Research Progress of Low Dielectric Benzoxazine Resin
Vol 1, Issue 1, 2018
VIEWS - 2064 (Abstract) 72 (PDF)
Abstract
Benzoxazine resin, a new type of phenolic resin, has many advantages, such as a strong molecular design, no small molecular release in the curing process, excellent thermal stability and mechanical properties, and a high residual carbon ratio. Thus, it is important for electronic communication industry matrix material. To meet the needs of high-frequency and high-speed communication technology for low-dielectric polymer resin, the low-dielectric modification of benzoxazine resin is of great significance to the high frequency and high-speed propagation of the signal, which attracts a wide range of materials researchers’ attention. In this paper, we review a series of studies on the low dielectric modification of benzoxazine resin in recent years, including the synthesis of new monomers, inorganic - organic hybridization, copolymerization with other resins, and low molecular weight benzoxazine resin research trends.
Keywords
Full Text:
PDFReferences
1. Rimdusit S, Ishida H. Development of new class of electronic Packaging materials based on ternary systems of benzoxazine, epoxy, and phenolic resins. Polymer 2000; 22: 7941-7949.
2. Rimdusit S, Ishida H. Gelation study of high processability and High reliability ternary systems based on benzoxazine, epoxy and Phenolic resins for application electronic packaging materials. Rheologica Acta 2000; 41: 1-9.
3. Ogura I. Handbook of low and high dielectric constant materials and their applications. Academic Press, 1999. 213-219.
4. Hamerton I, Howlin B J, Mitchelll A L, et al. Systematic Examination of thermal, mechanical and dielectrical properties of Aromatic polybenzoxazines. Reactive and Functional Polymers 2012; 72: 736-744.
5. Sua YC, Chen WC, Ou KL, et al. Study of the morphologies and dielectric constants of nanoporous materials derived from benzoxazine-terminated poly (3 caprolactone)/polybenzoxazine stocks. Polymer 2005; 46: 3758-3766.
6. Kumar RS, Padmanathanbc N, Alagar M. Design of hydrophobic Polydimethylsiloxane and polybenzoxazine hybrids for interlayer Low k dielectrics. New Journal of Chemistry 2015; 39: 3995-4008.
7. Zhang K, Zhuang QX, Liu XY, et al. Preparation and properties of novel low dielectric constant benzoxazole-based polybenzoxazine. Polymer Chemistry 2012; 50: 5115-5123.
8. Zhang K, Zhuang QX, Cai RL, et al. Synthesis and Copolymerization of benzoxazines with low-solar constants and High thermal stability. RSC Advances 2013; 3: 5261-5270.
9. Herrera PV, Doyama K, Abe H, et al. Synthesis and Characterization of highly fluorinated polymer with the benzoxazine moiety in the main chain. Macromolecules 2008; 41: 9704-9714.
10. Herrera PV, Ishida H. Synthesis and characterization of highly Fluorinated diamines and benzoxazines derived therefrom. Journal of Fluorine Chemistry 2009; 130: 573-580.
11. Parveen AS, Thirukumaran P, Sarojadevi M. Low dielectric Materials from fluorinated polybenzoxazines. Polymers for Advanced Technologies 2014; 25: 1538-1545.
12. Su YC, Chang FC. Synthesis and characterization of fluorinated polybenzoxazine material with low dielectric constant. Polymer 2003; 44: 7989-7996.
13. Shieh J Y, Lin C Y, Huang C L, et al. Synthesis and characterization of novel dihydrobenzoxazineous. Journal of Applied Polymer Science 2006; 101: 342-347.
14. Hwang HJ, Lin CY, Wang CS Flame retardancy and dielectric properties of dicyclopentadiene-based benzoxazine cured with a phosphorus-containing phenolic resin. Journal of Applied Polymer Science 2008; 110: 2413-2423.
15. Liu Z, Yuan C, Huang F. Benzoxazine blend resin and its glass fiber cloth preparation and properties of reinforced composites. Polymer Materials Science and Engineering 2013; 30(4): 13-21.
16. Xiao L, Yu R, Zhao W, et al. Benzoxazine resin based aromatic sulfonamide fiber and glass study on the properties of fiber composites. FRP/Composites 2010; 6: 21-24.
17. Wang YQ, Kou KC, Zhuo LH, et al. Preparation of Boz/glass fibers/cyanate ester resins Lamin composites. Polymer Composites 2015; 1-5.
18. Li GZ, Wang LC, Ni HL, et al. Polyhedral oligomeric silsesquioxane (POSS) polymers and copolymers: A review. Journal of Inorganic and Organometallic Polymers 2001; 3: 123-154.
19. Tseng MC, Liu YL. Preparation, morphology, and ultra-low Natural constants of benzoxazine-based polymers/polyhedral oligomeric silsesquioxane (POSS) nanocomposites. Polymer 2010; 51: 5567-5575.
20. Vengatesan MR, Devaraju S, Kumar AA, et al. Studies on thermal and dielectric properties of octa (maleimido phenyl) silsesquioxane (OMPS) Polybenzoxazine (PBZ) hybrid nanocomposites. High Performance Polymers 2011; 23: 441-456.
21. Vengatesan M R, Devaraju S, Dinakaran K, et al. Studies on Thermal and dielectric properties of organo clay and octakis (dim ethylsiloxypropylglycidylether) Silsesquioxane filled polybenzoxazine Hybrid nanocomposites. Polymer Composites 2011; 11: 1701-1711.
22. Kumar RS, Alagar M. Dielectric and thermal behaviors of POSS terms polyurethane based polybenzoxazine nanocomposites. RSC Advances 2015; 42: 33008-33015.
23. Sethuraman K, Vengatesan MR, Lakshmikandhan T, et al. Thermal and dielectric properties of ‘thiolene’ photocured hybrid Composite materials from allylterminated benzoxazine and SH-POSS. High Performance Polymers 2015; 27: 1-12.
24. Thirukumaran P, Parveen AS, Sarojadevi M. Synthesis of Eugenol-based polybenzoxazine-poss nanocomposites for low dielectric applications. Polymer Composites 2015; 11: 1973-1982.
25. Chandramohan A, Chozhan CK, Alagar M. Polysilsesquioxanere inforced phosphorous containing bis (4-maleimidophenyl) benzoxazine hybrid nanocomposites. High Performance Polymers 2013; 25: 744-758.
26. Liu HC, Su WC, Liu YL. Self-assembled benzoxazine-bridged polysilsesquioxanes exhibiting ultralow-host constants and yellow-light photoluminescent emission. Journal of Materials Chemistry 2011; 21: 7182-7187.
27. Kumar R S, Ariraman M, Alagar M. Design of lamellar structured POSS / BPZ polybenzoxazine nanocomposites as the novel class of ultra low k dielectric material. RSC Advances 2014, 4: 19127-19136.
28. Zhang K, Zhuang QZ, Liu XY, et al. A new benzoxazine Containing benzoxazole-functionalized polyhedral oligomeric silsesquioxane and the corresponding polybenzoxazine nanocomposites. Macromolecules 2013; 46: 2696-2704.
29. Kumar R S, Ariraman M, Alagar M. Studies on MCM-41/PDMS based hybrid polybenzoxazine nanocomposites for interlayer low k dielectrics. RSC Advances 2015; 5: 40798-40806.
30. Vengatesan MR, Devaraju S, Dinakaran K, et al. SBA-15 filled Polybenzoxazine nanocomposites for low-k dielectric applications. Journal of Materials Chemistry 2012; 22: 7559-7566.
31. Selvaraj V, Jayanthi KP, Lakshmikandhanc T, et al. Development of a polybenzoxazine/TSBA-15composite from the Renewable resource cardanol for low-k applications. RSC Advances 2015, 5: 48898-48907.
32. Geim A K. Graphene: Status and prospects. Science 2009; 324: 1530-1534.
33. Stankovich S, Dikin DA, Dommett GHB, et al. Graphenebased composite materials. Nature 2006; 442: 282-286.
34. Novoselov KS, Falko VI, Colombo L, et al. A roadmap for graphene. Nature 2012; 490: 192-200.
35. Zeng M, Wang J, Li RR, et al. The curing behavior and thermal property of graphene oxide/benzoxazine nanocomposites. Polymer 2013; 54: 3107-3116.
36. Xu QY, Zeng M, Feng ZJ, et al. Understanding the effects of carboxylated groups of functionalized graphene oxide on the curing behavior and intermolecular interactions of benzoxazine nanocomposites. RSC Advances 2016; 6: 31484-31496.
37. Kumar RS, Ariraman M, Alagar M. Studies on dielectric properties of GO reinforced bisphenol-Z polybenzoxazine hybrids. RSC Advances 2015; 5: 23787-23797.
38. Lin CH, Huang SJ, Wang PJ, et al. Miscibility, microstructure, and thermal and dielectric properties of reactive blends of dicyanate ester and diamine-based benzoxazine. Macromolecules 2012; 45: 7461-7466.
39. Yan HX, Li TT, Feng S, et al. Mechanical and dielectric properties of blends of dicyanate ester and bisphenol a-based benzoxazine. High Performance Polymers 2014; 26: 618-625.
40. Li X, Luo X, Xia Y, et al. Benzoxazine/cyanate ester copolymer and performance. Polymer Materials Science and Engineering 2015; 31(8): 96-101.
41. Lin CH, Huang CM, Wong TI, et al. High-Tg and lowdielectric epoxy hotosets based on a propargyl ether-containing phosphinated benzoxazine. Polymer Chemistry 2014; 52: 1359-1367.
42. Krishnadevi K, Selvaraj V. Development of halogen-free flame retardant phosphazene and rice husk ash incorporated benzoxazine blended epoxy composites for microelectronic applications. New Journal of Chemistry 2015; 39: 6555-6567.
43. Krishnadevi K, Grace AN, Alagar M, et al. Development of hexa (aminophenyl) cyclotriphosphazene-modified cyanate ester composites for high temperature applications. High Performance Polymers 2014; 26: 89-96.
44. Krishnadevi K, Selvaraj V, Prasanna D. Thermal, mechanical and antibacterial properties of cyclophosphazined incorporated benzoxazine blended bismaleimide composites. RSC Advances 2015; 5: 913-921.
45. Wang CF, Su YC, Kuo SW, et al. Low-surface-free-energy Materials based on polybenzoxazines. Angewandte Chemie International Edition 2006; 45: 2248-2251.
46. Li XD, Xia YQ, Xu WL, et al. The curing procedure for a Benzoxazine-cyanate-epoxy system and the properties of the terpolymer. Polymer Chemistry 2012; 3: 1629-1633.
47. Jamshidi S, Yeganeh H, Ataei S M. Preparation and properties of one-pack polybenzoxazine-modified polyurethanes with improved thermal stability and electrical insulating properties. Polymer International 2011; 60: 126-135.
48. Gaina C, Ursache O, Gaina V, et al. Poly (urethane-benzoxazine)s. Journal of Polymer Research 2014; 21: 586-596.
49. Wang YQ, Kou KC, Zhuo LH, et al. Thermal, mechanical and dielectric properties of BMI modified by the bis allyl benzoxazine. Journal of Polymer Research 2015, 22: 51-59.
50. Wang YQ, Kou KC, Zhao W, et al. The effect of functionalized benzoxazine with allyl groups on the dielectric, mechanical and thermal properties of BMI/BADCy composites. RSC Advances 2015; 5: 99313-99321.
51. Wang YQ, Kou KC, Wu GL, et al. The effect of bis allyl benzoxazine on the thermal, mechanical and dielectric properties of bismaleimide-cyanate blend polymers. RSC Advances 2015; 5: 58821-58831.
52. Zhang CX, Luo XX, Zhu RQ, et al. Thermal and dielectric properties of epoxy/DDS/CTBN adhesive modified by cardanol based benzoxazine. Journal of Adhesion Science and Technology 2015; 29: 767-777.
DOI: https://doi.org/10.24294/jpse.v1i1.234
Refbacks
- There are currently no refbacks.
Copyright (c) 2018 Qiuping Yin*, Zhenbo Zhang, Hongyu Liu
License URL: https://creativecommons.org/licenses/by-nc/4.0/
This site is licensed under a Creative Commons Attribution 4.0 International License.