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Non-halogenated Flame Retardant Handbook


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      Tests in pure water, river water, and activated sludge showed that commercial triaryl phosphates, alkyl diphenyl phosphates and aromatic bisphosphates undergo reasonably facile conversion to inorganic phosphates by hydrolysis and biodegradation [434–437]. Due to their low water solubility triaryl phosphates and in particularly TPP are rapidly absorbed into aquatic sediments [438]. Phosphate-cleaving enzymes are widespread in nature. Trialkyl phosphates are more resistant to hydrolysis [439], but they undergo easier photooxidation compared to aromatic phosphates [440]. However, the oxidation can be significantly slowed down if the aliphatic phosphates are absorbed on inert particles [441]. Phosphonates can undergo biodegradation of the P-C bond by certain microorganisms [442, 444]. Proper incineration at 600 - 800°C of flame-retardant plastics or thermosets containing organophosphorus flame retardants leads to quantitative conversion into phosphorus oxides or inorganic phosphates [445, 446], but flame retardants and byproducts of partial decomposition can be emitted in informal open flame recycling [447, 448]. The resultant inorganic phosphates from flame retardants would be orders of magnitude lower than phosphates from agricultural and municipal sources, and thus an inconsequential contributor to algae proliferation. Therefore, it is reasonable to believe that organophosphorus flame retardants and plasticizers cannot be persistent organic pollutants (POP).

      A few recent reviews summarized the observed [465, 466] and computed [467] effects of phosphorus flame retardants on human health and the environment. The most concentrated compounds in every study were tris(1-chloro-2-propyl) phosphate (TCPP) and tris(2,3-dichloropryl) phosphate (TDCP) which are chlorinated phosphates and therefore are out of the scope of this chapter. The most common halogen free contaminants are tris(2-butoxyethyl) phosphate and tributyl phosphate which are mostly used as non-flame-retardant plasticizers or leveling agents in floor wax. These phosphates were also found in human urine along with triphenyl phosphate. Triphenyl phosphate is a common impurity in bisphosphates used in electronic and other consumer products [468], but it is also commonly used in nail lacquer. Finding all of these compounds in the environment especially indoors is not surprising because they are relatively volatile [469] and more mobile than most organohalogen FRs [470], whereas heavier and less mobile bisphosphates are very rarely detected in the environment. In general, aliphatic phosphates hydrolyze more slowly than aromatic phosphates and in addition to this TCPP and TDCP are sterically hindered which also slows down their hydrolysis and eventually mineralization [471].

      The growth of phosphorus-based flame retardants as a class is often attributed to the replacement of halogenated flame retardants which is disputable. Although there is a general market trend to halogen-free flame retardants mostly dictated by original equipment manufacturers (OEMs) for their “green image”, there are many areas where halogenated flame retardants cannot be replaced due to technical reasons. Since phosphorus flame retardants possess gas phase and condensed phase modes of flame-retardant action with the gas phase being mostly underutilized there are good prospects for the development of new FRs with mostly gas phase activity or the discovery of new synergistic combinations. Because phosphorus FRs are selectively active in only a handful of highly charrable and heteroatomic polymers there is a need for the development of more universal flame retardants. This research can progress either by development of new highly efficient and hydrolytically stable intumescent systems or of highly efficient gas phase active FRs or of a combination of both. Plastics containing phosphorus FRs are poorly recyclable and so there is interest in more hydrolytically and thermally stable phosphorus flame retardants that are favorable to recycling.