Characterization of Physical, Thermal and Spectral Properties of Biofield Treated 2,6-Dichlorophenol

2,6-Dichlorophenol (2,6-DCP) is a compound used for the synthesis of chemicals and pharmaceutical agents. The present work is intended to evaluate the impact of Mr. Trivedi’s biofield energy treatment on physical, thermal and spectral properties of the 2,6-DCP. The control and treated 2,6-DCP were characterized by various analytical techniques such as X-ray diffraction (XRD), differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), Fourier transform infrared (FT-IR) spectroscopy, and ultra violet-visible spectroscopy (UV-vis) analysis. The XRD results showed the increase in crystallite size of treated sample by 28.94% as compared to the control sample. However, the intensity of the XRD peaks of treated 2,6-DCP were diminished as compared to the control sample. The DTA analysis showed a slight increase in melting temperature of the treated sample. Although, the latent heat of fusion of the treated 2,6-DCP was changed substantially by 28% with respect to the control sample. The maximum thermal decomposition temperature (Tmax) of the treated 2,6-DCP was decreased slightly in comparison with the control. The FT-IR analysis showed a shift in C=C stretching peak from 1464?1473 cm-1 in the treated sample as compared to the control sample. However, the UV-vis analysis showed no changes in absorption peaks of treated 2,6-DCP with respect to the control sample. Overall, the result showed a significant effect of biofield energy treatment on the physical, thermal and spectral properties of 2,6-DCP. It is assumed that increase in crystallite size and melting temperature of the biofield energy treated 2,6-DCP could alleviate its reaction rate that might be a good prospect for the synthesis of pharmaceutical compounds.

In summary, the XRD results revealed a decrease in intensity and increase in crystallite size of the treated 2,6-DCP as compared to the control sample. It is hypothesized that biofield treatment could have provided the energy that caused a reduction in dislocation density and increase in crystallite size. The DTA result showed a slight increase in melting temperature of the treated 2,6-DCP as compared to the control. However, TGA and DTG analysis showed no changes in onset temperature and Tmax of the treated sample. The FT-IR analysis showed alterations in wavenumber of C=C group stretching of the treated samples as compared to the control sample. It was presumed that it might be due to the increase in dipole moment of the C=C bond as compared to the control sample. Overall, the result showed the impact of biofield energy treatment on physical, thermal and spectral properties of 2,6-DCP. The increase in crystallite size and minimal increase in melting temperature of the biofield energy treated 2,6-DCP might improve its reaction rate thus, it could be utilized as intermediate for the synthesis of pharmaceutical compounds.