelectron Adv M 11 3 264 269 Jailaubekov Askat E Willard Adam P Tritsch John R Chan Wai Lun Sai Na Gearba Raluca Kaake Loren G Williams Kenrick J Leung Kevin Rossky Peter J Zhu X Y 2013 Hot charge transfer excitons set the time limit for charge separation at donor acceptor interfaces in organic photovoltaics Nature Materials 12 1 66 73 Bibcode 2013NatMa 12 66J doi 10 1038 nmat3500 PMID 23223125 Xin Li January 2013 CuPc C60 bulk heterojunction photovoltaic cells with evidence of phase segregation Organic Electronics 14 250 254 doi 10 1016 j orgel 2012 10 041 Chaidogiannos G Petraki F Glezos N Kennou S Nespurek S 2009 Low voltage operating OFETs based on solution processed metal phthalocyanines Applied Physics A 96 3 763 Bibcode 2009ApPhA 96 763C doi 10 1007 s00339 009 5268 1 S2CID 98694166 New material for quantum computing discovered out of the blue phys org October 27 2013 Quenqua Douglas November 4 2013 A Key to Quantum Computing Close to Home The New York Times Gerd Lobbert Phthalocyanines in Ullmann s Encyclopedia of Industrial Chemistry 2002 Wiley VCH Weinheim doi 10 1002 14356007 a20 213 Erk Peter Hengelsberg Heidi Haddow Mairi F Van Gelder Richard 2004 The innovative momentum of crystal engineering CrystEngComm 6 78 474 doi 10 1039 b409282a Copper phthalocyanine chemblink com Rzepa H S Monastral the colour of blue imperial ac uk Archived 2020 09 21 at the Wayback Machine James H Sharp Martin Abkowitz 1973 Dimeric Structure of a Copper Phthalocyanine Polymorph J Phys Chem 77 11 477 481 doi 10 1021 j100623a012 Jacques M Assour 1965 On the Polymorphic Modifications of Phthalocyanines J Phys Chem 69 7 2295 2299 doi 10 1021 j100891a026 Hassan A K Gould R D 2006 Structural Studies of Thermally Evaporated Thin Films of Copper Phthalocyanine Physica Status Solidi A 132 1 91 101 Bibcode 1992PSSAR 132 91H doi 10 1002 pssa 2211320110 Hai Wang Soumaya Mauthoor Salahud Din Jules A Gardener Rio Chang Marc Warner Gabriel Aeppli David W McComb Mary P Ryan Wei Wu Andrew J Fisher Marshall Stoneham Sandrine Heutz June 7 2010 Ultralong Copper Phthalocyanine Nanowires with New Crystal Structure and Broad Optical Absorption ACS Nano 4 7 3921 3926 arXiv 1012 2141 doi 10 1021 nn100782w PMID 20527798 S2CID 2209898 Amy C Cruickshank Christian J Dotzler Salahud Din Sandrine Heutz Michael F Toney Mary P Ryan 2012 The crystalline structure of copper phthalocyanine films on ZnO 1100 Journal of the American Chemical Society 134 35 14302 14305 doi 10 1021 ja305760b PMID 22897507 Safety data sheet Archived 2012 02 28 at the Wayback Machine cornelius co uk Sandor S Prelipceanu O Checiu I 1985 Sulphonated phthalocyanine induced caudal malformative syndrome in the chick embryo Morphol Embryol Bucur 31 3 173 81 PMID 2931590 External links editDiscovery of a new pigment Monastral blue usurped colorantshistory org Patrick Linstead talking about phthalocyanine Imperial College London Chemistry department Retrieved from https en wikipedia org w index php title Copper phthalocyanine amp oldid 1214919050, wikipedia, wiki, book, books, library,

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