Advanced Flame‐Retardant Methods for Polymeric Materials

Most organic polymeric materials have high flammability, for which the large amounts of smoke, toxic gases, heat, and melt drips produced during their burning cause immeasurable damages to human life and property every year. Despite some desirable results having been achieved by conventional flame‐r...

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Published inAdvanced materials (Weinheim) Vol. 34; no. 46; pp. e2107905 - n/a
Main Authors Liu, Bo‐Wen, Zhao, Hai‐Bo, Wang, Yu‐Zhong
Format Journal Article
LanguageEnglish
Published Germany Wiley Subscription Services, Inc 17.11.2022
Subjects
Biomimetics
bulk additives
bulk‐copolymerization
Char formation
Copolymerization
flame‐retardant methods
Flammability
Materials science
polymeric materials
Smoke
Surface treatment
bulk-copolymerization
flame-retardant methods
surface treatment
bulk additives
polymeric materials
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Abstract Most organic polymeric materials have high flammability, for which the large amounts of smoke, toxic gases, heat, and melt drips produced during their burning cause immeasurable damages to human life and property every year. Despite some desirable results having been achieved by conventional flame‐retardant methods, their application is encountering more and more difficulties with the ever‐increasing high flame‐retardant requirements such as high flame‐retardant efficiency, great persistence, low release of heat, smoke, and toxic gases, and more importantly not deteriorating or even enhancing the overall properties of polymers. Under such condition, some advanced flame‐retardant methods have been developed in the past years based on “all‐in‐one” intumescence, nanotechnology, in situ reinforcement, intrinsic char formation, plasma treatment, biomimetic coatings, etc., which have provided potential solutions to the dilemma of conventional flame‐retardant methods. This review briefly outlines the development, application, and problems of conventional flame‐retardant methods, including bulk‐additive, bulk‐copolymerization, and surface treatment, and focuses on the raise, development, and potential application of advanced flame‐retardant methods. The future development of flame‐retardant methods is further discussed. Flame‐retardant methods for polymeric materials are reviewed with particular focus on advanced flame‐retardant methods developed in recent years. Both the advantages and drawbacks of these methods are discussed, and prospects for the future development of flame‐retardant methods are presented. It is hoped that this review will guide the development of flame‐retardant polymeric materials.
AbstractList Most organic polymeric materials have high flammability, for which the large amounts of smoke, toxic gases, heat, and melt drips produced during their burning cause immeasurable damages to human life and property every year. Despite some desirable results having been achieved by conventional flame-retardant methods, their application is encountering more and more difficulties with the ever-increasing high flame-retardant requirements such as high flame-retardant efficiency, great persistence, low release of heat, smoke, and toxic gases, and more importantly not deteriorating or even enhancing the overall properties of polymers. Under such condition, some advanced flame-retardant methods have been developed in the past years based on "all-in-one" intumescence, nanotechnology, in situ reinforcement, intrinsic char formation, plasma treatment, biomimetic coatings, etc., which have provided potential solutions to the dilemma of conventional flame-retardant methods. This review briefly outlines the development, application, and problems of conventional flame-retardant methods, including bulk-additive, bulk-copolymerization, and surface treatment, and focuses on the raise, development, and potential application of advanced flame-retardant methods. The future development of flame-retardant methods is further discussed.Most organic polymeric materials have high flammability, for which the large amounts of smoke, toxic gases, heat, and melt drips produced during their burning cause immeasurable damages to human life and property every year. Despite some desirable results having been achieved by conventional flame-retardant methods, their application is encountering more and more difficulties with the ever-increasing high flame-retardant requirements such as high flame-retardant efficiency, great persistence, low release of heat, smoke, and toxic gases, and more importantly not deteriorating or even enhancing the overall properties of polymers. Under such condition, some advanced flame-retardant methods have been developed in the past years based on "all-in-one" intumescence, nanotechnology, in situ reinforcement, intrinsic char formation, plasma treatment, biomimetic coatings, etc., which have provided potential solutions to the dilemma of conventional flame-retardant methods. This review briefly outlines the development, application, and problems of conventional flame-retardant methods, including bulk-additive, bulk-copolymerization, and surface treatment, and focuses on the raise, development, and potential application of advanced flame-retardant methods. The future development of flame-retardant methods is further discussed.
Most organic polymeric materials have high flammability, for which the large amounts of smoke, toxic gases, heat, and melt drips produced during their burning cause immeasurable damages to human life and property every year. Despite some desirable results having been achieved by conventional flame-retardant methods, their application is encountering more and more difficulties with the ever-increasing high flame-retardant requirements such as high flame-retardant efficiency, great persistence, low release of heat, smoke, and toxic gases, and more importantly not deteriorating or even enhancing the overall properties of polymers. Under such condition, some advanced flame-retardant methods have been developed in the past years based on "all-in-one" intumescence, nanotechnology, in situ reinforcement, intrinsic char formation, plasma treatment, biomimetic coatings, etc., which have provided potential solutions to the dilemma of conventional flame-retardant methods. This review briefly outlines the development, application, and problems of conventional flame-retardant methods, including bulk-additive, bulk-copolymerization, and surface treatment, and focuses on the raise, development, and potential application of advanced flame-retardant methods. The future development of flame-retardant methods is further discussed.
Most organic polymeric materials have high flammability, for which the large amounts of smoke, toxic gases, heat, and melt drips produced during their burning cause immeasurable damages to human life and property every year. Despite some desirable results having been achieved by conventional flame‐retardant methods, their application is encountering more and more difficulties with the ever‐increasing high flame‐retardant requirements such as high flame‐retardant efficiency, great persistence, low release of heat, smoke, and toxic gases, and more importantly not deteriorating or even enhancing the overall properties of polymers. Under such condition, some advanced flame‐retardant methods have been developed in the past years based on “all‐in‐one” intumescence, nanotechnology, in situ reinforcement, intrinsic char formation, plasma treatment, biomimetic coatings, etc., which have provided potential solutions to the dilemma of conventional flame‐retardant methods. This review briefly outlines the development, application, and problems of conventional flame‐retardant methods, including bulk‐additive, bulk‐copolymerization, and surface treatment, and focuses on the raise, development, and potential application of advanced flame‐retardant methods. The future development of flame‐retardant methods is further discussed. Flame‐retardant methods for polymeric materials are reviewed with particular focus on advanced flame‐retardant methods developed in recent years. Both the advantages and drawbacks of these methods are discussed, and prospects for the future development of flame‐retardant methods are presented. It is hoped that this review will guide the development of flame‐retardant polymeric materials.
Author Zhao, Hai‐Bo
Wang, Yu‐Zhong
Liu, Bo‐Wen
Author_xml – sequence: 1
  givenname: Bo‐Wen
  orcidid: 0000-0002-1355-7495
  surname: Liu
  fullname: Liu, Bo‐Wen
  organization: Sichuan University
– sequence: 2
  givenname: Hai‐Bo
  orcidid: 0000-0002-5455-2965
  surname: Zhao
  fullname: Zhao, Hai‐Bo
  organization: Sichuan University
– sequence: 3
  givenname: Yu‐Zhong
  orcidid: 0000-0001-7535-7635
  surname: Wang
  fullname: Wang, Yu‐Zhong
  email: yzwang@scu.edu.cn
  organization: Sichuan University
BackLink https://www.ncbi.nlm.nih.gov/pubmed/34837231$$D View this record in MEDLINE/PubMed
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10.1016/j.ijbiomac.2019.11.220
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flame-retardant methods
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bulk additives
polymeric materials
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e_1_2_8_159_1
e_1_2_8_57_1
e_1_2_8_211_1
e_1_2_8_234_1
e_1_2_8_257_1
e_1_2_8_11_1
e_1_2_8_34_1
e_1_2_8_11_2
e_1_2_8_101_1
e_1_2_8_124_1
e_1_2_8_147_1
e_1_2_8_67_2
e_1_2_8_67_3
e_1_2_8_200_1
e_1_2_8_223_1
e_1_2_8_246_1
e_1_2_8_269_1
e_1_2_8_6_1
e_1_2_8_67_1
e_1_2_8_114_3
e_1_2_8_44_1
e_1_2_8_137_1
e_1_2_8_114_2
e_1_2_8_114_1
e_1_2_8_79_8
e_1_2_8_79_7
e_1_2_8_79_6
e_1_2_8_79_5
e_1_2_8_10_4
e_1_2_8_79_4
e_1_2_8_79_3
e_1_2_8_79_2
e_1_2_8_79_1
e_1_2_8_212_1
e_1_2_8_235_1
e_1_2_8_258_1
e_1_2_8_79_9
e_1_2_8_10_1
e_1_2_8_56_1
e_1_2_8_10_2
e_1_2_8_10_3
e_1_2_8_33_1
e_1_2_8_102_1
e_1_2_8_148_1
e_1_2_8_125_2
e_1_2_8_125_1
e_1_2_8_24_1
e_1_2_8_47_1
e_1_2_8_224_1
e_1_2_8_201_1
e_1_2_8_247_1
e_1_2_8_115_2
e_1_2_8_138_1
e_1_2_8_115_1
e_1_2_8_13_1
e_1_2_8_36_1
e_1_2_8_59_1
e_1_2_8_59_2
e_1_2_8_190_1
e_1_2_8_213_1
e_1_2_8_259_1
Jensen S. (e_1_2_8_21_1) 1966; 15
e_1_2_8_236_1
e_1_2_8_149_1
e_1_2_8_103_1
e_1_2_8_126_1
e_1_2_8_23_6
e_1_2_8_23_7
e_1_2_8_23_8
e_1_2_8_23_2
e_1_2_8_46_2
e_1_2_8_69_2
e_1_2_8_23_3
e_1_2_8_46_1
e_1_2_8_69_3
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e_1_2_8_69_1
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Rowland I. D. (e_1_2_8_189_1) 2001
e_1_2_8_4_1
e_1_2_8_116_2
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e_1_2_8_192_3
e_1_2_8_23_1
e_1_2_8_139_1
e_1_2_8_58_2
e_1_2_8_35_1
e_1_2_8_58_1
e_1_2_8_191_1
e_1_2_8_214_1
e_1_2_8_237_1
e_1_2_8_237_2
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e_1_2_8_237_4
e_1_2_8_237_5
e_1_2_8_127_1
e_1_2_8_12_1
e_1_2_8_104_1
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Snippet Most organic polymeric materials have high flammability, for which the large amounts of smoke, toxic gases, heat, and melt drips produced during their burning...
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SubjectTerms Biomimetics
bulk additives
bulk‐copolymerization
Char formation
Copolymerization
flame‐retardant methods
Flammability
Materials science
polymeric materials
Smoke
Surface treatment
Title Advanced Flame‐Retardant Methods for Polymeric Materials
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fadma.202107905
https://www.ncbi.nlm.nih.gov/pubmed/34837231
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Volume 34
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