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Physical & Chemical properties

Boiling point

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Reference
Endpoint:
boiling point
Type of information:
experimental study
Adequacy of study:
key study
Study period:
15 Oct 2016 to 31 Oct 2016
Reliability:
1 (reliable without restriction)
Rationale for reliability incl. deficiencies:
guideline study
Qualifier:
according to guideline
Guideline:
OECD Guideline 103 (Boiling Point)
Version / remarks:
July 1995
Qualifier:
according to guideline
Guideline:
EU Method A.2 (Boiling Temperature)
Version / remarks:
May 2008
GLP compliance:
yes (incl. QA statement)
Type of method:
differential scanning calorimetry
Atm. press.:
>= 100.2 - <= 102.2 kPa
Decomposition:
yes
Decomp. temp.:
178 °C

RESULTS:

The test substance was determined to decompose from approximately 178 °C (451 K). Decomposition was observed both in air and under a nitrogen atmosphere. Atmospheric pressure: 100.2 to 102.2 kPa.

From comparison of the thermogram profiles obtained from samples analysed using pre-perforated crucible lids (which allow self-pressurisation up to the boiling temperature) and those using manually pierced crucible lids (i.e. an open system), it is possible to evaluate if an observed endotherm originates from a true boiling temperature for the test substance. However in this case, no significant endotherms (beyond the melting of the test substance at approximately 135 °C) were observed before the sample underwent decomposition without any evidence of boiling, irrespective of the crucible lid type employed. Due to the low initial rate of enthalpy change during decomposition, the onset temperature could only be approximated. Due to the variance observed, a limit value has been reported based on the lowest observed onset temperature. The use of manually pierced crucibles (an open system) also provided an opportunity to assess the stability of the test substance in air and in an inert atmosphere (nitrogen). Decomposition was observed both in air and under a nitrogen atmosphere, indicating the process was most likely thermal and not oxidative.

Table 1: Thermographic data – determination 1

 

Thermal Event

 

Interpretation

Temperature

ºC

K

Approximate exotherm onset temperature.

Approximate decomposition step

onset temperature.

 

185.27

 

458

Extrapolated exotherm onset temperature.

Extrapolated decomposition step onset temperature.

 

223.86

 

497

Table 2: Thermographic data – determination 2

 

Thermal Event

 

Interpretation

Temperature

ºC

K

Approximate exotherm onset temperature.

Approximate decomposition step onset temperature.

 

183.30

 

456

Extrapolated exotherm onset temperature.

Extrapolated decomposition step onset temperature.

 

216.22

 

489

Table 3: Thermographic data – determination 3

 

Thermal Event

 

Interpretation

Temperature

ºC

K

Approximate exotherm onset temperature.

Approximate decomposition step onset temperature.

 

188.05

 

461

Extrapolated exotherm onset temperature.

Extrapolated decomposition step onset temperature.

 

226.62

 

500

Table 4: Thermographic data – determination 4

 

Thermal Event

 

Interpretation

Temperature

ºC

K

Approximate exotherm onset temperature.

Approximate decomposition step onset temperature.

 

183.28

 

456

Extrapolated exotherm onset temperature.

Extrapolated decomposition step onset temperature.

 

222.75

 

496

Table 5: Thermographic data – determination 5

 

Thermal Event

 

Interpretation

Temperature

ºC

K

Approximate exotherm onset temperature.

Approximate decomposition step onset temperature.

 

177.65

 

451

Extrapolated exotherm onset temperature.

Extrapolated decomposition step onset temperature.

 

223.44

 

497

Table 6: Thermographic data – determination 6

 

Thermal Event

 

Interpretation

Temperature

ºC

K

Approximate exotherm onset temperature.

Approximate decomposition step onset temperature.

 

185.54

 

459

Extrapolated exotherm onset temperature.

Extrapolated decomposition step onset temperature.

 

225.90

 

499
Conclusions:
The test substance starts to thermally decompose at approximately 178°C, (451 K) at 100.2 to 102.2 kPa, i.e. before the boiling point is reached.
Executive summary:

To determine the boiling temperature of the test substance a study was performed according to OECD 103 and EC Method A.2. in compliance with GLP. Due to thermal decomposition of the test substance at a temperature lower than that of the boiling point, it was not possible to determine the boiling point at normal pressure. Using differential scanning calorimetry it could be determined that thermal decomposition starts at about 178 °C (451 K),both in air and under a nitrogen atmosphere, i.e. before the boiling point was reached.

Description of key information

Substance decomposes before boiling, OECD 103 and EC Method A.2, DSC, O'Connor 2017.

Key value for chemical safety assessment

Additional information