Dielectric relaxation study of pyridine-n-propyl alcohol mixture using time domain reflectometry technique

被引:1
作者
Khan, Shakeel K. [1 ]
Khan, Zamir S. [2 ]
Bokhare, Aniket D. [3 ]
Lokhande, Milind P. [3 ]
Kumbharkhane, Ashok C. [4 ]
机构
[1] BS Patel Arts Commerce & Sci Coll, Dept Phys, Pimpalgaon Kale, Maharashtra, India
[2] Anjuman Coll Engn & Technol, Dept Phys, Nagpur 440001, India
[3] GVISH, Dept Phys & Elect, Amravati, India
[4] Swami Ramanand Teerth Marathwada Univ, Sch Phys Sci, Nanded, Maharashtra, India
来源
PHYSICS AND CHEMISTRY OF LIQUIDS | 2025年 / 63卷 / 03期
关键词
Pyridine; static dielectric constant; relaxation time; MOLECULAR INTERACTION; WATER MIXTURES; BINARY-MIXTURES; PERMITTIVITY; SURFACTANTS; BEHAVIOR;
D O I
10.1080/00319104.2024.2420327
中图分类号
O64 [物理化学(理论化学)、化学物理学];
学科分类号
070304 ; 081704 ;
摘要
The Time Domain Reflectometry (TDR) technique was used to analyse the complex permittivity spectra of the Pyridine-n-propyl alcohol mixture across the concentration and temperature range of 10-25 degrees C. The Cole-Davidson model was used to match the Pyridine- n-propyl alcohol complex permittivity spectra. The nonlinear least squares fit approach has been used to obtain the Static dielectric constant (epsilon 0), Relaxation time (tau), Effective Kirkwood correlation factor (geff) Excess permittivity$\left({\varepsilon _0<^>E} \right)$epsilon 0E, Thermodynamic parameters (activation enthalpy and activation entropy), and Bruggeman factor (fB). Furthermore, the analysis of excess characteristics and the Bruggeman factor points towards the presence of hydrogen bonding between the pyridine and n-propyl alcohol molecules.
引用
收藏
页码:424 / 435
页数:12
相关论文
共 34 条
[1]   Complex permittivity spectra of binary pyridine-amide mixtures using time-domain reflectometry [J].
Ahire, S ;
Chaudhari, A ;
Lokhande, M ;
Mehrotra, SC .
JOURNAL OF SOLUTION CHEMISTRY, 1998, 27 (11) :993-1008
[2]   Thermodynamic and Dielectric Properties of Cyclohexanol-Xylene Binary Mixtures Using Dielectric Spectroscopy [J].
Birajdar, S. S. ;
Kumbharkhane, A. C. ;
Hallale, S. N. ;
Hudge, P. G. ;
Suryawanshi, D. B. .
POLYCYCLIC AROMATIC COMPOUNDS, 2023, 43 (02) :1619-1627
[3]   Dielectric relaxation and hydrogen bonding interactions study of aqueous D-sorbitol using time domain reflectometry [J].
Bokhare, Aniket D. ;
Garad, Nitin. P. ;
Lokhande, Milind P. ;
Kumbharkhane, Ashok C. .
PHYSICS AND CHEMISTRY OF LIQUIDS, 2024, 62 (01) :1-8
[4]  
Bruggeman D.A. G., Annalen der Physik, V416, P636, DOI [10.1002/andp.19354160705, DOI 10.1002/ANDP.19354160705]
[5]   The dielectric relaxation of water between 0°C and 35°C [J].
Buchner, R ;
Barthel, J ;
Stauber, J .
CHEMICAL PHYSICS LETTERS, 1999, 306 (1-2) :57-63
[6]   Dielectric relaxation study of pyridine-alcohol mixtures using time domain reflectometry [J].
Chaudhari, A ;
Mehrotra, SC .
MOLECULAR PHYSICS, 2002, 100 (24) :3907-3913
[7]   TIME DOMAIN REFLECTION METHODS FOR DIELECTRIC MEASUREMENTS TO GHZ [J].
COLE, RH ;
BERBERIAN, JG ;
MASHIMO, S ;
CHRYSSIKOS, G ;
BURNS, A ;
TOMBARI, E .
JOURNAL OF APPLIED PHYSICS, 1989, 66 (02) :793-802
[8]   DIELECTRIC RELAXATION IN GLYCERINE [J].
DAVIDSON, DW ;
COLE, RH .
JOURNAL OF CHEMICAL PHYSICS, 1950, 18 (10) :1417-1417
[9]   DIELECTRIC RELAXATION IN GLYCEROL, PROPYLENE GLYCOL, AND NORMAL-PROPANOL [J].
DAVIDSON, DW ;
COLE, RH .
JOURNAL OF CHEMICAL PHYSICS, 1951, 19 (12) :1484-1490
[10]  
Dharmalingam K, 2009, J APPL SCI ENG, V12, P123
1234