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Supelco

Carbosieve Carbon Adsorbent

matrix Carbosieve S-II, 60-80 mesh, bottle of 10 g

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About This Item

EC Number:
UNSPSC Code:
23201100

product name

Carbosieve Adsorbent, matrix Carbosieve S-II, 60-80 mesh, bottle of 10 g

product line

Carbosieve

Quality Level

form

granular

packaging

bottle of 10 g

technique(s)

LPLC: suitable
gas chromatography (GC): suitable
solid phase extraction (SPE): suitable

surface area

~1059 m2/g

matrix

Carbosieve S-II

matrix active group

carbon

particle size

60-80 mesh

pore size

~0.01 cm3/g mesoporosity
~0.45 cm3/g microporosity
~0 cm3/g macroporosity
~6-15 Å pore diameter

density

~0.61 g/mL (free fall density)

separation technique

reversed phase

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General description

A carbon molecular sieve (CMS) is the porous carbon skeletal framework that remains after pyrolysis of a polymeric precursor. These particles are:
  • Spherical (better packed bed performance than granular particles)
  • Hard and non-friable (pack well, will not break)
  • Highly porous (high surface areas)
  • Used for molecules with an analyte size relative to C2-C5 n-alkanes
  • Hydrophobic (can be used in high humidity environments)

Generally, CMS adsorbents offer greater relative adsorptive strength compared to spherical graphitized polymer carbon (SGPC) and graphitized carbon black (GCB) adsorbents. Our Carbosieve products are a type of CMS adsorbent.
  • Have non-tapered pores
  • Very strong adsorptive strength due to only containing micropores
  • Provide great performance for many small, volatile analytes that most adsorbents have trouble retaining

For more information about any of our specialty carbon adsorbents, please visit sigma-aldrich.com/carbon

Legal Information

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flash_point_f

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flash_point_c

Not applicable

ppe

Eyeshields, Gloves, type P3 (EN 143) respirator cartridges


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Water adsorption capacity of the solid adsorbents Tenax TA, Tenax GR, Carbotrap, Carbotrap C, Carbosieve SIII, and Carboxen 569 and water management techniques for the atmospheric sampling of volatile organic trace gases.
Detlev H et al.
Analytical Chemistry, 67 (23), 4380-4386 (1995)
C Y Peng et al.
Journal of environmental monitoring : JEM, 2(4), 313-324 (2001-03-16)
Air sampling, using sorbents, thermal desorption and gas chromatography, is a versatile method for identifying and quantifying trace levels of volatile organic compounds (VOCs). Thermal desorption can provide high sensitivity, appropropriate choices of sorbents and method parameters can accommodate a
Juliane Hollender et al.
Journal of chromatography. A, 962(1-2), 175-181 (2002-08-30)
A simple method using active trapping on adsorbents and thermal desorption followed by GC-MS analysis was developed for the indoor air monitoring of monoterpenes. The study was carried out using a dynamically generated atmosphere consisting of 11 monoterpenes: camphene, camphor
D R Nelson et al.
Applied microbiology, 28(2), 258-261 (1974-08-01)
A gas chromatographic procedure for the simultaneous analysis of (14)C-labeled and unlabeled metabolic gases from microbial methanogenic systems is described. H(2), CH(4), and CO(2) were separated within 2.5 min on a Carbosieve B column and were detected by thermal conductivity.
Stuart Batterman et al.
Journal of environmental monitoring : JEM, 4(3), 361-370 (2002-07-04)
While air sampling techniques using adsorbent-based collection, thermal desorption and chromatographic analysis have found a niche in ambient air sampling, occupational applications have been more limited. This paper evaluates the use of thermal desorption techniques for low flow active and

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