Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄

Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄

The isochoric thermal conductivity of solid n-hexane C₆H₁₄ has been investigated on three samples of different density in the temperature interval from 100 K to the onset of melting. In all the cases the isochoric thermal conductivity varied following a dependence which is weaker than Λ ∝ 1/Т. The r...

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Date:2011
Main Authors: Konstantinov, V.A., Revyakin, V.P., Sagan, V.V.
Format: Article
Language:English
Published: Фізико-технічний інститут низьких температур ім. Б.І. Вєркіна НАН України 2011
Series:Физика низких температур
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8th International Conference on Cryocrystals and Quantum Crystals
Online Access:https://nasplib.isofts.kiev.ua/handle/123456789/118549
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Cite this:Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄ / V.A. Konstantinov, V.P. Revyakin, V.V. Sagan // Физика низких температур. — 2011. — Т. 37, № 5. — С. 531-534. — Бібліогр.: 17 назв. — англ.

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spelling nasplib_isofts_kiev_ua-123456789-1185492025-02-23T19:25:09Z Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄ Konstantinov, V.A. Revyakin, V.P. Sagan, V.V. 8th International Conference on Cryocrystals and Quantum Crystals The isochoric thermal conductivity of solid n-hexane C₆H₁₄ has been investigated on three samples of different density in the temperature interval from 100 K to the onset of melting. In all the cases the isochoric thermal conductivity varied following a dependence which is weaker than Λ ∝ 1/Т. The results obtained are compared with the thermal conductivities of other representatives of n-alkanes. The contributions of low-frequency phonons and “diffuse modes” to the thermal conductivity are calculated. 2011 Article Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄ / V.A. Konstantinov, V.P. Revyakin, V.V. Sagan // Физика низких температур. — 2011. — Т. 37, № 5. — С. 531-534. — Бібліогр.: 17 назв. — англ. 0132-6414 PACS: 66.70.–f https://nasplib.isofts.kiev.ua/handle/123456789/118549 en Физика низких температур application/pdf Фізико-технічний інститут низьких температур ім. Б.І. Вєркіна НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
topic 8th International Conference on Cryocrystals and Quantum Crystals
8th International Conference on Cryocrystals and Quantum Crystals
spellingShingle 8th International Conference on Cryocrystals and Quantum Crystals
8th International Conference on Cryocrystals and Quantum Crystals
Konstantinov, V.A.
Revyakin, V.P.
Sagan, V.V.
Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄
Физика низких температур
description The isochoric thermal conductivity of solid n-hexane C₆H₁₄ has been investigated on three samples of different density in the temperature interval from 100 K to the onset of melting. In all the cases the isochoric thermal conductivity varied following a dependence which is weaker than Λ ∝ 1/Т. The results obtained are compared with the thermal conductivities of other representatives of n-alkanes. The contributions of low-frequency phonons and “diffuse modes” to the thermal conductivity are calculated.
format Article
author Konstantinov, V.A.
Revyakin, V.P.
Sagan, V.V.
author_facet Konstantinov, V.A.
Revyakin, V.P.
Sagan, V.V.
author_sort Konstantinov, V.A.
title Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄
title_short Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄
title_full Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄
title_fullStr Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄
title_full_unstemmed Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄
title_sort isochoric thermal conductivity of solid n-alkanes: hexane c₆h₁₄
publisher Фізико-технічний інститут низьких температур ім. Б.І. Вєркіна НАН України
publishDate 2011
topic_facet 8th International Conference on Cryocrystals and Quantum Crystals
url https://nasplib.isofts.kiev.ua/handle/123456789/118549
citation_txt Isochoric thermal conductivity of solid n-alkanes: hexane C₆H₁₄ / V.A. Konstantinov, V.P. Revyakin, V.V. Sagan // Физика низких температур. — 2011. — Т. 37, № 5. — С. 531-534. — Бібліогр.: 17 назв. — англ.
series Физика низких температур
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fulltext © V.A. Konstantinov, V.P. Revyakin, and V.V. Sagan, 2011 Fizika Nizkikh Temperatur, 2011, v. 37, No. 5, p. 531–534 Isochoric thermal conductivity of solid n-alkanes: hexane C6H14 V.A. Konstantinov, V.P. Revyakin, and V.V. Sagan B. Verkin Institute for Low Temperature Physics and Engineering of the National Academy of Sciences of Ukraine 47 Lenin Ave., Kharkov 61103, Ukraine E-mail: konstantinov@ilt.kharkov.ua Received December 10, 2010 The isochoric thermal conductivity of solid n-hexane C6H14 has been investigated on three samples of differ- ent density in the temperature interval from 100 K to the onset of melting. In all the cases the isochoric thermal conductivity varied following a dependence which is weaker than Λ ∝ 1/Т. The results obtained are compared with the thermal conductivities of other representatives of n-alkanes. The contributions of low-frequency pho- nons and “diffuse modes” to the thermal conductivity are calculated. PACS: 66.70.–f Nonelectronic thermal conduction and heat-pulse propagation in solids; thermal waves, Keywords: n-alkanes, hexane, isochoric thermal conductivity, phonons, “diffusive” modes. Introduction Normal alkanes (n-paraffins) of the CnH2n+2 type form a class of substances that are intermediate in changing – over to long-chain polymers. N-alkanes have a compara- tively simple structure and a molecular packing: in the so- lid state the axes of all molecules are always parallel to one another irrespective of a particular crystalline modification [1]. Owing to their relative simplicity, normal alkanes are naturally considered as the starting point for understanding the structural and termophysical properties of more com- plex long-chain compounds. N-alkanes exhibit an extremely diverse dynamic behavior both in the solid and liquid states. The melting temperature increases in this series of compounds with the length of the chain and its behavior is nonmonotonic: the n-alkanes with an add number of carbon atoms (odd n-alkanes) melt at comparatively lower temperatures than those with an even number of C atoms (even n-alkanes). An interesting effect is observed when the orthorhombic, monoclinic and triclinic structures alternate with the even and odd members of the series [1–3]. The even n-alkanes with n = 6 – 24 (n = the number of C atoms) crystallize at low temperatures forming a triclinic cell. Heptane (n = 7) and nonane (n = 9) have an orthorhombic structure at low temperatures. Glass-like “ro- tational” phases with hexagonal symmetry were found in rather narrow temperature interval below the melting points of odd n-alkanes starting with n = 9. The region of existence of the “rotational” phase increases with the length of the chain. Hexagonal modifications also occur in even n-alkanes starting with n = 22 [1–4]. Short-chain (n ≤ 6) and “even” n-alkanes are the least studied members of the series. Previously, thermal con- ductivity was investigated only in “odd” n-alkanes with n = 9–19 at constant pressure 30 MPa [5]. We have inves- tigated the isochoric thermal conductivity of methane [6], ethane [7] and propane [8]. Here we report the isochoric thermal conductivity of solid n-hexane (C6H14) measured on samples of various densities in the temperature interval from 100 K to the onset of melting. According to colorimetric data, n-hexane has only one crystallographic modification and melts at Tm = 177.8 K with the entropy of melting ΔSf /R = 8.85 [9]. The crystal structure of n-hexane has been determined by the x-ray method at 90 and 158 K [2,10]. It is triclinic, space group Pī, with one molecule in the unit cell. On elastic neutron scattering [11], the lattice mode peaks occur at 35, 55, 71 and 93 cm–1, which agree well with the Raman scattering data [12] (53, 74 and 87 cm–1). It is found that in n-hexane the lowest intramolecular modes are separated from the lattice modes not so distinctly as in light n-alkanes. The Debye temperature may be evaluated as the upper boun- dary of the lattice modes (∼102 K). Experimental For a correct comparison with theory, the measurement must be made at a constant density of the sample to ex- clude the thermal expansion effect. Constant-volume in- vestigations are possible for molecular solids having com- paratively high compressibility coefficients. Using a high pressure cell, it is possible to grow samples of sufficient density which can be cooled then with practically invaria- V.A. Konstantinov, V.P. Revyakin, and V.V. Sagan 532 Fizika Nizkikh Temperatur, 2011, v. 37, No. 5 Fig. 1. The isochoric thermal conductivity of three solid n-hexane samples of various densities: №1(■), №2 (▲) и №3 (●). Solid lines are smoothed values of isochoric thermal conductivity. Dashed line is the thermal conductivity under atmospheric (zero) pressure. 100 120 140 160 180 200 2 3 4 5 6 7 3 2 1 T, K C H6 14 � � , m W /c m K Fig. 2. Isobaric thermal conductivity of some n-alkanes (this study and [5,7,8]). Data for ethane, propane and hexane corres- pond to zero pressure; thermal conductivity of “odd” n-alkanes with n = 9–19 correspond to pressure 30 MPa. 40 80 120 160 200 240 280 320 2 4 6 8 T, K C H19 40 C H17 36 C H15 32 C H13 28 C H11 24 C H9 20 C H6 14 C H2 6 C H3 8 � � , m W /c m K ble volume whereas the pressure in the cell decreases. As samples of moderate densities are cooled the pressure in the sell drops to zero at a certain characteristic temperature T0 and the isochoric condition is then broken. At and be- low T0 isochoric data turn to isobaric at zero pressure. On further cooling, the sample can separate from the walls of the cell or its continuity can be disturbed. In constant- volume experiments melting occur in a certain temperature interval, and its onset shifts towards higher temperatures as the density of the samples increases. These measurements were made by a steady – state flow heat method in a coaxi- al geometry setup [13]. The samples were grown under different pressures (40–120 MPa), the temperature gradient over the measuring cell being about 1.5 K/cm. As the growth was completed, the capillary was blocked by cool- ing it with liquid nitrogen, and the samples were annealed below melting temperatures for about two hours to remove the density gradients. After the measurements the samples were evaporated into a thin-wall vessel, and the samples masses were determined through weighting. The molar volumes of the samples were found from known volume of the measuring cell and the sample mass. Purity of the C6H14 used was no worse than 99.8%. Results and discussion The experimental results are shown in Fig. 1, which carries the smoothed thermal conductivity of the solid phase (solid lines) and the isobaric (P = 0, MPa) thermal conductivity (dashed line). The thermal conductivities of the samples grown under identical conditions (grown time, pressure and temperature gradient over the measuring cell) coincident within the experimental error, which is evidence of the fine – disperse state of the samples (considerable anisotropy of the thermal conductivity can be expected along and across the plane of the layers). The molar vo- lumes Vm of the samples, the temperatures T0 of the onset of experimental condition V = const, and the temperatures Tm of the onset of melting are given in Table 1. The Bridgman coefficient ( ln / ln )Tg V= − ∂ Λ ∂ was calcu- lated from experimental data to be 7.6 ± 0.6 at T = 178 K. Table 1. Molar volumes Vm of samples, temperatures T0 of the onset of experimental condition V = const, and temperatures Tm of the onset of melting. Number of sample Vm, cm3/mole T0, K Tm, K 1 95.6 116 235 2 96.7 142 210 3 97.3 166 192 The isochoric thermal conductivity of all solid n-hexane samples decreases with increasing temperature following a dependences weaker than Λ ∝ 1/T. A similar behavior was observed previously in the low-temperature phase of ethane [7] and in propane [8]. It was noted previously that the thermal conductivity of long-chain odd n-alkanes (C9H20–C19H40) has some features in common [5]. As the “rotational” phase melts, the thermal conductivity changes by about 35% and is independent of the chain length. The jump of the thermal conductivity on changing to the low temperature ordered phase decreases with the increasing length of the chain and makes ∼85% for n-undecane and ∼40% for n-nonadecane. The absolute value of thermal conductivity increases in the “rotational” phase with the increasing chain length. The isobaric thermal conductivity of some n-alkanes is shown in Fig. 2 (data of this study and [5,7,8] along with the thermal conductivities of the liquid phases of these com- pounds measured immediately after melting [5,14]. Data for ethane, propane and hexane correspond to zero pressure; thermal conductivity of “odd” n-alkanes with n = 9–19 was studied at constant pressure 30 MPa. Some information about structure and thermo physical properties of n-alkanes discussed is also available in Table 2. As noted above, the Isochoric thermal conductivity of solid n-alkanes: hexane C6H14 Fizika Nizkikh Temperatur, 2011, v. 37, No. 5 533 isobaric thermal conductivity exhibits closely similar beha- vior in short and long-chain n-alkanes. On the transition from the ordered phase to a liquid the thermal conductivity of the n-alkanes starting with propane changes nearly twice and is independent of the total entropy of transitions and the chain length. Such change is much smaller in the case of spherical and elliptic molecules: for example, ΔΛ/ΛL is only 20–30% in methane and ethane. This can be related to the higher degree of orientational ordering in solid long-chain n- alkanes as compared to spherical molecules. Table 2. The structure of n-alkanes [2,5,10], the temperature Tα–β and the entropy ΔSα–β/R of the transition to the “rotational” phase, the temperature Tm and the melting entropy ΔSm/R [NIST Standard Reference Data: http://webbook.nist.gov/chemistry/form-ser.html], a complete change of the entropy and variations of thermal conductivity Λα/ΛL during the ordered phase – liquid transition [5,7,8,14]. The deviation of the isochoric thermal conductivity from the dependence Λ∝1/T in the orientationally-ordered phases of molecular crystals can be explained proceeding from the concept of the “lower limit to thermal conductivi- ty” [15,16]. In this case the thermal conductivity can be calculated within the model in which heat is transported by both low-frequency phonons and “diffuse” modes. In sim- ple Debye model the thermal conductivity can be described by the following expression 3 / 4 2 0 e( ) 3 ( ) (e -1) D T x B x D T xT nk l x dx Θ⎛ ⎞ Λ = ⎜ ⎟Θ⎝ ⎠ ∫v (1) where 2 1/3 ( / )(6 ) ,D Bh k nΘ = πv n is the number of atoms (molecules) per unit volume, v is polarization – ave- raged sound velocity, h is Planck constant l(x) is phonon mean-free path. For T ≥ ΘD the phonon mean-free path can be found as 2 2 2 2 2 1( ) B hl x CT k T x = v , (2) where C is a coefficient. Since the mean-free path of the phonons cannot be smaller than the half wavelength l(x) = = aλ/2, where a ≈ 1, the “diffusivity edge” *Θ is * 2 / ,Bh ak CTΘ = v (3) The modes whose mean-free path is aλ/2 are denoted as “diffuse” modes. It is assumed, that * DΘ ≤ Θ otherwise * .DΘ = Θ The thermal conductivity integral can be sub- divided into two parts describing the contributions to ther- mal conductivity from low-frequency phonons Λph and high-frequency “diffuse” modes Λdif: Λ = Λph + Λdif (4) *3 / 4 ph 2 0 e( ) 3 ( ) (e 1) T x B x D T xT nk l x dx Θ⎡ ⎤⎛ ⎞ ⎢ ⎥Λ = ⋅ ⋅⎜ ⎟Θ ⎢ ⎥−⎝ ⎠ ⎣ ⎦ ∫v (5) * 3 / 4 dif 2 / e( ) 3 2 (e 1) D T x B x D BT T h xT nk dx k xT Θ Θ ⎡ ⎤⎛ ⎞ ⎢ ⎥Λ = ⋅ α ⋅⎜ ⎟ ⎢ ⎥Θ −⎝ ⎠ ⎣ ⎦ ∫ vv (6) The lower limit to thermal conductivity Λmin is reached if all vibrating modes have “diffusive” character: l(λ) = aλ/2 and it can be written as 2 /1/3 3 2/3 min 2 0 e3 6 (e 1) D T x B x D T xn k dx Θ⎛ ⎞π⎛ ⎞Λ = α ⎜ ⎟⎜ ⎟ Θ⎝ ⎠ −⎝ ⎠ ∫v . (7) The least-square fitting to the smoothed thermal con- ductivity was performed for the highest-density sample with Vm = 95.6 сm3/mole. Unfortunately, no experimental data on the sound velocity in solid n-hexane are available presently. We therefore used value v = 2.4×103 m/s for liquid n-hexane immediately after melting [17] and varied the parameters C and α. The best agreement with the expe- rimental was achieved with C = 6.8 10–10 сm/K and α = = 1.86. These coefficients C and α are closed to those of ethane and propane (see Table 3). Table 3. The average sound velocity v, and the fitting parame- ters C and α. Substance v×10–5 cm/s C×109 cm/K α C2H6 1.42 1.06 1.84 C3H8 1.95 1.1 2.64 C6H14 2.4 0.68 1.86 Substance Structure Tα–β, K ΔSα–β/R Tm, K ΔSm/R ΔSα–L/R Λα/ΛL C2H6 P21/n, z = 2 89.8 2.74 90.3 0.77 3.6 1.3 C3H8 P21/n, z = 4 - - 85.5 4.95 4.95 2.2 C6H14 Pī, z = 1 - - 177.8 8.85 8.85 1.9 C9H20 Pī, z = 1 217.2 3.48 219.7 8.47 12.0 2.4 C11H24 Pbcn, z = 4 236.6 2.9 247.6 10.8 13.7 2.4 C13H28 Pbcn, z = 4 255.0 3.6 267.8 12.8 16.4 2.3 C15H32 Pbcn, z = 4 270.9 4.1 283.1 14.7 18.8 2.1 C17H36 Pbcn, z = 4 284.3 4.8 295.1 16.4 21.2 2.0 C19H40 Pbcn, z = 4 296.0 5.6 304.0 18.8 24.3 2.0 V.A. Konstantinov, V.P. Revyakin, and V.V. Sagan 534 Fizika Nizkikh Temperatur, 2011, v. 37, No. 5 Fig. 3. The curve fitted to the smoothed experimental thermal conductivity of sample №1 and the calculated contributions to thermal conductivity from low-frequency phonons Λph and “dif- fuse” modes Λdif. The dash–and–dot line is for the lower limit of the lattice thermal conductivity Λmin. 100 120 140 160 180 200 0 1 2 3 4 5 6 �min �dif �ph � T, K � � , m W /c m K The smoothed values of thermal conductivity (dark squares), the fitting curve (solid line) and the contributions of low-frequency phonons Λph and diffuse modes Λdif (dashed lines) are shown in Fig. 3. Here as dot-dashed line is also shown the lower limit to thermal conductivity, calcu- lated according to Eg. (7). It is seen that the “diffuse” beha- vior of the vibrational modes becomes evident at T > 130 K. Up to T = 200 K the contribution of “diffuse” modes is smaller than of phonons, which agrees well with the large jump of thermal conductivity observed on melting. Conclusion The isochoric thermal conductivity of solid n-hexane C6H14 has been investigated on three samples of different density in the temperature interval from 100 K to the onset of melting. In all the cases the isochoric thermal conductiv- ity varied following a dependence which is weaker than Λ ∝ 1/Т. The isobaric thermal conductivity exhibits closely similar behavior in short and long-chain n-alkanes. On the transition from the ordered phase to a liquid the thermal conductivity of the n-alkanes starting with propane changes nearly twice and is independent of the total entro- py of transitions and the chain length. Such change is much smaller in the case of spherical and elliptic molecules. This can be related to the higher degree of orientational ordering in solid n-alkanes as compared to spherical molecules. The contributions of low-frequency phonons Λph and “diffuse modes” Λdif to the thermal conductivity are calculated. Unlike crystals consisting of the globular-shape molecules Λph is smaller than Λdif, which agrees well with the large jump of thermal conductivity observed on melting. 1. A.I. Kitaigoroddkiy, Molecular Crystals (in Russian), Nauka, Moscow (1971). 2. 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B.A. Younglove and J.F. Ely, J. Phys. Chem. Ref. Data, 16, 577 (1987). 15. D.G. Cahill, S.K. Watson, and R.O. Pohl, Phys. Rev. B46, 6131 (1992). 16. V.A. Konstantinov, Low Temp. Phys. 29, 567 (2003) [Fiz. Nizk. Temp. 29, 422 (2003)]. 17. V.K. Sachdeva and V.S. Nanda, J. Chem Phys. 75, 4745 (1981).

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