Abstract:In
this work we report fabrication of high-quality AB- and BA-type
heterostructured thin films of cubic Cu(II) (A-type) and tetragonal
Cu(I) (B-type) coordination polymers (CPs) on the functionalized Au
substrate by the layer-by-layer method. Successful growth of Cu(I)-CP
on top of Cu(II)-CP was assigned to be due to the interfacial reduction
reaction (IRR). Notably, electrical transport measurements across
AB- and BA-type heterostructured thin films revealed rectification
of current in opposite directions… Show more
“…Briefly, a Au substrate (functionalized with a self-assembled monolayer (SAM) of mercaptoundecanoic acid (MUDA)) was sequentially dipped into AgOAc (silver acetate) and TCNQ solutions in ethanol to grow the Ag-TCNQ thin film at ambient conditions (see the Supporting Information for experimental details). Note that in each LbL growth cycle, multilayers of Ag-TCNQ were deposited, which is consistent with our earlier observations on thin films of CPs, in general. ,− Visual inspection of the bare functionalized Au and the Ag-TCNQ thin film revealed a distinct change in color from golden to dark blue (Figure ).…”
supporting
confidence: 89%
“…The here presented growth of Ag-TCNQ thin films is not as precise as covering the entire surface with one layer of Ag-TCNQ in one cycle of LbL, as in our earlier studies on the LbL growth of Cu-TCNQ thin films under similar conditions. 7,18,19,21 That is why we need to keep the pH of the Ag(I) solution at ≥6.5 and continue LbL cycles until the surface is completely covered with Ag-TCNQ crystallites followed by formation of a thin film in subsequent cycles. Interestingly, upon mixing the TCNQ solution with the AgOAc solution (Figure S9) as well as the TCNQ solution with the AgNO 3 solution (Figure S10), solid Ag-TCNQ was consistently isolated from both the mixtures (Figure S9 and Figure S10).…”
Wet-chemical
fabrication of a crystalline Ag-TCNQ (TCNQ = 7,7,8,8-tetracyanoquinodimethane)
thin film on non-Ag substrate is challenging whereby the chemistry
was powered by photon energy and/or electrical energy. We report for
the first time, direct chemical growth of a Ag-TCNQ thin film on a
functionalized Au substrate by employing the layer-by-layer (LbL)
approach at ambient reaction conditions. Various Ag(I) salt precursors
previously realized to be unsuitable for the fabrication of Ag-TCNQ
thin films on non-Ag substrates ultimately gave rise to dense and
uniform thin films of Ag-TCNQ. The crucial knob regulating the direct
formation of the thin films of Ag-TCNQ was identified to be the pH
of the respective Ag(I) solutions.
“…Briefly, a Au substrate (functionalized with a self-assembled monolayer (SAM) of mercaptoundecanoic acid (MUDA)) was sequentially dipped into AgOAc (silver acetate) and TCNQ solutions in ethanol to grow the Ag-TCNQ thin film at ambient conditions (see the Supporting Information for experimental details). Note that in each LbL growth cycle, multilayers of Ag-TCNQ were deposited, which is consistent with our earlier observations on thin films of CPs, in general. ,− Visual inspection of the bare functionalized Au and the Ag-TCNQ thin film revealed a distinct change in color from golden to dark blue (Figure ).…”
supporting
confidence: 89%
“…The here presented growth of Ag-TCNQ thin films is not as precise as covering the entire surface with one layer of Ag-TCNQ in one cycle of LbL, as in our earlier studies on the LbL growth of Cu-TCNQ thin films under similar conditions. 7,18,19,21 That is why we need to keep the pH of the Ag(I) solution at ≥6.5 and continue LbL cycles until the surface is completely covered with Ag-TCNQ crystallites followed by formation of a thin film in subsequent cycles. Interestingly, upon mixing the TCNQ solution with the AgOAc solution (Figure S9) as well as the TCNQ solution with the AgNO 3 solution (Figure S10), solid Ag-TCNQ was consistently isolated from both the mixtures (Figure S9 and Figure S10).…”
Wet-chemical
fabrication of a crystalline Ag-TCNQ (TCNQ = 7,7,8,8-tetracyanoquinodimethane)
thin film on non-Ag substrate is challenging whereby the chemistry
was powered by photon energy and/or electrical energy. We report for
the first time, direct chemical growth of a Ag-TCNQ thin film on a
functionalized Au substrate by employing the layer-by-layer (LbL)
approach at ambient reaction conditions. Various Ag(I) salt precursors
previously realized to be unsuitable for the fabrication of Ag-TCNQ
thin films on non-Ag substrates ultimately gave rise to dense and
uniform thin films of Ag-TCNQ. The crucial knob regulating the direct
formation of the thin films of Ag-TCNQ was identified to be the pH
of the respective Ag(I) solutions.
“…In view of poor electrical conductivity of MOFs coupled with fabrication challenges of downsizing these materials into crystalline thin film configurations, investigations on electron transport across hetero-structured thin films of MOFs are rarely explored 23 , except the recent studies on the realization of p-n hetero-junction diodes 24 , 25 . Herein, we present an emergence of metallic conduction at the interface of a Mott and a band insulating MOFs.…”
Section: Introductionmentioning
confidence: 99%
“…1 ). Fabrication of such Cu(II)-Cu(I) (3 d 9 –3 d 10 ) interface is attributed to the interfacial reduction reaction (IRR) 24 , 27 , 28 whereby solution of Cu(II)(OAc) 2 was consistently introduced as the metal ion precursor during two consecutive LbL growth with the BPyDC and TCNQ ligands. Fig.…”
Downsizing materials into hetero-structured thin film configurations is an important avenue to capture various interfacial phenomena. Metallic conduction at the interfaces of insulating transition metal oxides and organic molecules are notable examples, though, it remained elusive in the domain of coordination polymers including metal-organic frameworks (MOFs). MOFs are comprised of metal centers connected to organic linkers with an extended coordination geometry and potential void space. Poor orbitals overlap often makes these crystalline solids electrical insulators. Herein, we have fabricated hetero-structured thin film of a Mott and a band insulating MOFs via layer-by-layer method. Electrical transport measurements across the thin film evidenced an interfacial metallic conduction. The origin of such an unusual observation was understood by the first-principles density functional theory calculations; specifically, Bader charge analysis revealed significant accumulation and percolation of charge across the interface. We anticipate similar interfacial effects in other rationally designed hetero-structured thin films of MOFs.
“…The Au substrate was thiolate functionalized by dipping the substrate into 1 mM solution of MUDA in ethanol and acetic acid (v/v = 9:1) for approximately 2 days followed by washing with ethanol and drying in a stream of N 2 gas. ,,− …”
Single-crystal to single-crystal transformation is an elegant example of altering a crystalline solid-state of matter to a solid-state with a different chemical identity. Herein, we present an alluring example of thin-film to thin-film transformation of metal−organic to metal−halide by exploring chemistry at the solid−gas interface. Exposure of crystalline AgTCNQ (TCNQ = 7,7,8,8tetracyanoquinodimethane) thin-film to iodine (I 2 ) vapor and subsequent washing with chloroform (CHCl 3 ) generated crystalline AgI (silver iodide) thin-film. The chemical transformation AgTCNQ → AgI was so rapid that it took place within 2 min at ambient conditions. Reversible structural phase transition in the thin-film of AgI (β-phase ↔ α-phase) was further captured in variable temperature X-ray diffraction patterns, which appears promising for superionic conductivity and pyroelectricity applications.
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