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Administrative data

Link to relevant study record(s)

Reference

Endpoint:

vapour pressure

Type of information:

experimental study

Adequacy of study:

key study

Study period:

From December 13, 2018 to December 20, 2018

Reliability:

1 (reliable without restriction)

Rationale for reliability incl. deficiencies:

guideline study

Qualifier:

according to guideline

Guideline:

OECD Guideline 104 (Vapour Pressure Curve)

Deviations:

no

Qualifier:

according to guideline

Guideline:

EU Method A.4 (Vapour Pressure)

Deviations:

no

GLP compliance:

yes

Type of method:

effusion method: vapour pressure balance

Key result

Test no.:

#1

Temp.:

ca. 25 °C

Vapour pressure:

ca. 0.008 Pa

Results

Recorded temperatures, mass differences and the resulting calculated values of vapor pressure are shown in the following tables:

 

Run 1

 

Table1– Vapor Pressure Data

Temperature (ºC)		Temperature (K)		Reciprocal Temperature (K-1)		Mass Difference (µg)		Mass Difference (kg)		Vapor Pressure (Pa)		Log10Vp
35		308.15		0.003245		4.26		4.260e-09		0.00591		-2.22841
36		309.15		0.003235		5.14		5.140e-09		0.00714		-2.14630
37		310.15		0.003224		3.21		3.210e-09		0.00446		-2.35067
38		311.15		0.003214		4.00		4.000e-09		0.00555		-2.25571
39		312.15		0.003204		4.81		4.810e-09		0.00668		-2.17522
40		313.15		0.003193		4.36		4.360e-09		0.00605		-2.21824
41		314.15		0.003183		6.36		6.360e-09		0.00883		-2.05404
42		315.15		0.003173		7.47		7.470e-09		0.01037		-1.98422
43		316.15		0.003163		8.67		8.670e-09		0.01204		-1.91937
44		317.15		0.003153		8.56		8.560e-09		0.01188		-1.92518
45		318.15		0.003143		10.07		1.007e-08		0.01398		-1.85449

A plot of Log₁₀(vapor pressure (Pa)) versus reciprocal temperature (1/T(K)) for Run 1 gives the following statistical data using an unweighted least squares treatment (For graph run, kindly refer to the attached background material section of the IUCLID).

Slope:		-4.17 x 103
Standard error in slope:		788
Intercept:		11.2
Standard error in intercept:		2.52

The results obtained indicate the following vapor pressure relationship:

Log₁₀(Vp (Pa)) = -4.17 x 10³/temp(K) + 11.2

The above yields a vapor pressure (Pa) at 298.15 K with a common logarithm of -2.77.

 

Run 2

 

Table2– Vapor Pressure Data

Temperature (ºC)		Temperature (K)		Reciprocal Temperature (K-1)		Mass Difference (µg)		Mass Difference (kg)		Vapor Pressure (Pa)		Log10Vp
35		308.15		0.003245		4.79		4.790e-09		0.00665		-2.17718
36		309.15		0.003235		4.79		4.790e-09		0.00665		-2.17718
37		310.15		0.003224		4.28		4.280e-09		0.00594		-2.22621
38		311.15		0.003214		4.37		4.370e-09		0.00607		-2.21681
39		312.15		0.003204		5.82		5.820e-09		0.00808		-2.09259
40		313.15		0.003193		5.05		5.050e-09		0.00701		-2.15428
41		314.15		0.003183		6.74		6.740e-09		0.00936		-2.02872
42		315.15		0.003173		6.47		6.470e-09		0.00898		-2.04672
43		316.15		0.003163		8.11		8.110e-09		0.01126		-1.94846
44		317.15		0.003153		8.20		8.200e-09		0.01138		-1.94386
45		318.15		0.003143		9.50		9.500e-09		0.01319		-1.87976

A plot of Log₁₀(vapor pressure (Pa)) versus reciprocal temperature (1/T(K)) for Run 2 gives the following statistical data using an unweighted least squares treatment (For graph run, kindly refer to the attached background material section of the IUCLID).

Slope:		-3.24 x 103
Standard error in slope:		477
Intercept:		8.28
Standard error in intercept:		1.52

The results obtained indicate the following vapor pressure relationship:

Log₁₀(Vp (Pa)) = -3.24 x 10³/temp(K) + 8.28

 

The above yields a vapor pressure (Pa) at 298.15 K with a common logarithm of -2.60.

 

Run 3

 

Table3– Vapor Pressure Data

Temperature (ºC)		Temperature (K)		Reciprocal Temperature (K-1)		Mass Difference (µg)		Mass Difference (kg)		Vapor Pressure (Pa)		Log10Vp
35		308.15		0.003245		4.36		4.360e-09		0.00605		-2.21824
36		309.15		0.003235		3.33		3.330e-09		0.00462		-2.33536
37		310.15		0.003224		3.41		3.410e-09		0.00473		-2.32514
38		311.15		0.003214		4.78		4.780e-09		0.00664		-2.17783
39		312.15		0.003204		5.34		5.340e-09		0.00741		-2.13018
40		313.15		0.003193		4.79		4.790e-09		0.00665		-2.17718
41		314.15		0.003183		6.44		6.440e-09		0.00894		-2.04866
42		315.15		0.003173		6.38		6.380e-09		0.00886		-2.05257
43		316.15		0.003163		8.67		8.670e-09		0.01204		-1.91937
44		317.15		0.003153		9.14		9.140e-09		0.01269		-1.89654
45		318.15		0.003143		9.66		9.660e-09		0.01341		-1.87257

A plot of Log₁₀(vapor pressure (Pa)) versus reciprocal temperature (1/T(K)) for Run 3 gives the following statistical data using an unweighted least squares treatment (For graph run, kindly refer to the attached background material section of the IUCLID).

Slope:		-4.47 x 103
Standard error in slope:		573
Intercept:		12.2
Standard error in intercept:		1.83

The results obtained indicate the following vapor pressure relationship:

Log₁₀(Vp (Pa)) = -4.47 x 10³/temp(K) + 12.2

 

The above yields a vapor pressure (Pa) at 298.15 K with a common logarithm of -2.82.

Run 4

 

Table4– Vapor Pressure Data

Temperature (ºC)		Temperature (K)		Reciprocal Temperature (K-1)		Mass Difference (µg)		Mass Difference (kg)		Vapor Pressure (Pa)		Log10Vp
35		308.15		0.003245		3.18		3.180e-09		0.00441		-2.35556
36		309.15		0.003235		4.29		4.290e-09		0.00596		-2.22475
37		310.15		0.003224		3.84		3.840e-09		0.00533		-2.27327
38		311.15		0.003214		4.25		4.250e-09		0.00590		-2.22915
39		312.15		0.003204		4.87		4.870e-09		0.00676		-2.17005
40		313.15		0.003193		5.63		5.630e-09		0.00782		-2.10679
41		314.15		0.003183		6.04		6.040e-09		0.00839		-2.07624
42		315.15		0.003173		6.13		6.130e-09		0.00851		-2.07007
43		316.15		0.003163		7.59		7.590e-09		0.01054		-1.97716
44		317.15		0.003153		8.67		8.670e-09		0.01204		-1.91937
45		318.15		0.003143		8.99		8.990e-09		0.01248		-1.90379

A plot of Log₁₀(vapor pressure (Pa)) versus reciprocal temperature (1/T(K)) for Run 4 gives the following statistical data using an unweighted least squares treatment (For graph run, kindly refer to the attached background material section of the IUCLID).

Slope:		-4.25 x 103
Standard error in slope:		294
Intercept:		11.5
Standard error in intercept:		0.939

The results obtained indicate the following vapor pressure relationship:

Log₁₀(Vp (Pa)) = -4.25 x 10³/temp(K) + 11.5

 

The above yields a vapor pressure (Pa) at 298.15 K with a common logarithm of -2.80.

 

Run 5

Table5– Vapor Pressure Data

Temperature (ºC)		Temperature (K)		Reciprocal Temperature (K-1)		Mass Difference (µg)		Mass Difference (kg)		Vapor Pressure (Pa)		Log10Vp
35		308.15		0.003245		3.71		3.710e-09		0.00515		-2.28819
36		309.15		0.003235		4.06		4.060e-09		0.00564		-2.24872
37		310.15		0.003224		3.98		3.980e-09		0.00553		-2.25727
38		311.15		0.003214		4.03		4.030e-09		0.00559		-2.25259
39		312.15		0.003204		3.99		3.990e-09		0.00554		-2.25649
40		313.15		0.003193		5.49		5.490e-09		0.00762		-2.11805
41		314.15		0.003183		5.11		5.110e-09		0.00709		-2.14935
42		315.15		0.003173		6.46		6.460e-09		0.00897		-2.04721
43		316.15		0.003163		7.71		7.710e-09		0.01070		-1.97062
44		317.15		0.003153		7.58		7.580e-09		0.01052		-1.97798
45		318.15		0.003143		9.13		9.130e-09		0.01267		-1.89722

A plot of Log₁₀(vapor pressure (Pa)) versus reciprocal temperature (1/T(K)) for Run 5 gives the following statistical data using an unweighted least squares treatment (For graph run, kindly refer to the attached background material section of the IUCLID).

Slope:		-3.92 x 103
Standard error in slope:		434
Intercept:		10.4
Standard error in intercept:		1.39

The results obtained indicate the following vapor pressure relationship:

Log₁₀(Vp (Pa)) = -3.92 x 10³/temp(K) + 10.4

 

The above yields a vapor pressure (Pa) at 298.15 K with a common logarithm of -2.76.

 

Run 6

 

Table6– Vapor Pressure Data

Temperature (ºC)		Temperature (K)		Reciprocal Temperature (K-1)		Mass Difference (µg)		Mass Difference (kg)		Vapor Pressure (Pa)		Log10Vp
35		308.15		0.003245		3.64		3.640e-09		0.00505		-2.29671
36		309.15		0.003235		4.09		4.090e-09		0.00568		-2.24565
37		310.15		0.003224		3.66		3.660e-09		0.00508		-2.29414
38		311.15		0.003214		4.46		4.460e-09		0.00619		-2.20831
39		312.15		0.003204		4.11		4.110e-09		0.00571		-2.24336
40		313.15		0.003193		5.42		5.420e-09		0.00752		-2.12378
41		314.15		0.003183		5.73		5.730e-09		0.00795		-2.09963
42		315.15		0.003173		5.74		5.740e-09		0.00797		-2.09854
43		316.15		0.003163		5.97		5.970e-09		0.00829		-2.08145
44		317.15		0.003153		8.17		8.170e-09		0.01134		-1.94539
45		318.15		0.003143		8.89		8.890e-09		0.01234		-1.90868

A plot of Log₁₀(vapor pressure (Pa)) versus reciprocal temperature (1/T(K)) for Run 6 gives the following statistical data using an unweighted least squares treatment (For graph run, kindly refer to the attached background material section of the IUCLID).

Slope:		-3.68 x 103
Standard error in slope:		414
Intercept:		9.61
Standard error in intercept:		1.32

 

The results obtained indicate the following vapor pressure relationship:

Log₁₀(Vp (Pa)) = -3.68 x 10³/temp(K) + 9.61

 

The above yields a vapor pressure (Pa) at 298.15 K with a common logarithm of -2.73.

 

Run 7

 

Table7– Vapor Pressure Data

Temperature (ºC)		Temperature (K)		Reciprocal Temperature (K-1)		Mass Difference (µg)		Mass Difference (kg)		Vapor Pressure (Pa)		Log10Vp
35		308.15		0.003245		3.97		3.970e-09		0.00551		-2.25885
36		309.15		0.003235		4.03		4.030e-09		0.00559		-2.25259
37		310.15		0.003224		3.74		3.740e-09		0.00519		-2.28483
38		311.15		0.003214		4.33		4.330e-09		0.00601		-2.22113
39		312.15		0.003204		4.14		4.140e-09		0.00575		-2.24033
40		313.15		0.003193		4.91		4.910e-09		0.00682		-2.16622
41		314.15		0.003183		5.29		5.290e-09		0.00734		-2.13430
42		315.15		0.003173		6.69		6.690e-09		0.00929		-2.03198
43		316.15		0.003163		7.01		7.010e-09		0.00973		-2.01189
44		317.15		0.003153		8.59		8.590e-09		0.01193		-1.92336
45		318.15		0.003143		7.14		7.140e-09		0.00991		-2.00393

A plot of Log₁₀(vapor pressure (Pa)) versus reciprocal temperature (1/T(K)) for Run 7 gives the following statistical data using an unweighted least squares treatment (For graph run, kindly refer to the attached background material section of the IUCLID).

Slope:		-3.46 x 103
Standard error in slope:		452
Intercept:		8.91
Standard error in intercept:		1.45

 

The results obtained indicate the following vapor pressure relationship:

Log₁₀(Vp (Pa)) = -3.46 x 10³/temp(K) + 8.91

 

The above yields a vapor pressure (Pa) at 298.15 K with a common logarithm of -2.69.

The values of vapor pressure at 25 °C, extrapolated from each graph, are summarized in the following table:

Table 8 Summary of Vapor Pressure Data

Run		Log10[Vp(25 ºC)]
1		-2.07
2		-2.09
3		-2.08
4		-2.11
5		-2.11
6		-2.12
7		-2.12
Mean		-2.10
Vapor Pressure		7.93 x 10-3Pa

 

Discussion

The test substance did not change in appearance under the conditions used in the determination. A total of 7 runs were completed for the main sequence. All 7 runs were used as equilibrium had been reached.The results may represent rounded values obtained by calculations based on the exact raw data.

 

Conclusion

The vapor pressure of the test substance has been determined to be 7.9 x 10^-3 Pa at 25 ºC.

Conclusions:

Under the study conditions, the vapour pressure of the test substance was determined to be 7.9 x 10E-3 Pa at 25°C.

Executive summary:

A study was conducted to determine the vapour pressure of the test substance using the vapour pressure balance method, according to OECD Guideline 104 and EU Method A4, in compliance with GLP. A total of 7 runs were completed for the main sequence and all 7 runs were used as equilibrium had been reached. Under the study conditions, the vapour pressure of the test substance was determined to be 7.9 x 10E-3 Pa at 25°C (Ford, 2019).

Description of key information

The vapour pressure of the test substance was determined using the vapour pressure balance method, according to OECD Guideline 104 and EU Method A.4 (Ford, 2019).

Key value for chemical safety assessment

Vapour pressure:

0.008 Pa

at the temperature of:

25 °C

Additional information