A Short‐Chain Branching Distribution Determination Technique for Polyethylene Using IR5‐Detected GPC

Yu, Youlu

doi:10.1002/masy.201900014

Cited by 4 publications

(2 citation statements)

References 12 publications

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“…Recently, SEC coupled with IR-5 detection also in practice to determine SCB distribution for polyolefins which gives information of SCB distribution across the MWD [30]. It was reported that SEC-IR-5 detection also suffers from certain limitations that detection limit of this technique was found to be ∼0.5-1.0 SCB/1000TC, this uncertainty is attributed by experimental conditions and environment, which can affect not only the signals but also the noise levels at different IR bands [15]. However, LDPE typically exhibits 10 to 30 SCBs per 1000 carbon atoms, and the LCB density is only 1-3 per 1000 carbon atoms as evident from earlier reported findings [10] hence detection limit is not the concern in the case of LDPE while using SEC-IR-5 as a detection tool.…”

Section: Introductionmentioning

confidence: 99%

“…Based on the prior art analysis, researchers have reported standalone techniques, for example, nuclear magnetic resonance (NMR) [13], Fourier-transform infrared (FT-IR) spectroscopy [14], GPC-IR-5 [15] methods to measure the SCB distributions. On the other hand, tradi-tional LCB determinations methods are also in practice, for example, rheology [16,17], NMR [18], high temperature-size exclusion chromatography (HT-SEC) with triple detectors (DRI/Visco/RALS/LALS) [19,20], SEC-multiangle light-scattering (SEC-MALS) [21,22], SEC-MALS/VISCO [23,24], SEC-IR-VISCO-MALS [25], or combination of 13 C NMR and SEC methods to quantify the LCB/SCB in LDPE resin [26].…”

Section: Introductionmentioning

confidence: 99%

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High temperature‐size exclusion chromatography with triple detection to assess the molecular architecture of low‐density polyethylene: Insight into branching and processability correlations

Subbaiah,

Shanmugam,

Hau

2024

J of Separation Science

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In this study, three commercially available low‐density polyethylene (LDPE) polymers produced via a tubular reactor process, with varying melt flow rates at 190°C/2.16 kg (4.0, 1.9, and 0.75 g/10 min), have been selected and subjected to high temperature‐size exclusion chromatography (SEC) analysis coupled with an infrared‐5 (IR‐5), viscometer (VISCO), and multiangle laser light‐scattering detectors. The molecular weight (MW), MW distribution, short‐chain branching (SCB), and long‐chain branching parameters were investigated. It was found that MW obtained by the universal technique (∼1.57–1.7 times) and multiangle laser light‐scattering detection technique is (∼1.43–1.55 times) higher than that of the conventional calibration technique, which could be attributed to structural complexity associated with LDPEs which is not clearly understood by conventional SEC mode alone. The bulk SCB per 1000 total carbon atoms estimated by IR‐5 detection was found to range from 16.50 to 17.80. On the other hand, long chain branching frequency per 1000 total carbon atoms obtained by online VISCO and multiangle laser light‐scattering detection ranged from 0.46 to 0.54 and 0.65 to 0.94, respectively. Further, the significance of long chain branching parameters on the polymer processing behavior was studied in correlation with rheological property (Die swell ratio).

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

High temperature‐size exclusion chromatography with triple detection to assess the molecular architecture of low‐density polyethylene: Insight into branching and processability correlations

Subbaiah,

Shanmugam,

Hau

2024

J of Separation Science

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Development of an Integrated On‐Line 2D Analytical TREF‐High Throughput SEC Technique for Polyolefins Characterization

Hildebrand

2020

Macromolecular Symposia

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Complete polymer compositional information of polyolefins is critically valuable in understanding the polymer structure-processing-property relationship, thus helping tailor-design polymers with desired end-use properties. In this paper, a robust on-line 2D analytical TREF combined with high-throughput SEC technique (2D aTREF-hSEC) is described that can rapidly determine the bivariate distribution of chemical composition and molecular weight of polyethylene resins. Unlike Nakano and Goto's pioneering cross fractionation apparatus and the commercial CFC instrument, this 2D aTREF-hSEC system has the following unique characteristics: First of all, the GPC injection volume is not limited by the dead volume of the full TREF column. It can be set at any desired values to ensure optimized separation in SEC. Second, the flow rates for the TREF and SEC unit are independently controlled, which add operational flexibility and help optimize the separation efficiency in both the TREF and the SEC dimension. Third, the 2D aTREF-hSEC system runs continuously instead of stepwise. Once started, the TREF column elutes continuously without stopping to wait for the completion of downstream SEC elution before the next SEC injection, increasing the resolution in TREF dimension. Fourth, experimental time is significantly reduced thanks to the employment of high throughput SEC column. And finally, this 2D aTREF-hSEC technique in principle can be applied equally well to characterize other semi-crystalline polymers and potentially any polymers whose solubility is a function of temperature.

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Modeling of the molecular weight distribution and short chain branching distribution of linear low-density polyethylene from a pilot scale gas phase polymerization process

Feng

Chen

et al. 2022

Chemical Engineering Science

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A Short‐Chain Branching Distribution Determination Technique for Polyethylene Using IR5‐Detected GPC

Cited by 4 publications

References 12 publications

High temperature‐size exclusion chromatography with triple detection to assess the molecular architecture of low‐density polyethylene: Insight into branching and processability correlations

High temperature‐size exclusion chromatography with triple detection to assess the molecular architecture of low‐density polyethylene: Insight into branching and processability correlations

Development of an Integrated On‐Line 2D Analytical TREF‐High Throughput SEC Technique for Polyolefins Characterization

Modeling of the molecular weight distribution and short chain branching distribution of linear low-density polyethylene from a pilot scale gas phase polymerization process

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