Coordination Polymers for Nanoelectronics

Gómez-Herrero, Júlio; Zamora, Félix

doi:10.1002/adma.201101952

Cited by 49 publications

(40 citation statements)

References 24 publications

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“…It is highly dispersive in energy, thereby giving a very low effective hole mass (i.e., very good conduction properties). This result confirms that this class of coordination polymer is very promising for use in nanoscale electronic devices 16a. Notably, the parent [Pt 2 (RCS 2 ) 4 I] n MMX polymers, which were recently investigated by using the same DFT approach,10d, 21 exhibit metallic behaviour.…”

Section: Resultssupporting

confidence: 75%

“…On-demand technological applications require the development of molecular wires with versatile electrical behaviour across long distances. [15,16] Furthermore, the possibility of modulating the intrinsic electronic nature of selected bimetallic subunits may be exploited in the formation of molecular wires with controlled electrical properties. One way to pursue these goals involves tuning the electronic properties of the bimetallic entity.…”

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confidence: 99%

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Electrical Behaviour of Heterobimetallic [MM′(EtCS₂)₄] (MM′=NiPd, NiPt, PdPt) and MM′X‐Chain Polymers [PtM(EtCS₂)₄I] (M=Ni, Pd)

Givaja

Castillo

Mateo

et al. 2012

Chemistry A European J

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Herein, we report the isolation of new heterobimetallic complexes [Ni(0.6)Pd(1.4)(EtCS(2))(4)] (1), [NiPt(EtCS(2))(4)] (2) and [Pd(0.4)Pt(1.6)(EtCS(2))(4)] (3), which were constructed by using transmetallation procedures. Subsequent oxidation with iodine furnished the MM'X monodimensional chains [Ni(0.6)Pt(1.4)(EtCS(2))(4)I] (4) and [Ni(0.1)Pd(0.3)Pt(1.6)(EtCS(2))(4)I] (5). The physical properties of these systems were investigated and the chain structures 4 and 5 were found to be reminiscent of the parent [Pt(2)(EtCS(2))(4)I] species. However, they were more sensitively dependent on the localised nature of the charge on the Ni ion, which caused spontaneous breaking of the conduction bands.

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Section: Resultssupporting

confidence: 75%

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confidence: 99%

Electrical Behaviour of Heterobimetallic [MM′(EtCS₂)₄] (MM′=NiPd, NiPt, PdPt) and MM′X‐Chain Polymers [PtM(EtCS₂)₄I] (M=Ni, Pd)

Givaja

Castillo

Mateo

et al. 2012

Chemistry A European J

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“…This change implies a slight change of the interplanar distances from 6.146 Å for compound 4 to 6.173 Å for 6 . A similar trend between the solvent molecules and the interplanar distance is observed in an analogous family containing chloride anions 11,12…”

Section: Resultssupporting

confidence: 73%

Reversible Solvent‐Exchange‐Driven Transformations in Multifunctional Coordination Polymers Based on Copper‐Containing Organosulfur Ligands

et al. 2014

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The preparation by simple direct synthesis of a series of coordination polymers based on copper with chloride or bromide and dipyrimidinedisulfide is reported. The structural characterisations of these compounds reveal a rich structural variety as a result of the number of coordination modes available to the organosulfur ligand, in combination with the bridging capabilities of the halides. Interestingly, some of the polymers displayed fully reversible solvent exchange/removal crystal‐to‐crystal 2D to 0D and 2D to 2D transformations. These materials show multifunctional electronic properties. Thus, some of them are semiconductors and present weak antiferromagnetic interactions, and the CuI/CuII coordination polymers present coexistence of paramagnetism with weak red emission. These compounds present some of the lowest NIR energy luminescence in d10 transition‐metal complexes.

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“…[12] MMX chains are therefore promising candidates for nanoelectronic applications in which molecular wires that can transport electrical charges across long distances are required. [10,13] Furthermore, the relatively low work function (ca. 3.7 eV) [14] and the fact that thin films of MMX are almost transparent for thicknesses lower than 50 nm make this class of structure extremely appealing for molecular electronics and optoelectronics.…”

Section: Introductionmentioning

confidence: 99%

The Isolation of Single MMX Chains from Solution: Unravelling the Assembly–Disassembly Process

Azani

Paz

Hermosa

et al. 2013

Chemistry A European J

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Herein, we provide a systematic theoretical and experimental study of the structural and optical properties of MMX (M=metal, X=halide) chains. The influence of solvent, temperature, and concentration has been analyzed to find suitable parameters for initial building-block associations in solution. By using density functional calculations, we have computed the dissociation energy of different MMX oligomers (up to the tetramer) in the gas phase. On the basis of these findings, we discuss the most likely disassembly scenario and propose a new interpretation of these compounds. We also calculated the charge redistribution that occurs upon MM+XMMX binding in vacuum. Time-dependent density functional theory (TDDFT) is used to calculate the UV/visible spectra of different MMX chains up to the tetramer in the gas phase. The implications of these theoretical findings in the analysis of our experiments are discussed in the text. The overall body of data presented suggests a new way of looking at such linear structures. By taking into account these new data, we have been able to isolate single/few MMX chains on mica.

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Coordination Polymers for Nanoelectronics

Cited by 49 publications

References 24 publications

Electrical Behaviour of Heterobimetallic [MM′(EtCS₂)₄] (MM′=NiPd, NiPt, PdPt) and MM′X‐Chain Polymers [PtM(EtCS₂)₄I] (M=Ni, Pd)

Electrical Behaviour of Heterobimetallic [MM′(EtCS₂)₄] (MM′=NiPd, NiPt, PdPt) and MM′X‐Chain Polymers [PtM(EtCS₂)₄I] (M=Ni, Pd)

Reversible Solvent‐Exchange‐Driven Transformations in Multifunctional Coordination Polymers Based on Copper‐Containing Organosulfur Ligands

The Isolation of Single MMX Chains from Solution: Unravelling the Assembly–Disassembly Process

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Coordination Polymers for Nanoelectronics

Cited by 49 publications

References 24 publications

Electrical Behaviour of Heterobimetallic [MM′(EtCS2)4] (MM′=NiPd, NiPt, PdPt) and MM′X‐Chain Polymers [PtM(EtCS2)4I] (M=Ni, Pd)

Electrical Behaviour of Heterobimetallic [MM′(EtCS2)4] (MM′=NiPd, NiPt, PdPt) and MM′X‐Chain Polymers [PtM(EtCS2)4I] (M=Ni, Pd)

Reversible Solvent‐Exchange‐Driven Transformations in Multifunctional Coordination Polymers Based on Copper‐Containing Organosulfur Ligands

The Isolation of Single MMX Chains from Solution: Unravelling the Assembly–Disassembly Process

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Electrical Behaviour of Heterobimetallic [MM′(EtCS₂)₄] (MM′=NiPd, NiPt, PdPt) and MM′X‐Chain Polymers [PtM(EtCS₂)₄I] (M=Ni, Pd)

Electrical Behaviour of Heterobimetallic [MM′(EtCS₂)₄] (MM′=NiPd, NiPt, PdPt) and MM′X‐Chain Polymers [PtM(EtCS₂)₄I] (M=Ni, Pd)