Date published: 2025-10-16
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Tetrabenzylthiuram disulfide (CAS 10591-85-2) - chemical structure image
Molecular structure of Tetrabenzylthiuram disulfide, CAS Number: 10591-85-2
Tetrabenzylthiuram disulfide (CAS 10591-85-2) - chemical structure image
Molecular structure of Tetrabenzylthiuram disulfide, CAS Number: 10591-85-2
Molecular structure of Tetrabenzylthiuram disulfide, CAS Number: 10591-85-2

Tetrabenzylthiuram disulfide (CAS 10591-85-2)

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Alternate Names:
Dibenzylcarbamothioylsulfanyl N,N-dibenzylcarbamodithioate
CAS Number:
10591-85-2
Molecular Weight:
544.82
Molecular Formula:
C30H28N2S4
For Research Use Only. Not Intended for Diagnostic or Therapeutic Use.
* Refer to Certificate of Analysis for lot specific data.

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Tetrabenzylthiuram disulfide is predominantly used in research related to its role as a vulcanization accelerator in the rubber industry. This compound is studied for its efficiency in enhancing the cross-linking characteristics of rubber, which improves the mechanical properties such as elasticity, resilience, and durability of rubber products. Researchers also explore the kinetics of vulcanization reactions facilitated by Tetrabenzylthiuram disulfide to optimize production processes and material properties. Additionally, it is used in studies investigating its potential as a fungicide due to its biocidal properties. Tetrabenzylthiuram disulfide′s role in these applications makes it a subject of interest in materials science and agricultural research, aiming to develop more effective industrial and protective treatments.


Tetrabenzylthiuram disulfide (CAS 10591-85-2) References

  1. Role of Interface Structure and Chain Dynamics on the Diverging Glass Transition Behavior of SSBR-SiO2-PIL Elastomers.  |  Sattar, MA. and Patnaik, A. 2020. ACS Omega. 5: 21191-21202. PMID: 32875255
  2. EFFECT OF SULFUR TO ACCELERATOR RATIO ON CROSSLINK STRUCTURE, REVERSION, AND STRENGTH IN NATURAL RUBBER  |  Kanoktip Boonkerd; Chudej Deeprasertkul; Kanyarat Boonsomwong. (2016). Rubber Chemistry and Technology. 89 (3):: 450–464.
  3. Thermal dissociation of thiuram disulfides in solution; an electron spin resonance and kinetic study  |  PJ Nichols and MW Grant. 1983. Australian Journal of Chemistry. 36(7): 1379 - 1386.
  4. Studies on the effect of thiuram disulfide on NR vulcanization accelerated by thiazole-based accelerator systems  |  Subhas Chandra Debnath, Dipak Kumar Basu. May 1996. Journal of Applied Polymer Science. Volume60, Issue6 9: Pages 845-855.
  5. Low molecular weight 'liquid' polymer extended compounds, impact on free volume and crosslink density studied by positron lifetime spectroscopy and stress-strain analysis according to Mooney-Rivlin  |  M. Gruendken a b, D. Koda c, J. Dryzek d, A. Blume a. August 2021,. Polymer Testing. Volume 100,: 107239.
  6. Properties of Natural Rubber Reinforced by Carbon Black-based Hybrid Fillers  |  Puchong Thaptong,Chakrit Sirisinha,Uthai Thepsuwan &Pongdhorn Sae-Oui. 2014 - Issue 8. Polymer-Plastics Technology and Engineering. Volume 53,: Pages 818-823.
  7. Effects of silanization temperature and silica type on properties of silica-filled solution styrene butadiene rubber (SSBR) for passenger car tire tread compounds  |  Puchong Thaptong, Pongdhorn Sae-Oui, Chakrit Sirisinha. May 5, 2016. Journal of Applied Polymer Science. Volume133, Issue17.
  8. Comparative study among TMTD, TBzTD, and ZBEC accelerators in isobutylene‐isoprene elastomer vulcanization  |  Vinícius Guedes Gobbi, Talita Goulart da Silva, Matheus Santos Cunha, Tiago dos Santos Mendonça, Vitor Guedes Gobbi, Rossana Mara da Silva Moreira Thiré, Roberta Helena Mendonça. September 5, 2020. Journal of Applied Polymer Science. Volume137, Issue33: 48965.
  9. Effect of conductive carbon black on electrical conductivity and performance of tire tread compounds filled with carbon black/silica hybrid filler  |  Puchong Thaptong, Pairote Jittham, Pongdhorn Sae-oui. September 10, 2021. Journal of Applied Polymer Science. Volume138, Issue34: 50855.
  10. Electrosynthesis of tetrabenzylthiuram disulfide via flow reactors  |  Siyuan Zheng, Kai Wang. 10 August 2022,. Chemical Engineering Science. Volume 257,: 117717.
  11. Decrosslinking of zinc diacrylate-cured epoxidized natural rubber via selective cleavage of carbon–oxygen bond  |  Tengfei Lin, Jinhuang Ke, Jinyun Wang, Cong Lin, Xiao Wu. October 15, 2020. Journal of Applied Polymer Science. Volume137, Issue39: 49175.
  12. Oil resistance and low-temperature characteristics of plasticized nitrile butadiene rubber compounds  |  Do Young Kim, Gi Hong Kim, Gi Myeong Nam, Dong Gug Kang, Kwan Ho Seo. August 20, 2019. Journal of Applied Polymer Science. Volume136, Issue32: 47851.
  13. Properties of tire tread compounds based on functionalized styrene butadiene rubber and functionalized natural rubber  |  https://onlinelibrary.wiley.com/doi/abs/10.1002/app.48696. May 20, 2020. Journal of Applied Polymer Science. Volume137, Issue20: 48696.

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Product NameCatalog #UNITPriceQtyFAVORITES

Tetrabenzylthiuram disulfide, 1 g

sc-492101
1 g
$209.00
1-800-457-3801
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