Sodium alpha-olefin Sulfonate - ≥92% , CAS No.68439-57-6

CAS: 68439-57-6 Cat. No.: S304377 Número EC: 270-407-8
Disponible para pedir
GRADE & PURITY ≥92%
Storage
Room temperature,Desiccated
Shipped In
Normal
 ·  off list, applied to all prices below.
Size
Estado
Price
Qty
5g
S304377-5g
4

9,90US$

14,90US$
Guardar 5,00 US$ (33.56%)
25g
S304377-25g
4

31,90US$

47,90US$
Guardar 16,00 US$ (33.40%)
100g
S304377-100g
5

105,90US$

158,90US$
Guardar 53,00 US$ (33.35%)
500g
S304377-500g
1

397,90US$

596,90US$
Guardar 199,00 US$ (33.34%)
Enter a quantity for the sizes you want to add.
🧪

Why this grade

≥92% for sensitive chromatographic and analytical workflows requiring minimal baseline interference.

🌡

Storage & shipping

Room temperature,Desiccated Ships Normal Check lot-specific COA for exact specifications.

📋

Quality documents

SDS, COA, datasheet, and spec sheet available for download. Lot-specific COA accessible via lot number lookup.

📚

Literature proof

Cited in 11 peer-reviewed publications across chromatography, organic synthesis, and cross-coupling reactions.

Specifications

Especificaciones y pureza
≥92%
Condiciones de almacenamiento de almacenamiento
Room temperature, Desiccated
Enviado en
Normal
Pureza
≥92%

Documentation

📋 Safety Data Sheet (SDS)

Comprehensive hazard, handling, storage, and regulatory compliance document.

Download SDS →

✅ Certificate of Analysis (COA)

Lot-specific quality data. Enter your lot number to retrieve the exact COA.

Look up COA →

📊 Datasheet

Quick-reference summary of product specifications and applications.

View datasheet →

🔬 Specification Sheet

Full quality attributes and acceptance criteria for this grade.

View spec sheet →

Advanced Data

Certificados (CoA, COO, BSE/TSE y tabla de análisis)
C of A & Other Certificates(BSE/TSE, COO):
Analytical Chart:

Find and download the COA for your product by matching the lot number on the packaging.

23 results found

Lot NumberCertificate TypeFechaArticulo
E2308095Certificate of AnalysisFeb 04, 2026 S304377
C2324608Certificate of AnalysisJan 19, 2026 S304377
B2314144Certificate of AnalysisOct 30, 2025 S304377
A2309439Certificate of AnalysisOct 13, 2025 S304377
A2309385Certificate of AnalysisOct 13, 2025 S304377
H2224105Certificate of AnalysisJun 10, 2025 S304377
H2224104Certificate of AnalysisJun 10, 2025 S304377
J2511128Certificate of AnalysisJun 25, 2024 S304377
I2523057Certificate of AnalysisJun 25, 2024 S304377
G2409394Certificate of AnalysisJun 25, 2024 S304377
G2409393Certificate of AnalysisJun 25, 2024 S304377
G2409382Certificate of AnalysisJun 25, 2024 S304377
G2409381Certificate of AnalysisJun 25, 2024 S304377
G2409380Certificate of AnalysisJun 25, 2024 S304377
F2613033Certificate of AnalysisJun 25, 2024 S304377
E2521012Certificate of AnalysisJun 25, 2024 S304377
B2603135Certificate of AnalysisJun 25, 2024 S304377
G2131315Certificate of AnalysisMay 14, 2024 S304377
G2314169Certificate of AnalysisJul 22, 2022 S304377
H2224096Certificate of AnalysisJul 22, 2022 S304377
C2429019Certificate of AnalysisJul 22, 2022 S304377
H2224160Certificate of AnalysisJul 22, 2022 S304377
A2429416Certificate of AnalysisJul 22, 2022 S304377

Show more ⌵

Preguntas frecuentes y artículos
A Panoramic Guide to Surfactants: Definitions & Mechanisms, Key Metrics, Application Scenarios, and Selection Navigation (Tables 1–3)
Why LABSA (Sulfonic Acid) Is Commonly Used in Household Cleaning Formulations: Neutralization Mechanism, Detergency Action, and Formulation Application Points
Application of Fatty Acid Methyl Ester Sulfonate (MES) in Household Detergent and Cleaning Formulations: Detergency, Hard-Water Tolerance, and Selection Criteria
K12 (Sodium Lauryl Sulfate/SLS) Is More Than a Foaming Agent: Structure, Properties, and Applications in Personal Care and Household Care Formulations
Why Can 6501 (Cocamide DEA) Stabilize Foam and Build Viscosity? Structural Mechanism, 1:1/1:1.5 Differences, and Application Selection
AES (Fatty Alcohol Polyoxyethylene Ether Sulfate) in Personal and Home-Care Cleansing Formulations: An Analysis of Structure, Performance, and Low-Temperature Flowability
Degreasing Agents from a Molecular-Structure Perspective: How AEO, APG, and Related Surfactants Can Replace Nonylphenol Ethoxylates (NPE)
Understanding CAPB from Its Structure: How Cocamidopropyl Betaine Improves Foam, Enhances Mildness, and Supports Thickening
Interfacial Mechanism and Formulation Applications of AEO-9 (Fatty Alcohol Polyoxyethylene Ether): An Analysis of Emulsification, Wetting, Oil Soil Removal, and Co-Formulation Compatibility
Wetting and Penetration Mechanisms of Penetrating Agents in Household and Personal Care Cleaning Systems: Representative Structural Analysis Using JFC, OEP-70, and DOSS as Examples
What Are the Differences Among Sodium Dodecylbenzenesulfonate/SDBS, LAS, and Sodium α-Olefin Sulfonate/AOS: A Comparative Overview of Synthesis, Structure, Mechanism of Action, and Formulation Selection
From Structure to Selection: Mechanisms and Application Assessment of Low-Foam Oil and Wax Removal with Fatty Acid Methyl Ester Ethoxylates (FMEE)
Analysis of the Foaming Performance Differences Between K12 and AOS: Structure, Acid–Base Stability, and Formulation Selection
Understanding Anionic Surfactants in Household and Personal-Care Formulations from a Structural Perspective: Structural and Performance Differences among Representative Raw Materials such as LAS, AES, K12, AOS, MES, and FMES
Structural Characteristics, Low-Temperature Flowability, and Home-Care Cleaning Applications of Palm-Derived Isomeric Alcohol Polyoxyethylene Ether PLE-S9
Citations of This Product
Referencias
1. Jiani Hu, Meilong Fu, Yuxia Zhou, Fei Wu, Minxuan Li.  (2023)  Experimental Study on SiO2 Nanoparticles-Assisted Alpha-Olefin Sulfonate Sodium (AOS) and Hydrolyzed Polyacrylamide (HPAM) Synergistically Enhanced Oil Recovery.  Energies,  16  (22): (7523).  [PMID:] [10.3390/en16227523]
2. Zejun Wang, Zhibing Yang, Yi-Feng Chen.  (2023)  Pore-scale investigation of surfactant-enhanced DNAPL mobilization and solubilization.  CHEMOSPHERE,      [PMID:37673186] [10.1016/j.chemosphere.2023.140071]
3. Li Zhe, He Yingqi, Kang Wanli, Yang Hongbin, Zhou Bobo, Jiang Haizhuang, Hao Jiting, Ning Changyuan, Wang Huazheng.  (2023)  Anionic–zwitterionic viscoelastic surfactant strengthened air foams for heterogeneous reservoirs.  PHYSICS OF FLUIDS,  35  (8):   [PMID:] [10.1063/5.0163830]
4. Xiaoning Feng, Shuhai Guo, Fushan Wen, Wei Zhu, Xiujie Yang, Meixia Gu, Nan Shi, Zhiheng Li, Bin Lou, Dong Liu.  (2023)  New insight into desorption behavior and mechanism of oil from aged oil-contaminated soil in microemulsion.  JOURNAL OF HAZARDOUS MATERIALS,      [PMID:36913749] [10.1016/j.jhazmat.2023.131108]
5. Ning Sun, Xue Yao, Zhongzheng Xu, Jiaming Li, Ning Yang, Dongfang Lyu, Guang Zhao, Caili Dai.  (2022)  Janus nanographene oxide with aerophilic/hydrophilic characteristics for enhancing foam stability in high-temperature reservoirs.  JOURNAL OF MOLECULAR LIQUIDS,      [PMID:] [10.1016/j.molliq.2022.121087]
6. Shuai Liu, Yuan Geng, Chao Li, Min Hu, Jiang Liu, Qi Gao, Xingguang Xu.  (2024)  Exploring the microscopic synergism of hydrophobic nanoparticles and surfactants in surfactants-assisted nanofluids (SAN) for enhanced oil recovery.  Geoenergy Science and Engineering,      [PMID:] [10.1016/j.geoen.2024.213632]
7. Haibo He, Jixiang Guo, Bo Wang, Yuzhi Zhang, Fan Lei, Tao Wang, Tiantian Zhang, Jing Wang.  (2024)  Research on the Application Potential of New Nano-Oil Displacement Agents to Improve Shale Oil Recovery Rates.  Energies,  18  (1): (61).  [PMID:] [10.3390/en18010061]
8. Jiayi Zhou, Ruobing Yu, Jinyu Shi.  (2025)  Quantum dot ' armor ' coating: a composite coating with excellent performance based on modified carbon quantum dots.  JOURNAL OF LUMINESCENCE,      [PMID:] [10.1016/j.jlumin.2025.121457]
9. Hongbin Yang, Haocong Li, Hao Xu, Ruichao Wang, Yubin Zhang, Luyao Xing, Xin Chen, Liang Peng, Wanli Kang, Bauyrzhan Sarsenbekuly.  (2025)  Enhanced CO2 foam stabilization with fluorescent nano polymer microspheres for improved oil recovery: Insights from microscopic and macroscopic displacement studies.  Geoenergy Science and Engineering,      [PMID:] [10.1016/j.geoen.2025.214222]
10. Yuanyuan Guo, Wanqing Wu, Chengzhuo Li, Yu Zhou, Van Thanh Pham, Qinggong Zheng.  (2025)  Solid-state hydrogen hydrates formation in a low- concentration MOF complexed with 1,3-DIOX.  Journal of Environmental Chemical Engineering,      [PMID:] [10.1016/j.jece.2025.119930]
11. Yuxin Luo, Wenyi Yang, Zhanpeng Xie, Hang Zheng, Wanfen Pu, Feng Jiang.  (2026)  Synthesis of a Multi-Armed Hydrazide-POSS and Its Enhancement on the Salt and Thermal Resistance of Hydrophobically Associated Polymers.  POLYMER ENGINEERING AND SCIENCE,      [PMID:] [10.1002/pen.70387]
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