Tunable Dielectric Responses Triggered by Dimensionality Modification in Organic–Inorganic Hybrid Phase Transition Compounds (C₅H₆N)Cd_nCl_2n+1 (n = 1 and 2)

Abstract: Two hybrids (CHN)CdCl (1) and (CHN)CdCl (2) were synthesized by stoichiometric regulation of reactants. 1 with a one-dimensional chain-like structure shows a step-like dielectric anomaly at around 158 K. 2 with a layered structure undergoes a prominent phase transition in the vicinity of 182 K, accompanying obvious dielectric relaxation behavior in a broad temperature range. Systematic characterization, such as differential scanning calorimetry (DSC), single-crystal X-ray diffraction, and dielectric measuremen… Show more

“…), following a slowly increasing slope, while a reverse process appears around 393 K for the cooling run, where the dielectric constant falls from 9.5 to 8.4 (a.u.). Relative to heat response for phase transition, dielectric constant changes is slightly lagged; this dielectric constant switched mode was also reported in other early work , , , , . Besides, similar dielectric variation law also applies to other frequencies, such as 100 kHz (Figure S4).…”

“…Nevertheless, most organic‐inorganic hybrid reversible phase transition materials (OIHPTM) still suffer a few challenges, such as, i) a low phase transition temperature (usually below or in the vicinity of room temperature), however practical applications require higher temperature such as a automatic switch for a mobile phone's baterry, so exploration of switchable materials with high reversible phase transition temperature always is a goal for physicist and chemist;, ii) a single performance, they mainly focused on ferroelectric, switchable dielectric properties, etc. and the other physical properties such as conduct electricity are seldom reported , , .…”

High‐Temperature Reversible Phase Transition and Switchable Dielectric and Semiconductor Properties in a 2D Hybrid [(C₃H₁₂N₂O)CdCl₄]_n

“…), following a slowly increasing slope, while a reverse process appears around 393 K for the cooling run, where the dielectric constant falls from 9.5 to 8.4 (a.u.). Relative to heat response for phase transition, dielectric constant changes is slightly lagged; this dielectric constant switched mode was also reported in other early work , , , , . Besides, similar dielectric variation law also applies to other frequencies, such as 100 kHz (Figure S4).…”

“…Nevertheless, most organic‐inorganic hybrid reversible phase transition materials (OIHPTM) still suffer a few challenges, such as, i) a low phase transition temperature (usually below or in the vicinity of room temperature), however practical applications require higher temperature such as a automatic switch for a mobile phone's baterry, so exploration of switchable materials with high reversible phase transition temperature always is a goal for physicist and chemist;, ii) a single performance, they mainly focused on ferroelectric, switchable dielectric properties, etc. and the other physical properties such as conduct electricity are seldom reported , , .…”

High‐Temperature Reversible Phase Transition and Switchable Dielectric and Semiconductor Properties in a 2D Hybrid [(C₃H₁₂N₂O)CdCl₄]_n

“…Geometry parameters, such as Cd-Cl terminal , Cd-Cl bridging distances and Cd-Cl-Cd angles are comparable to those in other polymeric cadmium chloride structures that comprise (a) vertex-sharing octahedral units (see, for example, Chapuis et al, 1975;Chapuis, 1977;Lu et al, 2013;Sun et al, 2017;Wei, 1987;Willett, 1977;Yu et al, 2009); (b) face-sharing octahedral units (see, for example, Ma et al, 2006;Morosin, 1972;Peral et al, 2000). In the studied structure Cd-Cl terminal bond lengths range from 2.530 (2) Å to 2.656 (2) Å , Cd-Cl bridging bond lengths are in the range 2.6681 (18)-2.7184 (18) Å and Cd trans -Cl-Cd trans angles range between 168.77 (8) and 178.77 (9) (Table 2).…”

Room-temperature ferroelasticity and unusual sequence of phase transitions in the crystal of (N₂H₅)₃[CdCl₅]

“…As an important class of functional materials, compounds with switchable physical properties via optical, electrical, magnetic, or mechanical manipulation are technologically important, because they can be used in a wide range of applications, including switches and memory devices [1][2][3][4][5]. Recently, a great deal of effort in this field has been devoted to the design of molecule-based materials with multiple switching effects of physical properties for potential application in the fields of digital processing, optoelectronic devices, and sensors [6][7][8].…”

Above Room Temperature Reversible Phase Transition Induces Distinct Dielectric and Nonlinear Optical Switching Response Behavior in Crown-Ether-Based Supramolecular Clathrate