Restek's PLOT Column Family —
The Benchmark For Performance!

  • Innovative bonding process minimizes particle release.
  • More consistent flow means stable retention times.
  • Outstanding peak symmetry improves impurity analysis.

Next Generation of Porous Layer Open
Tubular (PLOT) Columns

  • Stabilized particle layers improve robustness and reproducibility of retention and flow.
  • Compatible with valve switching and Deans switching systems.
  • Highly efficient, reproducible analyses; ideal for permanent gases, solvents, and hydrocarbons.
  • Innovative manufacturing procedure reduces particle generation and improves performance of PLOT columns.
  • Wound on a 7"-diameter, 11-pin cage unless otherwise noted.

Porous layer open tubular (PLOT) columns are very beneficial for solving application problems, especially for the analysis of volatile compounds. PLOT columns have a unique selectivity, allowing for the separation of volatile compounds at ambient temperature. Due to the adsorption mechanism of the stationary phases used in PLOT columns, permanent gases and light hydrocarbons can be resolved at ambient temperature; columns can then be programmed to higher temperatures to elute higher boiling compounds.

Traditional PLOT Columns Offer Poor Stability

Figure 1: Particles released from traditional PLOT columns can cause blockages. Particles released from traditional PLOT columns can cause blockages.

The traditional PLOT column is built with a 5–50 μm layer of particles adhered to the tubing walls. Because this layer of particles generally lacks stability, PLOT columns must be used very carefully, as particle release is common and can cause unpredictable changes in retention time and flow behavior. Traditional PLOT columns also must generally be used in conjunction with particle traps to prevent the contamination of valves, injectors, and GC detectors. Detectors contaminated with particles typically generate electronic noise, which shows up chromatographically as a spike in the baseline. In extreme cases, detector flow can be obstructed by particle buildup. Particles can also affect valves by becoming lodged in the valve and causing leaks or restricting flow. Figure 1 shows an example of blockage caused by particle accumulation inside a Press-Tight® connector.

Restek® PLOT Columns Offer Improved Stability to Minimize Particle Release

Restek has developed technology and procedures to manufacture PLOT columns with concentric stabilized adsorption layers. These next generation PLOT columns show a constant flow behavior (permeability) and have significantly improved mechanical stability, resulting in easier operation, better chromatography, and reduced particle release. Greater particle stability means more reproducible retention times, virtually no spiking, and longer column lifetimes. This innovative Restek® stabilization chemistry is currently applied to all fused silica and metal PLOT columns featured here.

Consistent Flow Restriction Factor (F) Guarantees Reproducible Flow

Figure 2: Inconsistent coating thicknesses result in restrictions that cause significant variation in flow.

Inconsistent coating thicknesses result in restrictions that cause significant variation in flow.

Thick layers of particles are difficult to deposit in a homogeneous layer, and in traditionally manufactured PLOT columns, this results in variable coating thicknesses. The positions where the layer is thicker act as restrictions and affect flow (Figure 2). Depending on the number and intensity of these restrictions, traditional PLOT columns often show greater variation in flow restriction than wall coated open tubular (WCOT) columns. In practice, conventional PLOT columns with the same dimensions can differ in flow by a factor of 4 to 6 when operated at the same nominal pressure. For applications where flow is important, such as with Deans switching, the nonreproducible flow behavior of most commercially available PLOT columns is a problem.

In order to measure flow restriction reproducibility, Restek introduced a new factor: the flow restriction factor (F). This factor is based on the retention time of an unretained marker compound, as measured on both coated and uncoated tubing using the same backpressure setting (Equation 1). For quality control purposes, methane is used as the marker when evaluating porous polymer columns, and helium is used for testing molecular sieve 5A columns.

Flow restriction factor determination can be used to assess both the degree of column restriction and the reproducibility of the column coating process. Figure 3 shows typical results for PLOT columns manufactured using a conventional process. Because of the difference in flow restriction, individual columns have very different flow characteristics. In contrast, Figure 4 shows results for columns made using our Rt®-QS-BOND (bonded porous polymer) PLOT column process. Clearly, our manufacturing process results in greater consistency in both column coating thickness and flow restriction, which results in more stable retention times and better performance in Deans and related flow switching techniques. Flow restriction factors are specified on the certificate of analysis (CofA) included with every Restek® PLOT column, and the values are listed on the report.

Figure 3: Traditional PLOT columns show significant flow variability, indicating inconsistent column coating thicknesses.

Traditional PLOT columns show significant flow variability, indicating inconsistent column coating thicknesses.

Equation 1: Flow restriction factor (F) is used to demonstrate coating consistency.

Inconsistent coating thicknesses result in restrictions that cause significant variation in flow.

Note: F values will always be <1 as the coated column always has more restriction than the uncoated column.

Figure 4: PLOT columns from Restek offer consistent flow restriction, giving more reproducible results column to column.

Traditional PLOT columns show significant flow variability,indicating inconsistent column coating thicknesses.

Restek’s PLOT columns are exceptionally robust, featuring concentric stabilized coating layers. They allow for more consistent gas flows and are recommended for applications sensitive to variation in retention time or flow. These PLOT columns are a significant advance in technology and are ideal for efficient, reproducible analyses of permanent gases, solvents, and hydrocarbons.

PLOT Column Phase Cross-Reference: Similar Selectivity

Restek® Rt® and MXT® Columns

Porous Layer

Supelco

Alltech

Agilent (J&W, Varian, Chrompack)

Quadrex

Alumina BOND/Na2SO4

Aluminum oxide

Alumina-Sulfate

AT-Alumina

GS-Alumina, CP-Al2O3/NA2SO4

Alumina BOND/KCl

Aluminum oxide

Alumina-Chloride

GS-Alumina KCl, HP PLOT Al2O3, CP-Al2O3/KCl

Alumina BOND/CFC

Aluminum oxide

unique product

Alumina BOND/MAPD

Aluminum oxide

Select Al2O3 MAPD

Msieve 5A

Molecular sieve 5A

Molsieve 5A

AT-Molesieve

HP PLOT Molesieve,
CP-Molesieve 5A

PLT-5A

Q-BOND

100% Divinylbenzene

Supel-Q-PLOT

AT-Q

HP PLOT Q ,CP-PoraPlot Q, PoraBond Q

QS-BOND

Intermediate polarity porous polymer

GS-Q

S-BOND

DVB vinylpyridine polymer

CP-PoraPlot S

U-BOND

DVB ethylene glycoldimethylacrylate polymer

HP PLOT U, CP-PoraPlot U, CP-PoraBond U

Silica BOND

Bonded silica

CP Silica PLOT, GS-GasPro


Rt®-Alumina BOND Columns

Restek® Rt®-Alumina BOND columns are highly selective for C1–C5 hydrocarbons and separate all saturated and unsaturated hydrocarbon isomers above ambient temperatures. The reactivity of the aluminum oxide stationary phase is minimized, by deactivation with inorganic salts like KCl or Na2SO4, to improve column response for polar unsaturates, such as dienes, and the column's sensitivity (or response) ensures linear and quantitative chromatographic analysis for these compounds. Strong bonding mimimizes particle generation and release, which allows valve switching with minimal risk to the injection or detection systems. And because they are stable up to at least 200 °C, Rt®-Alumina BOND columns can be regenerated to restore full efficiency and selectivity by conditioning at their maximum temperature if water is adsorbed. High capacity and loadability give you exceptionally symmetrical peaks, making these columns ideal for volatile hydrocarbon separations at percent levels, as well as impurity analyses at ppm concentrations. Restek® Rt®-Alumina BOND PLOT columns are manufactured on fused silica tubing; select phases are also available on metal MXT® tubing.

To ensure reproducible retention times and predictable flow behavior column to column, each Rt®-Alumina BOND column is extensively tested. A hydrocarbon test mix confirms proper phase retention and selectivity. To calculate k (retention or capacity factor), which is a measure of phase retention, 1,3-butadiene is used, while selectivity is measured using retention indices for propadiene and methyl acetylene. The resolution of trans-2-butene and 1-butene is also verified and, to measure efficiency, plates per meter are checked using 1,3-butadiene.

Rt®-Alumina BOND/Na2SO4 Columns (fused silica PLOT)

(Na2SO4 deactivation)

  • Acetylene and propadiene elute after butanes.
  • Best separation for butene isomers (impurities in butene streams).
  • Methyl acetylene elutes after 1,3-butadiene.
  • Cyclopropane (impurity in propylene) elutes well before propylene.
  • Stable to 200 °C.
  • Also available on metal MXT® tubing!
tech tip

Traces of water in the carrier gas and samples will affect the retention and the selectivity of alumina. If exposed to water, the retention times will shorten. The column can be regenerated by conditioning for 15–30 minutes at 200 °C under normal carrier gas flow. Periodic conditioning ensures excellent run-to-run retention time reproducibility.

Unless noted, the maximum programmable temperature for an Rt®-Alumina BOND column is
200 °C. Temperatures higher than the stated maximum temperature can cause irreversible changes to the porous layer adsorption properties.

Refinery Gas on Rt®-Alumina BOND (Na2SO4)

Peaks
1.Methane
2.Ethane
3.Ethylene
4.Propane
5.Propylene
6.Isobutane
7.n-Butane
8.Propadiene
9.Acetylene
10.trans-2-Butene
Peaks
11.1-Butene
12.Isobutylene
13.cis-2-Butene
14.iso-Pentane
15.n-Pentane
16.1,3-Butadiene
17.trans-2-Pentene
18.2-Methyl-2-butene
19.1-Pentene
20.cis-2-Pentene
21.Hexanes
Refinery Gas on Rt-Alumina BOND (Na2SO4)
GC_PC01085
ColumnRt®-Alumina BOND/Na2SO4, 50 m, 0.53 mm ID, 10 µm (cat.# 19756)
SampleRefinery gas
Injection
Inj. Vol.:10 µL split
Liner:Taper (2 mm) (cat.# 20795)
Inj. Temp.:200 °C
Split Vent Flow Rate:80 ml/min
Oven
Oven Temp.:45 °C (hold 1 min) to 200 °C at 10 °C/min (hold 3.5 min)
Carrier GasH2, constant pressure (8.0 psi, 55.2 kPa)
Linear Velocity:74 cm/sec @ 45 °C
DetectorFID @ 200 °C

Rt®-Alumina BOND/KCl Columns (fused silica PLOT)

(KCl deactivation)

  • Restek's lowest polarity alumina column.
  • Low moisture sensitivity reduces the need for frequent regeneration.
  • Acetylene elutes before n-butane.
  • Methyl acetylene (impurity in 1,3-butadiene) elutes before 1,3-butadiene.
  • Stable to 200 °C.

Ethylene and C1-C5 Hydrocarbons by ASTM D6159-97 on Rt®-Alumina BOND/KCl, Rtx®-1

Peaks
1.Methane
2.Ethane
3.Ethylene
4.Propane
5.Cyclopropane
6.Propylene
7.Acetylene
8.Isobutane
9.Propadiene
Peaks
10.n-Butane
11.trans-2-Butene
12.1-Butene
13.Isobutylene
14.cis-2-Butene
15.iso-Pentane
16.Methylacetylene
17.n-Pentane
18.1,3-Butadiene
Ethylene and C1-C5 Hydrocarbons by ASTM D6159-97 on Rt-Alumina BOND/KCl, Rtx-1
GC_PC01110
ColumnRt®-Alumina BOND/KCl *, 50 m, 0.53 mm ID, 10 µm (cat.# 19760)
SampleEthylene gas plus C1 through C5 hydrocarbons
Injection
Inj. Vol.:1 µL split
Liner:2 mm splitless (cat.# 20712)
Inj. Temp.:200 °C
Split Vent Flow Rate:60 ml/min
Oven
Oven Temp.:35 °C (hold 2 min) to 190 °C at 4 °C/min (hold 15 min)
Carrier GasHe, constant pressure (8.0 psi, 55.2 kPa)
Linear Velocity:25.4 cm/sec @ 35 °C
DetectorFID @ 200 °C
Make-up Gas Type:N2
Data Rate:20 Hz
InstrumentHP5890 GC
Notes* Rt®-Alumina BOND/KCl, 50 m, 0.53 mm ID, 10.0 μm (cat.# 19760) in series with an Rtx®-1, 30 m, 0.53 mm ID, 5.0 μm (cat.# 10179) connected using a universal Press-Tight® connector (cat. # 20401)

(conditions as per ASTM D6159-97)

Rt®-Alumina BOND/CFC Columns (fused silica PLOT)

  • Improved inertness for chlorofluorocarbon (CFC) compounds.
  • Highly selective alumina-based column, separates most CFCs.
  • High retention and capacity for CFCs.
  • Stable to 200 °C.

The Alumina BOND/CFC adsorbent is ideal for retaining volatile halogenated compounds, especially CFCs (chlorinated fluorocarbons) like Freon® products. It offers high selectivity, allowing a wide range of CFC isomers to be resolved at above ambient temperatures. The Rt®-Alumina BOND/CFC column is thoroughly deactivated to reduce the reactivity of alumina. Even though there is still some residual reactivity for some mono- or disubstituted CFCs, the majority of these compounds can be accurately quantified from main stream processes or in impurity analyses.

tech tip

Especially when valve switching or backflushing is used, Restek recommends using particle traps to help prevent detector spikes and valve rotor scratches.

Visit www.restek.com/plot for specialized PLOT column particle traps.

Impurity Analysis of 1,1,1,2-Tetrafluoroethane (CFC-134a) on Rt®-Alumina BOND/CFC

Peaks
1.Chloropentafluoroethane (CFC-115)
2.Dichlorodifluoromethane (CFC-12)
Peaks
3.Chlorodifluoromethane (CFC-22)
4.1,1,1,2-Tetrafluoroethane (CFC-134a)
Impurity Analysis of 1,1,1,2-Tetrafluoroethane (CFC-134a) on Rt-Alumina BOND/CFC
GC_GN1155
ColumnRt®-Alumina BOND/CFC, 30 m, 0.53 mm ID (cat.# 19763)
Sample1,1,1,2-Tetrafluoroethane
Conc.:Neat
Injection
Inj. Vol.:500 µL split
Oven
Oven Temp.:80 °C (hold 6 min) to 140 °C at 10 °C/min (hold 2 min)
Carrier GasHe
DetectorFID
NotesGas sampling, purity analysis

Note that tailing peaks are common in CFC analyses due to overloading normally employed for this type of work.

Rt®-Alumina BOND/MAPD Columns (fused silica PLOT)

  • Optimized deactivation produces maximum response when analyzing trace levels of acetylene, methyl acetylene, and propadiene.
  • Stable response factors make this column ideal for process-type applications where recalibration must be minimized.
  • High loadability reduces peak tailing and improves separations.
  • Extended temperature range up to 250 °C for fast elution of high molecular weight (HMW) hydrocarbons and accelerated column regeneration following exposure to water.
  • Stable to 250 °C.
  • Also available on metal MXT® tubing!

Restek's R&D chemists have optimized the deactivation technology applied to our Rt®-Alumina BOND/MAPD column for improved analysis of trace concentrations of polar hydrocarbons like acetylene, methyl acetylene, and propadiene in hydrocarbon streams containing higher levels of C1-C5 hydrocarbons. Our alumina PLOT deactivation produces an incredibly inert column that offers superior reproducibility and stable response factors to maximize the number of analyses before recalibration is required. Its high sample capacity reduces peak tailing, thereby improving the separation of target compounds. In addition, a 250 °C maximum operating temperature lets you more quickly elute hydrocarbons up to dodecane and reduces regeneration time when the column is exposed to water from samples or carrier gases.

1,3-Butadiene on Rt®-Alumina BOND/MAPD (Purity Analysis)

Rt®-Alumina BOND/MAPD PLOT
columns are made specifically
for the analysis of petrochemicals
and downstream products such
as ethylene, propylene, butylenes,
and butadiene.

Peaks
1.Isobutane
2.n-Butane
3.Propadiene
4.trans-2-Butene
5.1-Butene
6.Isobutene
7.cis-2-Butene
8.Isopentane
9.n-Pentane
10.1,2-Butadiene
11.1,3-Butadiene
12.Methyl acetylene
1,3-Butadiene on Rt-Alumina BOND/MAPD (Purity Analysis)
GC_PC1211
ColumnRt®-Alumina BOND/MAPD, 50 m, 0.53 mm ID, 10.0 µm (cat.# 19778)
SampleCrude 1,3-butadiene
Injection
Inj. Vol.:10 µL split
Liner:2.0 mm ID straight inlet liner (cat.# 20712)
Inj. Temp.:200 °C
Split Vent Flow Rate:100 mL/min
Oven
Oven Temp.:70 °C (hold 5 min) to 200 °C at 10 °C/min (hold 0 min)
Carrier GasHe, constant pressure (20 psi, 137.9 kPa)
DetectorFID @ 250 °C
Make-up Gas Flow Rate:30 mL/min
Make-up Gas Type:N2
Data Rate:20 Hz
InstrumentHP5890 GC

Molecular Sieve 5A PLOT Columns

Restek’s molecular sieve 5A PLOT columns are designed for efficient separation of argon/oxygen and other permanent gases, including carbon monoxide. Special coating and deactivation procedures ensure chromatographic efficiency and the integrity of the porous layer coating. Molecular sieves have very high retention, allowing separations of permanent gases at temperatures above ambient. Our deactivation technology also allows carbon monoxide to elute as a sharp peak. Additionally, our unique immobilization process guarantees that the uniform particles remain adhered to the tubing—even after continuous valve cycling.

Rt®-Msieve 5A Columns (fused silica PLOT)

  • Improve accuracy with sharp, symmetrical peaks for argon, oxygen, and carbon monoxide.
  • Easily separate permanent gases at temperatures above ambient.
  • Restek® PLOT technology reduces particle release, improving flow reproducibility and reducing downtime for maintenance.
  • Stable to 300 °C.
  • Also available on metal MXT® tubing!

Separation of Argon/Oxygen and Other Permanent Gases on Rt®-Msieve 5A

PeaksConc.
(µg/mL)
1.Hydrogen40
2.Argon30
3.Oxygen50
4.Nitrogen50
5.Methane40
6.Carbon monoxide50
Permanent Gases Rt-Msieve 5A
GC_PC00898
ColumnRt-Msieve 5A, 30 m, 0.53 mm ID, 50 µm (cat.# 19723)
SamplePermanent gases
Injectionsample valve
Sample Loop Vol.:5 µL
Valve Name:6-port Valco valve
Inj. Temp.:200 °C
Valve Temp.:Ambient °C
Oven
Oven Temp.:27 °C (hold 5 min) to 100 °C at 10 °C/min (hold 5 min)
Carrier GasHe, constant flow
Flow Rate:5.0 mL/min
DetectorValco helium ionization detector @ 150 °C
tech tip

Because molecular sieve materials are very hydrophilic, they will adsorb water from the sample or carrier gas. Water contamination can have a detrimental effect on peak symmetry and can reduce the resolution of all compounds. If water contamination occurs, reactivate your Rt®-Msieve 5A PLOT column by conditioning at 300 °C with dry carrier gas flow for 3 hours.

Porous Polymer Columns

Porous polymers are unique, highly retentive stationary phases with a wide application range that are able to elute both polar and nonpolar compounds. They are very hydrophobic, so water has no impact on retention times and even elutes as a good chromatographic peak. The Q-BOND is our most nonpolar and widely used porous polymer column; functional groups can be added to increase polarity (i.e., QS-, S-, and U-BOND). The process used to manufacture porous polymer PLOT columns causes the particles to adhere strongly to the walls of the tubing, so there is virtually no particle generation. You get reproducible performance from column to column, including selectivity and flow.

Rt®-Q-BOND Columns (fused silica PLOT)

100% divinylbenzene

  • Nonpolar PLOT column incorporating 100% divinylbenzene.
  • Excellent for analysis of C1 to C3 hydrocarbons as well as isomers and alkanes up to C12.
  • High retention for CO2 simplifies gas analysis; CO2 and methane separated from O2/N2/CO.
    (Note: O2/N2/CO not separated at ambient temperature.)
  • Use for analysis of oxygenated compounds and solvents.
  • Maximum temperature of 300 °C.
  • Also available on metal MXT® tubing!

Solvent Mixture on Rt®-Q-BOND

Peaks
1.Methanol
2.Ethanol
3.Acetonitrile
4.Acetone
5.Dichloromethane
6.1,1-Dichloroethene
7.Nitromethane
8.trans-1,2-Dichloroethylene
9.cis-1,2-Dichloroethylene
10.Tetrahydrofuran
11.Chloroform
12.Ethyl acetate
13.1,2-Dichloroethane
14.1,1,1-Trichloroethane
Peaks
15.Benzene
16.1,2-Dimethoxyethane
17.Trichloroethylene
18.1,4-Dioxane
19.Pyridine
20.Dimethylformamide
21.Methylcyclohexane
22.Toluene
23.2-Hexanone
24.Chlorobenzene
25.Ethylbenzene
26.m-Xylene
27.p-Xylene
28.o-Xylene
Solvent Mixture on Rt-Q-BOND
GC_PC01082
ColumnRt®-Q-BOND, 30 m, 0.53 mm ID, 20 µm (cat.# 19742)
SampleSolvent mixture
Injection
Inj. Vol.:1.0 µL split
Liner:Splitless taper (4 mm) (cat.# 20798)
Inj. Temp.:200 °C
Split Vent Flow Rate:100 ml/min
Oven
Oven Temp.:120 °C to 240 °C at 5 °C/min (hold 5.0 min)
Carrier GasH2, constant pressure (4.2 psi, 29.0 kPa)
Linear Velocity:40 cm/sec @ 120 °C
DetectorFID @ 240 °C

Rt®-QS-BOND Columns (fused silica PLOT)

porous divinylbenzene homopolymer

  • Intermediate polarity porous polymer PLOT column incorporating low 4-vinylpyridine.
  • Separates ethane, ethylene, and acetylene to baseline.
  • Stable to 250 °C.

Refinery Gas Mixture on Rt®-QS-BOND

Peaks
1.Air
2.Methane
3.Carbon dioxide
4.Ethylene
5.Acetylene
6.Ethane
7.Propylene
8.Propane
9.Propadiene
10.Isobutane
11.Isobutylene
Peaks
12.1-Butene
13.1,3-Butadiene
14.n-Butane
15.cis-2-Butene
16.trans-2-Butene
17.Isopentane
18.1-Pentene
19.2-Methyl-2-butene
20.n-Pentane
21.cis-2-Pentene
22.n-Hexane
Refinery Gas
GC_PC01143
ColumnRt®-QS-BOND, 30 m, 0.53 mm ID, 20 µm (cat.# 19738)
SampleRefinery gas standard
Injection
Inj. Vol.:20 µL split
Liner:2 mm (cat.# 20712)
Inj. Temp.:200 °C
Split Vent Flow Rate:35 mL/min
Oven
Oven Temp.:40 °C (hold 2 min) to 225 °C at 15 °C/min (hold 5 min)
Carrier GasHe, constant pressure (11.5 psi, 79.3 kPa)
Linear Velocity:68 cm/sec @ 40 °C
DetectorTCD @ 225 °C
Make-up Gas Type:He
Data Rate:20 Hz
Sensitivity Mode:He/H2
InstrumentHP5890 GC

Rt®-S-BOND Columns (fused silica PLOT)

porous divinylbenzene homopolymer

  • Midpolarity porous polymer PLOT column, incorporating high 4-vinylpyridine.
  • Use for the analysis of nonpolar and polar compounds.
  • Stable to 250 °C.
  • Also available on metal MXT® tubing!

Solvent Mixture on Rt®-S-BOND

Peaks
1.Methanol
2.Ethanol
3.Acetonitrile
4.Acetone
5.Dichloromethane
6.1,1-Dichloroethene
7.Nitromethane
8.trans-1,2-Dichloroethylene
9.cis-1,2-Dichloroethylene
10.Tetrahydrofuran
11.Chloroform
12.Ethyl acetate
13.1,2-Dichloroethane
14.1,1,1-Trichloroethane
Peaks
15.Benzene
16.1,2-Dimethoxyethane
17.Trichloroethylene
18.1,4-Dioxane
19.Pyridine
20.Dimethylformamide
21.Methylcyclohexane
22.Toluene
23.2-Hexanone
24.Chlorobenzene
25.Ethylbenzene
26.m-Xylene
27.p-Xylene
28.o-Xylene
Solvent Mixture on Rt-S-BOND
GC_PC01080
ColumnRt®-S-BOND, 30 m, 0.53 mm ID, 20 µm (cat.# 19746)
SampleSolvent mixture
Injection
Inj. Vol.:1.0 µL split
Liner:Taper (4 mm) (cat.# 20798)
Inj. Temp.:200 °C
Split Vent Flow Rate:100 ml/min
Oven
Oven Temp.:120 °C to 220 °C at 5 °C/min (hold 5.0 min)
Carrier GasH2, constant pressure (4.2 psi, 29.0 kPa)
Linear Velocity:40 cm/sec @ 120 °C
DetectorFID @ 220 °C

Rt®-U-BOND Columns (fused silica PLOT)

divinylbenzene ethylene glycol/dimethylacrylate

  • Restek's highest polarity porous polymer column.
  • Polar PLOT column, incorporating divinylbenzene ethylene glycol/dimethylacrylate.
  • Highly inert for the analysis of polar and nonpolar compounds.
  • Ideal for trace H2S, COS, and mercaptans in hydrocarbon streams.
  • Stable to 190 °C.

Formaldehyde on Rt®-U-BOND

Excellent peak shape for
highly polar analytes

Peaks
1.Air
2.Carbon dioxide
3.Formaldehyde
4.Water
5.Methanol
Formaldehyde on Rt-U-BOND
GC_CH01137
ColumnRt®-U-BOND, 30 m, 0.53 mm ID, 20 µm (cat.# 19750)
SampleFormaldehyde (manual headspace)
Injection
Inj. Vol.:10 µL split (split ratio 10:1)
Liner:2 mm split Precision® liner w/wool (cat.# 20823)
Inj. Temp.:200 °C
Split Vent Flow Rate:40 mL/min
Oven
Oven Temp.:100 °C (hold 1 min) to 150 °C at 25 °C/min (hold 3 min)
Carrier GasHe, constant pressure (7.7 psi, 53.1 kPa)
Linear Velocity:39 cm/sec @ 100 °C
DetectorTCD @ 200 °C
Make-up Gas Type:He
Data Rate:20 Hz
Sensitivity Mode:He/H2
InstrumentHP5890 GC

Rt®-Silica BOND Columns (fused silica PLOT)

  • Versatile column ideal for analysis of light hydrocarbons, sulfur gases, halocarbons, and carbon dioxide.
  • Individually QC tested with sensitive C4 probes to ensure consistent selectivity.
  • Proprietary manufacturing process practically eliminates particle release, reducing downtime due to obstructed FID jets.
  • Stable to 260 °C.

Saturated and Unsaturated Hydrocarbons on Rt®-Silica BOND PLOT Column

Peaks
1.Methane
2.Ethane
3.Ethylene
4.Acetylene
5.Propane
6.Cyclopropane
7.Propylene
8.Propadiene
Peaks
9.n-Butane
10.1-Butene
11.Methyl acetylene
12.1,3-Butadiene
13.trans-2-Butene
14.Isobutylene
15.cis-2-Butene
16.Isopentane
17.n-Pentane
Saturated and Unsaturated Hydrocarbons on Rt-Silica BOND PLOT Column
GC_PC1266
ColumnRt®-Silica BOND, 30 m, 0.32 mm ID (cat.# 19785)
SampleCustom DCG gas standard
Diluent:Nitrogen
Conc.:1 mole percent
Injection
Inj. Vol.:15 µL split (split ratio 35:1)
Liner:Premium 2 mm straight inlet liner (cat.# 23313.1)
Inj. Temp.:250 °C
Oven
Oven Temp.:60 °C (hold 2 min) to 175 °C at 2 °C/min
Carrier GasHe, constant flow
Flow Rate:3.3 mL/min
DetectorFID @ 260 °C
Make-up Gas Flow Rate:50 mL/min
Make-up Gas Type:N2
Hydrogen flow:40 mL/min
Air flow:400 mL/min
Data Rate:10 Hz
InstrumentAgilent 7890A GC

Metal MXT® PLOT Columns

Advantages of metal MXT® PLOT columns include:

  • Can be made in small coil diameters—perfect for tight spaces.
  • Rugged material withstands rough handling and shock.
  • Designed for robust performance in process GCs and field instruments.
  • Available in 3.5"-coil diameter or 7"-diameter, 11-pin cage.

Restek® chemists have developed technology that allows many of our popular PLOT columns to be made on Siltek®-treated stainless steel. These columns have the same characteristics and performance as fused silica PLOT columns, but offer additional benefits for process GCs and field applications as they are virtually unbreakable and can be coiled into very small diameters.

MXT®-Msieve 5AMXT®-Alumina BOND/MAPDMXT®-S-BOND

MXT®-Alumina BOND/Na2SO4MXT®-Q-BOND

MXT® Low Dead Volume Connector Kits for Metal Columns

  • Connect a guard column/transfer line to an MXT® stainless steel column.
  • Low thermal mass tracks rapid oven temperature programming.
  • Stainless steel ferrules and nuts.
  • Available in “Y” and union configurations.
  • Siltek® treatment ensures ultimate inertness.

Each kit contains the MXT® union, two 1/32-inch ferrules and nuts.

Download a PDF of our PLOT columns sales sheet