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Polyphenyl ether

January 29, 2023

Phenyl ether polymers are a class of polymers that contain a phenoxy or a thiophenoxy group as the repeating group in ether linkages. Commercial phenyl ether polymers belong to two chemical classes: polyphenyl ethers (PPEs) and polyphenylene oxides (PPOs). The phenoxy groups in the former class of polymers do not contain any substituents whereas those in the latter class contain 2 to 4 alkyl groups on the phenyl ring. The structure of an oxygen-containing PPE is provided in Figure 1 and that of a 2, 6-xylenol derived PPO is shown in Figure 2. Either class can have the oxygen atoms attached at various positions around the rings.

Figure 1: Representative Structure of Polyphenyl Ether (PPE)
Figure 2: Representative Structure of Polyphenylene Oxide (PPO)

Structure and synthesis

 
Figure 3: Ullmann Ether Synthesis of 4R2E (p-diphenoxybenzene), a simple polyphenyl ether
 
Figure 4: Structure of 2R1E diphenyl ether
 
Figure 5: structure of 3R2TE polyphenyl thioether

The proper name for a phenyl ether polymer is poly(phenyl ether) or polyphenyl polyether, but the name polyphenyl ether is widely accepted. Polyphenyl ethers (PPEs) are obtained by repeated application of the Ullmann Ether Synthesis: reaction of an alkali-metal phenate with a halogenated benzene catalyzed by copper.[1]

PPEs of up to 6 phenyl rings, both oxy and thio ethers, are commercially available. See Table 1.[2] They are characterized by indicating the substitution pattern of each ring, followed by the number of phenyl rings and the number of ether linkages. Thus, the structure in Figure 1 with n equal to 1 is identified as pmp5P4E, indicating para, meta, para substitution of the three middle rings, a total of 5 rings, and 4 ether linkages. Meta substitution of the aryl rings in these materials is most common and often desired. Longer chain analogues with up to 10 benzene rings are also known.

The simplest member of the phenyl ether family is diphenyl ether (DPE), also called diphenyl oxide, the structure of which is provided in Figure 4. Low molecular weight polyphenyl ethers and thioethers are used in a variety of applications, and include high-vacuum devices, optics, electronics, and in high-temperature and radiation-resistant fluids and greases. Figure 5 shows the structure of the sulfur analogue of 3-R polyphenyl ether shown in Figure 3.

Table 1: commercial polyphenyl ether products (PPEs)
Common and trade name Chemical name
Six-ring polyphenyl ether (6P5E); trade name: OS-138 Bis[m-(m-phenoxyphenoxy) phenyl] ether
Five-ring polyphenyl ether (5P4E); trade name: OS-124 m-Bis(m-phenoxyphenoxy)benzene
Four-ring polyphenyl ether (4P3E); trade name: MCS-210 Bis (m-phenoxyphenyl) ether
Three- and four-ring oxy- and thioethers; trade name: MCS-293 Thiobis[phenoxybenzene] and bis (phenylmercapto)benzene
Three-ring polyphenyl ether (3P2E); trade name: MCS-2167 m-Diphenoxybenzene
Two-ring diphenyl ether (2P1E) Diphenyl ether, diphenyl oxide, phenoxybenzene

Physical properties

Typical physical properties of polyphenyl ethers are provided in Table 2.[3] Physical properties of a particular PPE depend upon the number of aromatic rings, their substitution pattern, and whether it is an ether or a thioether. In the case of products of mixed structures, properties are hard to predict from only the structural features; hence, they must be determined via measurement.

The important attributes of PPEs include their thermal and oxidative stability and stability in the presence of ionizing radiation. PPEs have the disadvantage of having somewhat high pour points. For example, PPEs that contain two and three benzene rings are actually solids at room temperatures. The melting points of the ordinarily solid PPEs are lowered if they contain more m-phenylene rings, alkyl groups, or are mixtures of isomers. PPEs that contain only o- and p-substituted rings have the highest melting points.

Table 2: physical properties of polyphenyl ethers
Polyphenyl ether Appearance Pour point
(°C; °F) 		Thermal stability
(°C; °F) 		Viscosity (cSt),
at 100 °F (38 °C) 		Viscosity (cSt),
at 210 °F (99 °C)
6-ring 6P5E Clear liquid 10; 50 447; 836 2000 25
5-ring 5P4E Clear liquid 4.5; 40 453; 847 360 13
4-ring 4P3E Clear liquid −12; 10 441; 825 70 6
3- and 4-ring oxythio Hazy liquid −29; −20 367; 693 25 4
3-ring 3P2E Solid - 427; 800 12 3
2-ring 2P1E Solid - 316; >600 2.4 1.6

Thermo-oxidative stability

PPEs have excellent high temperature properties and good oxidation stability. With respect to volatilities, p-derivatives have the lowest volatilities, and the o-derivatives have the highest volatilities. The opposite is true for flash points and fire points. Spontaneous ignition temperatures of polyphenyl ethers lie between 550 and 595 °C (1,022 and 1,103 °F), alkyl substitution reduces this value by ~50 °C (122 °F). PPEs are compatible with most metals and elastomers that are commonly used in high-temperature applications. They typically swell common seal materials.[4]

Oxidation stability of un-substituted PPEs is quite good, partly because they lack easily oxidizable carbon-hydrogen bonds. Thermal decomposition temperature, as measured by the isoteniscope procedure, is between 440 and 465 °C (824 and 869 °F).

Radiation stability

Ionizing radiation affects all organic compounds, causing a change in their properties because radiation disrupts covalent bonds that are most prevalent in organic compounds. One result of ionization is that the organic molecules disproportionate to form smaller hydrocarbon molecules as well as larger hydrocarbons molecules. This is reflected by increased evaporation loss, lowering of the flash and fire points, and increased viscosity. Other chemical reactions caused by radiation include oxidation and isomerization. The former leads to increased acidity, corrosivity, and coke formation; the latter causes a change in viscosity and volatility.

PPEs have extremely high radiation resistance. Of all classes of synthetic lubricants (with the possible exception of perfluoropolyethers) the polyphenyl ethers are the most radiation resistant.[5] Excellent radiation stability of PPEs can be ascribed to the limited number of ionizable carbon-carbon and carbon-hydrogen bonds. In one study, the performance of PPE under the influence of 1×1011 ergs/gram of radiation at 99 °C (210 °F) was compared with synthetic ester, synthetic hydrocarbon, and silicone fluids.[6] PPE showed a viscosity increase of only 35%, while all other fluids showed a viscosity increase of 1700% and gelled. Further tests have shown PPEs to be resistant to gamma and associated neutron radiation dosages of 1×1010 erg/g at temperatures up to 315 °C (599 °F).

Surface tension

PPEs have high surface tension; hence these fluids have a lower tendency to wet metal surfaces. The surface tension of the commercially available 5R4E is 49.9 dynes/cm, one of the highest in pure organic liquids.[7] This property is useful in applications where migration of the lubricant into the surrounding environment must be avoided.

Applications

While originally PPEs were developed for use in extreme environments that were experienced in aerospace applications, they are now used in other applications requiring low volatility and excellent thermo-oxidative and ionizing radiation stability. Such applications include use as diffusion pump fluids; high vacuum fluids; and in formulating jet engine lubricants, high-temperature hydraulic lubricants and greases, and heat transfer fluids. In addition, because of excellent optical properties these fluids have found use in optical devices.

Ultra-high-vacuum fluids

Vacuum pumps are devices that remove gases from an enclosed space to greatly reduce pressure. Oil diffusion pumps in combination with a fore pump are amongst the most popular. Diffusion pumps use a high boiling liquid of low vapor pressure to create a high-speed jet that strikes the gaseous molecules in the system to be evacuated and direct them into space that is being evacuated by the fore pump. A good diffusion fluid must therefore reflect low vapor pressure, high flash point, high thermal and oxidative stability and chemical resistance. If the diffusion pump is operating in the proximity of ionizing radiation source, good radiation stability is also desired.

Data presented in Table 3 demonstrates polyphenyl ether to be superior to other fluids that are commonly used in diffusion pumps.[8] PPEs help achieve the highest vacuum of 4×10−10 torr at 25 °C. Such high vacuums are necessary in equipment such as electron microscopes, mass spectrometers and that used for various surface physics studies. Vacuum pumps are also used in the production of electric lamps, vacuum tubes, and cathode ray tubes (CRTs), semiconductor processing, and vacuum engineering.

Table 3: diffusion fluid property comparison
Fluid property Polyphenyl ether
SANTOVAC 5 		Silicone
Dow Corning 		Hydrocarbon oil
Apiezon
Vapor pressure, Torr at 25 °C 4×10−10 2×10−8 5×10−6
Molecular weight 446 484 420
Density at 25 °C 1.20 1.07 0.87
Flash point, °C 288 221 243
Boiling point at 1.3 mbar, °C 295 223 220
Viscosity (cSt) at 25 °C 1000 40 135
Viscosity (cSt) at 100 °C 12.0 4.3 7.0
Surface tension, dynes/cm 49.9 30.5 30.5
Refractive index at 25 °C, 589 nm 1.67 1.56 1.48
Thermal stability Excellent Good Poor
Oxidation resistance Excellent Excellent Poor-fair
Chemical resistance Excellent Good Poor
Radiation resistance Excellent Good Fair

Electronic connector lubricants

5R4E PPE has a surface tension of 49.9 dynes/cm, which is amongst the highest in pure organic liquids. Because of this, this PPE and the other PPEs do not effectively wet metal surfaces. This property is useful when migration of a lubricant from one part of the equipment to another part must be avoided, such as in certain electronic devices. A thin film of polyphenyl ether on a surface is not a thin contiguous film as one would envision, but rather comprises tiny droplets. This PPE property tends to keep the film stationary, or at least to cause it to remain in the area where the lubrication is needed, rather than migrating away by spreading and forming a new surface. As a result, contamination of other components and equipment, which do not require a lubricant, is avoided. The high surface tension of PPEs, therefore, makes them useful in lubricating electronic contacts.

Polyphenyl ether lubricants have a 30-year history of commercial service for connectors with precious and base metal contacts in telecom, automotive, aerospace, instrumentation and general-purpose applications.[9][10] In addition to maintaining the current flow and providing long-term lubrication, PPEs offer protection to connectors against aggressive acidic and oxidative environments. By providing a protective surface film, polyphenyl ethers not only protect connectors against corrosion but also against vibration-related wear and abrasion that leads to fretting wear. The devices that benefit from the specialized properties of PPEs include cell phones, printers, and a variety of other electronic appliances. The protection lasts for decades or for the life of the equipment.

Optics

Polyphenyl ethers (PPEs) possess good optical clarity, a high refractive index, and other beneficial optical properties. Because of these, PPEs have the ability to meet the rigorous performance demands of signal processing in advanced photonics systems. Optical clarity of PPEs resembles that of the other optical polymers, that is, they have refractive indices of between 1.5 and 1.7 and provide good propagation of light between approximately 400 nm and 1700 nm. Close refractive index (RI) matching between materials is important for proper propagation of light through them. Because of the ease of RI matching, PPEs are used in many optical devices as optical fluids. Extreme resistance to ionizing radiation gives PPEs an added advantage in the manufacture of solar cells and solid-state UV/blue emitters and telecommunication equipment made from high-index glasses and semiconductors.

High-temperature and radiation-resistant lubricants

PPEs, being of excellent thermo-oxidative stability and radiation resistance, have found extensive use in high temperature applications that also require radiation resistance. In addition, PPEs demonstrate better wear control and load-carrying ability than mineral oils, especially when used in bearings.

PPEs were developed for use in jet engines that involved high speed-related frictional temperatures of as high as 320 °C (608 °F). While the use of PPEs in lubricating jet engines has somewhat subsided due to their higher cost, they are still used in some aerospace applications. PPEs are also used as base fluids for radiation-resistant greases used in nuclear power plant mechanisms. PPEs and their derivatives have also found use as vapor phase lubricants in gas turbines and custom bearings, and wherever extreme environmental conditions exist. Vapor phase lubrication is achieved by heating the liquid lubricant above its boiling point. The resultant vapors are then transported to the hot bearing surface. If the temperatures of the bearing surface are kept below the lubricant’s boiling point, the vapors re-condense to provide liquid lubrication.

Polyphenyl ether technology can also provide superior fire safety and fatigue life, depending on the specific bearing design. In this application, PPEs have the advantage of providing lubrication both as a liquid at low temperatures and as a vapor at temperatures above 315 °C (599 °F). Due to the low volatility and excellent high-temperature thermo-oxidative stability, PPEs have also found use as a lubricant for chains used in and around kilns, metal fabrication plants, and glass molding and manufacturing equipment. In these high-temperature applications, PPEs do not form any sludge and hard deposits. The low soft-carbon residue that is left behind is removed easily by wiping. PPEs' low volatility, low flammability, and good thermodynamic properties make them ideally suited for use as heat transfer fluids and in heat sink applications as well.[11]

Polyphenylene oxides (PPOs)

Main article: Poly(p-phenylene oxide)

These polymers are made through oxidative coupling of substituted phenol in the presence of oxygen and copper and amine containing catalysts, such as cuprous bromide and pyridine. See Figure 2 for the PPO structure. PPO polymers can be classified as plastic resins. They and their composites with polystyrene, glass, and nylon are used as high-strength, moisture-resistant engineering plastics in a number of industries, including computer, telecommunication, and automotive parts. PPOs are marketed by SABIC Innovative Plastics under the trademarked name of Noryl.[12]

References

  1. ^ "The Ullmann Ether Condensation," by A A Moroz and Mark S Shvartsberg, 1974, Russ. Chem. Rev. 43 (8), 679-689
  2. ^ SANTOLUBES LLC Product Brochure
  3. ^ Joaquim, M., "Polyphenyl Ether Lubricants" Synthetic Lubricants and High-performance Functional Fluids", R. L. Rudnick and R. L. Shubkin, Eds., p. 239, Marcel Dekker, Inc., NY, 1999
  4. ^ "Synthetic Lubricants," Chapter 6, pp. 96–153, Lubricants and Related Products: Synthesis, Properties, Applications, International Standards by Dieter Klamann, Verlag Chemie Gmbh publisher (1984)
  5. ^ Bolt, R. O., "Radiation Effects on Lubricants," CRC Handbook of Lubrication, Vol. I, Theory and Practice of Tribology: Applications and Maintenance, pp. 3–44 , Richard E. Booser Editor, CRC Press, Boca Raton, 1983. Carroll, J. G. and Bolt. R. O., Radiation Effects on Organic Materials, Bolt. R. O. and Carroll, J. G., Eds., Academic Press, New York, 1963
  6. ^ Joaquim, M. E. and J. F. Herber, "Lubrication of Electronic Connectors and Equipment in Radiation Environments, http://www.chemassociates.com/products/findett/PPEs_Radiation2.pdf
  7. ^ The Surface Tension of Pure Liquid Compounds, Joseph J. Jasper, J. Phys. Chem. Ref. Data, Vol. 1, No. 4, 1972; https://www.nist.gov/srd/PDFfiles/jpcrd13.pdf
  8. ^ "Inside a Vacuum Diffusion Pump," by Manuel E. Joaquim and Bill Foley; http://www.xtronix.ch/pdf/Diffusion%20Pump.pdf
  9. ^ Using Lubricants to Avoid Failures in Medical Electronic Connectors," by Sibtain Hamid in Medical Electronics Manufacturing, Spring 2004 and SANTOLUBES Brochure on Stationary lubricants prevent connector failures
  10. ^ SANTOLUBES Brochure on Stationary lubricants prevent connector failures
  11. ^ Hamid, S. and Burian, S. A., "Polyphenyl Ether Lubricants," published in Synthetics, Mineral Oils, and Bio-based Lubricants: Chemistry and Technology, Leslie R. Rudnick Editor, pp. 175–199, Taylor and Francis Publisher
  12. ^ 2002grc087 High Heat PPO.: 13C and 31P NMR Methods for Characterizing End Groups and Chain Structures in Poly(2,6-dimethyl-1,4-phenylene oxide)/Poly(2,3,6-trimethyl-1,4-phenylene oxide) Copolymers[permanent dead link]

January 29, 2023
polyphenyl, ether, phenyl, ether, polymers, class, polymers, that, contain, phenoxy, thiophenoxy, group, repeating, group, ether, linkages, commercial, phenyl, ether, polymers, belong, chemical, classes, polyphenyl, ethers, ppes, polyphenylene, oxides, ppos, p. Phenyl ether polymers are a class of polymers that contain a phenoxy or a thiophenoxy group as the repeating group in ether linkages Commercial phenyl ether polymers belong to two chemical classes polyphenyl ethers PPEs and polyphenylene oxides PPOs The phenoxy groups in the former class of polymers do not contain any substituents whereas those in the latter class contain 2 to 4 alkyl groups on the phenyl ring The structure of an oxygen containing PPE is provided in Figure 1 and that of a 2 6 xylenol derived PPO is shown in Figure 2 Either class can have the oxygen atoms attached at various positions around the rings Figure 1 Representative Structure of Polyphenyl Ether PPE Figure 2 Representative Structure of Polyphenylene Oxide PPO Contents 1 Structure and synthesis 2 Physical properties 2 1 Thermo oxidative stability 2 2 Radiation stability 2 3 Surface tension 3 Applications 3 1 Ultra high vacuum fluids 3 2 Electronic connector lubricants 3 3 Optics 3 4 High temperature and radiation resistant lubricants 4 Polyphenylene oxides PPOs 5 ReferencesStructure and synthesis Edit Figure 3 Ullmann Ether Synthesis of 4R2E p diphenoxybenzene a simple polyphenyl ether Figure 4 Structure of 2R1E diphenyl ether Figure 5 structure of 3R2TE polyphenyl thioether The proper name for a phenyl ether polymer is poly phenyl ether or polyphenyl polyether but the name polyphenyl ether is widely accepted Polyphenyl ethers PPEs are obtained by repeated application of the Ullmann Ether Synthesis reaction of an alkali metal phenate with a halogenated benzene catalyzed by copper 1 PPEs of up to 6 phenyl rings both oxy and thio ethers are commercially available See Table 1 2 They are characterized by indicating the substitution pattern of each ring followed by the number of phenyl rings and the number of ether linkages Thus the structure in Figure 1 with n equal to 1 is identified as pmp5P4E indicating para meta para substitution of the three middle rings a total of 5 rings and 4 ether linkages Meta substitution of the aryl rings in these materials is most common and often desired Longer chain analogues with up to 10 benzene rings are also known The simplest member of the phenyl ether family is diphenyl ether DPE also called diphenyl oxide the structure of which is provided in Figure 4 Low molecular weight polyphenyl ethers and thioethers are used in a variety of applications and include high vacuum devices optics electronics and in high temperature and radiation resistant fluids and greases Figure 5 shows the structure of the sulfur analogue of 3 R polyphenyl ether shown in Figure 3 Table 1 commercial polyphenyl ether products PPEs Common and trade name Chemical nameSix ring polyphenyl ether 6P5E trade name OS 138 Bis m m phenoxyphenoxy phenyl etherFive ring polyphenyl ether 5P4E trade name OS 124 m Bis m phenoxyphenoxy benzeneFour ring polyphenyl ether 4P3E trade name MCS 210 Bis m phenoxyphenyl etherThree and four ring oxy and thioethers trade name MCS 293 Thiobis phenoxybenzene and bis phenylmercapto benzeneThree ring polyphenyl ether 3P2E trade name MCS 2167 m DiphenoxybenzeneTwo ring diphenyl ether 2P1E Diphenyl ether diphenyl oxide phenoxybenzenePhysical properties EditTypical physical properties of polyphenyl ethers are provided in Table 2 3 Physical properties of a particular PPE depend upon the number of aromatic rings their substitution pattern and whether it is an ether or a thioether In the case of products of mixed structures properties are hard to predict from only the structural features hence they must be determined via measurement The important attributes of PPEs include their thermal and oxidative stability and stability in the presence of ionizing radiation PPEs have the disadvantage of having somewhat high pour points For example PPEs that contain two and three benzene rings are actually solids at room temperatures The melting points of the ordinarily solid PPEs are lowered if they contain more m phenylene rings alkyl groups or are mixtures of isomers PPEs that contain only o and p substituted rings have the highest melting points Table 2 physical properties of polyphenyl ethers Polyphenyl ether Appearance Pour point C F Thermal stability C F Viscosity cSt at 100 F 38 C Viscosity cSt at 210 F 99 C 6 ring 6P5E Clear liquid 10 50 447 836 2000 255 ring 5P4E Clear liquid 4 5 40 453 847 360 134 ring 4P3E Clear liquid 12 10 441 825 70 63 and 4 ring oxythio Hazy liquid 29 20 367 693 25 43 ring 3P2E Solid 427 800 12 32 ring 2P1E Solid 316 gt 600 2 4 1 6Thermo oxidative stability Edit PPEs have excellent high temperature properties and good oxidation stability With respect to volatilities p derivatives have the lowest volatilities and the o derivatives have the highest volatilities The opposite is true for flash points and fire points Spontaneous ignition temperatures of polyphenyl ethers lie between 550 and 595 C 1 022 and 1 103 F alkyl substitution reduces this value by 50 C 122 F PPEs are compatible with most metals and elastomers that are commonly used in high temperature applications They typically swell common seal materials 4 Oxidation stability of un substituted PPEs is quite good partly because they lack easily oxidizable carbon hydrogen bonds Thermal decomposition temperature as measured by the isoteniscope procedure is between 440 and 465 C 824 and 869 F Radiation stability Edit Ionizing radiation affects all organic compounds causing a change in their properties because radiation disrupts covalent bonds that are most prevalent in organic compounds One result of ionization is that the organic molecules disproportionate to form smaller hydrocarbon molecules as well as larger hydrocarbons molecules This is reflected by increased evaporation loss lowering of the flash and fire points and increased viscosity Other chemical reactions caused by radiation include oxidation and isomerization The former leads to increased acidity corrosivity and coke formation the latter causes a change in viscosity and volatility PPEs have extremely high radiation resistance Of all classes of synthetic lubricants with the possible exception of perfluoropolyethers the polyphenyl ethers are the most radiation resistant 5 Excellent radiation stability of PPEs can be ascribed to the limited number of ionizable carbon carbon and carbon hydrogen bonds In one study the performance of PPE under the influence of 1 1011 ergs gram of radiation at 99 C 210 F was compared with synthetic ester synthetic hydrocarbon and silicone fluids 6 PPE showed a viscosity increase of only 35 while all other fluids showed a viscosity increase of 1700 and gelled Further tests have shown PPEs to be resistant to gamma and associated neutron radiation dosages of 1 1010 erg g at temperatures up to 315 C 599 F Surface tension Edit PPEs have high surface tension hence these fluids have a lower tendency to wet metal surfaces The surface tension of the commercially available 5R4E is 49 9 dynes cm one of the highest in pure organic liquids 7 This property is useful in applications where migration of the lubricant into the surrounding environment must be avoided Applications EditWhile originally PPEs were developed for use in extreme environments that were experienced in aerospace applications they are now used in other applications requiring low volatility and excellent thermo oxidative and ionizing radiation stability Such applications include use as diffusion pump fluids high vacuum fluids and in formulating jet engine lubricants high temperature hydraulic lubricants and greases and heat transfer fluids In addition because of excellent optical properties these fluids have found use in optical devices Ultra high vacuum fluids Edit Vacuum pumps are devices that remove gases from an enclosed space to greatly reduce pressure Oil diffusion pumps in combination with a fore pump are amongst the most popular Diffusion pumps use a high boiling liquid of low vapor pressure to create a high speed jet that strikes the gaseous molecules in the system to be evacuated and direct them into space that is being evacuated by the fore pump A good diffusion fluid must therefore reflect low vapor pressure high flash point high thermal and oxidative stability and chemical resistance If the diffusion pump is operating in the proximity of ionizing radiation source good radiation stability is also desired Data presented in Table 3 demonstrates polyphenyl ether to be superior to other fluids that are commonly used in diffusion pumps 8 PPEs help achieve the highest vacuum of 4 10 10 torr at 25 C Such high vacuums are necessary in equipment such as electron microscopes mass spectrometers and that used for various surface physics studies Vacuum pumps are also used in the production of electric lamps vacuum tubes and cathode ray tubes CRTs semiconductor processing and vacuum engineering Table 3 diffusion fluid property comparison Fluid property Polyphenyl ether SANTOVAC 5 Silicone Dow Corning Hydrocarbon oil ApiezonVapor pressure Torr at 25 C 4 10 10 2 10 8 5 10 6Molecular weight 446 484 420Density at 25 C 1 20 1 07 0 87Flash point C 288 221 243Boiling point at 1 3 mbar C 295 223 220Viscosity cSt at 25 C 1000 40 135Viscosity cSt at 100 C 12 0 4 3 7 0Surface tension dynes cm 49 9 30 5 30 5Refractive index at 25 C 589 nm 1 67 1 56 1 48Thermal stability Excellent Good PoorOxidation resistance Excellent Excellent Poor fairChemical resistance Excellent Good PoorRadiation resistance Excellent Good FairElectronic connector lubricants Edit 5R4E PPE has a surface tension of 49 9 dynes cm which is amongst the highest in pure organic liquids Because of this this PPE and the other PPEs do not effectively wet metal surfaces This property is useful when migration of a lubricant from one part of the equipment to another part must be avoided such as in certain electronic devices A thin film of polyphenyl ether on a surface is not a thin contiguous film as one would envision but rather comprises tiny droplets This PPE property tends to keep the film stationary or at least to cause it to remain in the area where the lubrication is needed rather than migrating away by spreading and forming a new surface As a result contamination of other components and equipment which do not require a lubricant is avoided The high surface tension of PPEs therefore makes them useful in lubricating electronic contacts Polyphenyl ether lubricants have a 30 year history of commercial service for connectors with precious and base metal contacts in telecom automotive aerospace instrumentation and general purpose applications 9 10 In addition to maintaining the current flow and providing long term lubrication PPEs offer protection to connectors against aggressive acidic and oxidative environments By providing a protective surface film polyphenyl ethers not only protect connectors against corrosion but also against vibration related wear and abrasion that leads to fretting wear The devices that benefit from the specialized properties of PPEs include cell phones printers and a variety of other electronic appliances The protection lasts for decades or for the life of the equipment Optics Edit Polyphenyl ethers PPEs possess good optical clarity a high refractive index and other beneficial optical properties Because of these PPEs have the ability to meet the rigorous performance demands of signal processing in advanced photonics systems Optical clarity of PPEs resembles that of the other optical polymers that is they have refractive indices of between 1 5 and 1 7 and provide good propagation of light between approximately 400 nm and 1700 nm Close refractive index RI matching between materials is important for proper propagation of light through them Because of the ease of RI matching PPEs are used in many optical devices as optical fluids Extreme resistance to ionizing radiation gives PPEs an added advantage in the manufacture of solar cells and solid state UV blue emitters and telecommunication equipment made from high index glasses and semiconductors High temperature and radiation resistant lubricants Edit PPEs being of excellent thermo oxidative stability and radiation resistance have found extensive use in high temperature applications that also require radiation resistance In addition PPEs demonstrate better wear control and load carrying ability than mineral oils especially when used in bearings PPEs were developed for use in jet engines that involved high speed related frictional temperatures of as high as 320 C 608 F While the use of PPEs in lubricating jet engines has somewhat subsided due to their higher cost they are still used in some aerospace applications PPEs are also used as base fluids for radiation resistant greases used in nuclear power plant mechanisms PPEs and their derivatives have also found use as vapor phase lubricants in gas turbines and custom bearings and wherever extreme environmental conditions exist Vapor phase lubrication is achieved by heating the liquid lubricant above its boiling point The resultant vapors are then transported to the hot bearing surface If the temperatures of the bearing surface are kept below the lubricant s boiling point the vapors re condense to provide liquid lubrication Polyphenyl ether technology can also provide superior fire safety and fatigue life depending on the specific bearing design In this application PPEs have the advantage of providing lubrication both as a liquid at low temperatures and as a vapor at temperatures above 315 C 599 F Due to the low volatility and excellent high temperature thermo oxidative stability PPEs have also found use as a lubricant for chains used in and around kilns metal fabrication plants and glass molding and manufacturing equipment In these high temperature applications PPEs do not form any sludge and hard deposits The low soft carbon residue that is left behind is removed easily by wiping PPEs low volatility low flammability and good thermodynamic properties make them ideally suited for use as heat transfer fluids and in heat sink applications as well 11 Polyphenylene oxides PPOs EditMain article Poly p phenylene oxide These polymers are made through oxidative coupling of substituted phenol in the presence of oxygen and copper and amine containing catalysts such as cuprous bromide and pyridine See Figure 2 for the PPO structure PPO polymers can be classified as plastic resins They and their composites with polystyrene glass and nylon are used as high strength moisture resistant engineering plastics in a number of industries including computer telecommunication and automotive parts PPOs are marketed by SABIC Innovative Plastics under the trademarked name of Noryl 12 References Edit The Ullmann Ether Condensation by A A Moroz and Mark S Shvartsberg 1974 Russ Chem Rev 43 8 679 689 SANTOLUBES LLC Product Brochure Joaquim M Polyphenyl Ether Lubricants Synthetic Lubricants and High performance Functional Fluids R L Rudnick and R L Shubkin Eds p 239 Marcel Dekker Inc NY 1999 Synthetic Lubricants Chapter 6 pp 96 153 Lubricants and Related Products Synthesis Properties Applications International Standards by Dieter Klamann Verlag Chemie Gmbh publisher 1984 Bolt R O Radiation Effects on Lubricants CRC Handbook of Lubrication Vol I Theory and Practice of Tribology Applications and Maintenance pp 3 44 Richard E Booser Editor CRC Press Boca Raton 1983 Carroll J G and Bolt R O Radiation Effects on Organic Materials Bolt R O and Carroll J G Eds Academic Press New York 1963 Joaquim M E and J F Herber Lubrication of Electronic Connectors and Equipment in Radiation Environments http www chemassociates com products findett PPEs Radiation2 pdf The Surface Tension of Pure Liquid Compounds Joseph J Jasper J Phys Chem Ref Data Vol 1 No 4 1972 https www nist gov srd PDFfiles jpcrd13 pdf Inside a Vacuum Diffusion Pump by Manuel E Joaquim and Bill Foley http www xtronix ch pdf Diffusion 20Pump pdf Using Lubricants to Avoid Failures in Medical Electronic Connectors by Sibtain Hamid in Medical Electronics Manufacturing Spring 2004 and SANTOLUBES Brochure on Stationary lubricants prevent connector failures SANTOLUBES Brochure on Stationary lubricants prevent connector failures Hamid S and Burian S A Polyphenyl Ether Lubricants published in Synthetics Mineral Oils and Bio based Lubricants Chemistry and Technology Leslie R Rudnick Editor pp 175 199 Taylor and Francis Publisher 2002grc087 High Heat PPO 13C and 31P NMR Methods for Characterizing End Groups and Chain Structures in Poly 2 6 dimethyl 1 4 phenylene oxide Poly 2 3 6 trimethyl 1 4 phenylene oxide Copolymers permanent dead link Retrieved from https en wikipedia org w index php title Polyphenyl ether amp oldid 1079453575, wikipedia, wiki, book, books, library,

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