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Accurate DSC measurement of the phase transition temperature in the TBPB–water system

Lin, W., Dalmazzone, D., F¨¹rst, W., Delahaye, A., Fournaison, L. and Clain, P.
2013
The Journal of Chemical Thermodynamics, Volume 61, June 2013, Pages 132-137
DSC; Phase equilibrium temperature; Semi-clathrate hydrate; Tetra-n-butylphosphonium bromide (TBPB)


Lin, W., Dalmazzone, D., F¨¹rst, W., Delahaye, A., Fournaison, L. and Clain, P., (2013), "Accurate DSC measurement of the phase transition temperature in the TBPB–water system", The Journal of Chemical Thermodynamics, Volume 61, June 2013, Pages 132-137.
Abstract:
There is some disagreement in the literature on the phase transition temperatures of salt semi-clathrates, which melt incongruently due to the change of salt concentration in the liquid phase. By using differential scanning calorimetry (DSC), the phase transition temperatures of tetrabutylphosphonium bromide (TBPB) hydrates were investigated at 0.10 < wTBPB < 0.37 and atmospheric pressure. The freezing point of ice with the presence of NaCl was also studied as a reference. In this work, two DSC procedures were employed: dynamic and stepwise schemes, characterized by the maximum peak temperature Tpeak and inflection point temperature Tend, and final step temperature Tstep, respectively. The stepwise DSC scheme was validated by the measurement of the ice freezing point at wNaCl = 0.10, 0.15 and 0.18. For the dynamic scheme, we developed and tested a method to estimate the melting temperature of TBPB hydrates. This method, though having a higher uncertainty, was more efficient than the stepwise scheme. The phase transition temperatures of TBPB hydrates are presented with the accuracy of 0.1 K and compared with literature data.

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Author Information and Other Publications Notes
Lin, W.
Aerosol Research and Exposure Assessment Laboratory, Department of Environmental Health, University of Cincinnati, Cincinnati, 0H45267-0056, USA
  1. Development of aerosol number samplers using foam filters
  2. Effect of sampling time and flow rates on the bioefficiency of three fungal spore sampling methods  
Dalmazzone, D.
     
F¨¹rst, W.
     
Delahaye, A.
     
Fournaison, L.
     
Clain, P.
     



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