Influence of temperature on the optical properties of zinc tris-thiourea sulfate (ZTS) single crystal

Influence of temperature on the optical properties of zinc tris-thiourea sulfate (ZTS) single crystal

► I study the effect of temperature on the optical properties of ZTS single crystal. ► Increasing temperature will decrease the optical energy gap. ► In the region of absorption edge, the absorption coefficient obeys Urbach’s rule. ► Increasing temperature will increase the Urbach tail energy. ► Tem...

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Bibliographic Details
Published in:Optical materials Vol. 35; no. 2; pp. 146 - 154
Main Author: Abdulwahab, A.M.
Format: Journal Article
Language:English
Published: Oxford Elsevier B.V 01-12-2012
Elsevier
Subjects:
Exact sciences and technology
Ferroelectric materials
Ferroelectricity
Fundamental areas of phenomenology (including applications)
Optical energy gap
Optical materials
Optical properties
Optics
Phase transformations
Phase transition
Physics
Polymers and organics
Sulfates
Two phase
Urbach’s rule
Wavelengths
Zinc
ZTS crystals
ZTS crystals
Optical energy gap
Urbach’s rule
Phase transition
Temperature dependence
Organic ligand
Zinc complexes
Sulfates
Absorption coefficients
Transmittance
Monocrystals
Ambient temperature
Optical properties
Visible radiation
Urbach's rule
Thiourea
Optical materials
Urbach rule
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Summary:► I study the effect of temperature on the optical properties of ZTS single crystal. ► Increasing temperature will decrease the optical energy gap. ► In the region of absorption edge, the absorption coefficient obeys Urbach’s rule. ► Increasing temperature will increase the Urbach tail energy. ► Temperature dependence relations have anomalies at the phase transition (323K). Single crystal of zinc tris-thiourea sulfate (ZTS) was synthesized and grown by the slow evaporation technique at 315K. The effect of temperature on the optical properties of ZTS crystal was studied in the temperature range 293–338K. This range involves the first-order phase transition temperature from ferroelectric to paraelectric phase (323K). At room temperature (293K), the optical transmittance (T) has high values in the completely visible wavelength range. The cut off wavelength equals to 278.5nm at room temperature. By increasing temperature, the optical transmittance decreases, however the cut off shifts to higher wavelengths. These changes have different rates in the two phases (ferroelectric and paraelectric). Analysis reveals that the type of transition is the direct allowed one. The optical energy gap (Eg) has the value of 3.89eV at room temperature. This value decreases linearly with increasing temperature by different rates in the two phases. In the region of the absorption edge, the absorption coefficient obeys Urbach’s rule, and Urbach parameters were calculated. The Urbach tail energy (Ee), which equals to 1.024eV at room temperature, increases linearly with increasing temperature. This change has different rates in the two phases. At room temperature, the steepness parameter (σ) has the value of 24.697×10−3. It decreases linearly with increasing [1/(Temp.)2] by different rates in the two phases. For all studied parameters, the temperature dependence relations change considerably while passing through 323K. This anomalous behavior confirms that the transition from ferroelectric to paraelectric phase occurs at this temperature.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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content type line 23
ISSN:0925-3467
1873-1252
DOI:10.1016/j.optmat.2012.07.015