Scalable and Solid‐State Redox Functionalization of Transparent Single‐Walled Carbon Nanotube Films for Highly Efficient and Stable Solar Cells

This study reports a scalable and room‐temperature solid‐state redox functionalization process for single‐walled carbon nanotubes (SWNTs) with instant efficacy and high stability. By drop‐casting/spin‐coating CuCl₂/Cu(OH)₂ colloidal ethanol solution onto SWNT films, the sheet resistance of the SWNT films achieves 69.4 Ω sq^?1 at 90% transparency without noticeable increase for more than 12 months. The charge transfer mechanism between the redox and the SWNTs is revealed by Raman and X‐ray photoelectron spectroscopies. The SWNT/silicon solar cells are utilized as a benchmark to evaluate the effectiveness of the redox functionalization process and its compatibility for device integration. The power conversion efficiency of the SWNT/Si solar cell increases by 115% after redox functionalization, reaching the value of 14.09% without degradation in the ambient for over 12 months. Temperature‐dependent operation characteristics of the redox functionalized SWNT/Si solar cells demonstrate that the Fermi level unpinning and enhanced tunneling of the charge carriers contribute to the significant improvement of the photovoltage and fill factor. The CuCl₂/Cu(OH)₂ redox also serves as an antireflection layer, resulting in a 20% increase of the photocurrent. The proposed redox functionalized SWNTs are promising as multifunctional transparent conductive films for wide‐range solar cell applications.     

Biosorption and Bioreduction of Copper from Different Copper Compounds in Aqueous Solution

High copper concentration is toxic for living organisms including humans. Biosorption is a bioremediation technique that can remove copper and other pollutants from aqueous medium and soils, consequently cleaning the environment. The aim of this study was, therefore, to investigate the influence of different copper compounds (Cu(II) as CuCl₂; Cu(II) as CuSO₄; and Cu(I) as CuCl) on copper bioreduction and biosorption using four copper-resistant bacteria isolated from the rhizosphere of two plants (Avena sativa and Plantago lanceolata) in aqueous matrix. Copper resistance profile, bioreduction, and biosorption after 48 h of incubation were evaluated. The isolates displayed high copper resistance. However, isolate A1 did not grow very well in the CuCl₂ and isolate T5 was less resistant to copper in aqueous solutions amended with CuCl (Cu(I)). The best copper source for copper bioreduction and biosorption was CuSO₄ and the isolates removed as much as ten times more copper than in aqueous solutions amended with the other copper compounds. Moreover, Cu(I) did not succumb to biosorption, although the microbes were resistant to aqueous solutions of CuCl. In summary, Cu(II) from CuSO₄ was furthermost susceptible to bioreduction and biosorption for all isolates. This is an indication that copper contamination of the environment from the use of CuSO₄ as an agrochemical is amenable to bioremediation.     

Effects of interaction between65Zn,cadmium, and copper in rats

Distribution and retention of zinc in the presence of cadmium and copper was studied in rats exposed repeatedly to these metals. The experiment was performed on white rats of the Wistar strain. The animals were divided into four groups/five rats each: 1)⁶⁵ZnCl₂; 2)⁶⁵ZnCl₂+CdCl₂; 3)⁶⁵ZnCl₂+CuCl₂; and 4) control group. Rats were administered sc every other day for two weeks:⁶⁵ZnCl₂−5 mg Zn/kg; CdCl₂−0,3 Cd/kg; and CuCl₂−2 mg Cu/kg. The zinc content was measured in rat tissues by γ-counting. Effect of Cd and Cu on subcellular distribution of zinc in the kidney and liver and on the level of metallothionein were also examined. Whole body retention of zinc under the influence of cadmium was lower than that observed in animals treated with zinc alone. However, copper increased twofold the whole body retention of zinc. Cadmium elevated the accumulation of zinc only in the kidneys nuclear fraction and liver soluble fraction. In the kidneys and liver, copper elevated the accumulation of zinc, in the nuclear, mitochondrial, and soluble fractions. The level of metallothionein-like proteins (MT) in the kidneys after a combined supply of zinc and copper was significantly increased with respect to the group of animals treated with zinc alone. These results indicated complex interactions between cadmium, copper, and zinc that can affect the metabolism of each of the metals.     

Synthesis, spectroscopic and structural characterization of some novel adducts of copper(II) salts with unidentate nitrogen bases

Syntheses, spectroscopic characterization and single crystal X-ray studies are reported for a number of complexes of copper(II) salts with simple monodentate nitrogen bases. The 1:4 adduct of copper(II) sulfate with 3,5-dimethylpyridine (m₂py) CuSO₄·4m₂py, takes the form [(O₃SO)Cu(m₂py)₄], the Cu-O vector of the square-pyramidal coordination environment being disposed on the 4-axis in tetragonal space group P4/n. The complex CuCO₃·Cu(NCS)₂·4py is a linear polymer, taking the form ?O·Cu(py)₂·O·C{O·Cu(py)₂(NCS)₂}·O·Cu(py)₂? (etc.), all atoms lying in the mirror plane of space group Pnma, excepting the pair of ‘py’ (pyridine) ligands disposed to either side. In Cu(OH)I·3/4I₂·2py·1/2MeCN ≡ [{(py)₂Cu(OH)}₄](I₃)₃I·2MeCN a novel cubanoid tetranuclear cation is found (2-symmetry). The EPR spectra of the above compounds show a trend in the anisotropy of the g-values that correlates well with the crystal structures. Obtained only in small quantities but supported by single crystal X-ray studies are the adduct of Cu(OH)Cl with pyrrolidine (pyrr), Cu(OH)Cl:pyrr (1:3), which takes the centrosymmetric binuclear form [(pyrr)₃Cu(μ-OH)₂Cu(pyrr)₃]Cl₂, the copper atom being disposed in a distorted trigonal bipyramidal array, and the adduct 3CuCl₂·CuO·4quin, [Cu₄Cl₆O(quin)₄]Cl₂, which contains the familiar Cu₄Cl₆O core with monodentate quinuclidine (quin) attached to the copper atoms; this compound crystallizes in the cubic space group .     

CuA centers and their biosynthetic models in azurin

Cu_A is a binuclear copper center that functions as an electron transfer agent, cycling between a reduced Cu(I)Cu(I) state and an oxidized mixed-valence Cu(+1.5)···Cu(+1.5) state. The copper ions are bridged by two cysteine thiolate ligands and form a copper–copper bond, the first reported of its kind in Nature. Such a “diamond-core” Cu₂S(Cys)₂ structure allows an unpaired electron to be completely delocalized over the two copper ions and contributes to its highly efficient electron transfer properties. This review provides accounts of how the Cu_A center was structurally characterized and highlights its salient spectroscopic properties. In the process, it introduces the Cu_A center in four different systems—native protein systems, soluble protein truncates of native proteins, synthetic models using organic molecules, and biosynthetic models using proteins as ligands—with a greater emphasis on biosynthetic models of Cu_A, especially on new, deeper insights gained from their studies.     

Copper uptake and intracellular distribution in the human intestinal Caco-2 cell line

The apical uptake of ⁶⁴CuCl₂ was investigated in human differentiated intestinal Caco-2 cells grown on permeable supports. At pH 6.0 in the apical compartment, the uptake of copper was linear over the first 6 min and between 10 and 80 M CuCl₂ exhibited non-saturable transport kinetics. In addition, copper uptake was energy-independent, affected by the valency state of copper, preferring Cu(II) over Cu(I), and not influenced by high (10 mM) extracellular calcium. The intracellular distribution of copper was investigated by FPLC at different times of uptake (`pulse') and of `chase'. Intracellular copper initially bound predominantly to low molecular weight components (i.e., glutathione), and subsequently shifted to higher molecular weight components such as metallothionein and Cu,Zn superoxide dismutase.     

Stabilization of non-histone proteins by copper ions does not alter chromatin properties of polythene chromosomes of <Emphasis Type="Italic">Chironomus plumosus</Emphasis>

Our previous study showed that the body of polythene chromosomes can be identified even after removal of all histones and DNA in the presence of 2 mM CuCl₂; this suggested that copper ions stabilized the bonds between non-histone proteins. In this study we tried to find out if copper ions bind with non-histone proteins reversibly or irreversibly. It is shown that the bodies of normal chromosomes and chromosomes stabilized by 2 mM CuCl₂ swell with partial disappearance of the banding pattern in a hypotonic solution (0.055 M NaCl) without copper ions. The selective removal of bivalent cations by 10 mM EDTA solution resulted in decondensation of normal polythene and stabilized chromosomes. The treatment of nuclear protein matrix of polythene chromosomes preparations with 10 mM EDTA resulted in the swelling of polythene chromosome body and disappearance of the banding pattern but their morphological organization maintained.     

Nanostructured copper oxides and phosphates from a new solid-state route

Nanostructured copper containing materials of CuO, Cu₃(PO₄)₃ and Cu₂P₂O₇ have been prepared by solid-state pyrolysis of molecular CuCl₂·NC₅H₄OH (I), CuCl₂·CNCH₂C₆H₄OH (II), oligomeric [Cu(PPh₃)Cl]₄ (III), N₃P₃[OC₆H₄CH₂CN·CuCl]₆[PF₆] (IV), N₃P₃[OC₆H₅]₅[OC₅H₄N·Cu][PF₆] (V), polymeric chitosan·(CuCl₂)_n (VI) and polystyrene-co-4-vinylpyridine PS-b-4-PVP·(CuCl₂) (VII) precursors. The products strongly depend on the precursor used. The pyrolytic products from phosphorus-containing precursors (III), (IV) and (V) are Cu phosphates or pyrophosphates, while non-phosphorous-containing precursors (VI) and (VII), result in mainly CuO. The use of chitosan as a solid-state template/stabilizer induces the formation of CuO and Cu₂O nanoparticles. Copper pyrophosphate (Cu₂P₂O₇) deposited on Si using (IV) as the precursor exhibits single-crystal dots of average diameter 100 nm and heights equivalent to twice the unit cell b-axis (1.5-1.7 nm) and an areal density of 5.1-7.7 Gigadots/in.². Cu₂P₂O₇ deposited from precursor (VI) exhibits unique labyrinthine high surface area deposits. The morphology of CuO deposited on Si from pyrolysis of (VI) depends on the polymer/Cu meta ratio. Magnetic measurements performed using SQUID on CuO nanoparticle networks suggest superparamagnetic behavior. The results give insights into compositional, shape and morphological control of the as-formed nanostructures through the structure of the precursors.     

Copper(II) complexes of N-heteroaromatic hydrazones: Synthesis, X-ray structure, magnetic behavior, and antibacterial activity

Three novel copper(II) complexes as condensation derivatives of 2-pyridinecarboxaldehyde, 2-acetylpyridine or 2-quinolinecarboxaldehyde with ethyl hydrazinoacetate hydrochloride were synthesized. X-ray crystal structures of all three complexes were determined. Crystallographic data indicate a common basis of the structures with some major differences. Both pyridine derivatives form complexes of the type [CuCl₂L] with distorted square-planar geometry around copper(II), but show a decisive difference in the side chain orientation. The quinoline derivative forms a dimeric complex of type [Cu₂Cl₄L₂] with distorted trigonal bipyramidal geometry around copper(II), but a rather short Cu···Cu contact, which is reflected in its magnetic properties. All three complexes showed antibacterial activity.     

Synthesis and crystal structure of a tetranuclear five-coordinated copper(II) complex with Schiff-base of N-(3-carboxylsalicylidene)-4-(2-iminoethyl)-morpholine

A tetranuclear copper(II) complex [Cu₄L₂(CH₃COO)₂(OH)₂]·6H₂O, in which L stands for the dianion of N-(3-carboxylsalicylidene)-4-(2-iminoethyl)morpholine, was synthesized and characterized by elemental analysis, IR, UV-Vis, TGA and X-ray single crystal diffraction. The crystal structure shows that the coordination unit is centrosymmetric with all the Cu(II) ions in square pyramidal coordination geometry. The coordination unit consists of two equivalent parts [Cu₂L(CH₃COO)(OH)], each containing two Cu(II) ions, a tetradentate N₂O₂ Schiff base dianion L²⁻, a CH₃COO⁻, and a OH⁻ anion. In [Cu₂L(CH₃COO)(OH)], the six coordination atoms (N₂O₄) are nearly coplanar, with Cu(1) and Cu(2) enchased in between; the phenolate oxygen and the OH⁻ oxygen as bridging atoms bind the two Cu(II) ions in close proximity; both O₄ around Cu(1) and N₂O₂ around Cu(2) form the basal plane of the coordination square pyramids. The two parts are connected by sharing two μ₃-OH⁻ oxygens and two μ₂-CH₃COO⁻ oxygens from each other, forming four edge-sharing coordination square pyramids around the four Cu(II) ions. A 3D network is formed through hydrogen bonding along a and c axis, and π-π interaction along b axis.     

On the mechanism of the comutagenic effect of Cu(II) with ultraviolet light

Although CuCl₂ alone is not mutagenic inE. coli or in Chinese hamster cells, exposure ofE. coli to CuCl₂ during, UV-irradiation causes enhancement of UV-mutagenesis. The mechanism for this comutagenic effect appears to be owing to increased DNA damage by the combined treatment of UV and Cu(II) compared with UV or Cu(II) alone. Using a sequencing gel approach, UV alone is found to cause a particular pattern of alkali-labile sites, whereas CuCl₂ alone caused few such sites. The combined action of UV+CuCl₂ greatly increased the amount of sites over that of UV alone, and caused a change in their pattern. In the presence of high NaCl concentrations, however, Cu(II) is able to induce DNA damage. This latter effect is most likely owing to the formation of hypochlorite ion. The hypothesis that the comutagenic effect of Cu(II) plus UV might be owing to hydroxyl radical formed via a Fenton reaction involving Cu(II) and UV-generated H₂O₂ was not supported, since no H₂O₂ is detectable in aqueous medium after UV irradiation, and catalase did not block the DNA damage. These results favor the hypothesis that UV-irradiation of Cu(II) causes a photoactivation, enabling it to generate free radicals, perhaps by reacting with dissolved oxygen.     

Effects of coating roughness and biofouling on ship resistance and powering

Abstract

Predictions of full-scale ship resistance and powering are made for antifouling coating systems with a range of roughness and fouling conditions. The estimates are based on results from laboratory-scale drag measurements and boundary layer similarity law analysis. In the present work, predictions are made for a mid-sized naval surface combatant at cruising speed and near maximum speed. The results indicate that slime films can lead to significant increases in resistance and powering, and heavy calcareous fouling results in powering penalties up to 86% at cruising speed. The present estimates show good agreement with results from full-scale ship power trials.     

Copper kinetics and hepatic metallothionein levels in the frog Rana ridibunda, after exposure to CuCl2

Adult female frogs Rana ridibunda were exposed to 50 and 100 ppm of Cu (as CuCl₂) dissolved in water for 5, 15 and 30 days. We measured the Cu content in the liver, kidneys, ventral skin, and large intestine. Hepatic metallothionein (MT) was also measured and we identified by elution the type of proteins bound to copper. Gross morphological characteristics of the frogs were not affected by Cu accumulation. Cu uptake took place first across the skin, then accumulated first in the large intestine, and then in the liver which was continuously accumulating Cu at all exposure concentrations and times. The highest concentration of the metal was recorded in the kidneys at 30 days and 100 ppm exposure. It appears that the kidneys act as the secondary route of Cu detoxification, probably after a Cu overload of liver. The concentration of hepatic MT increased with the increase of Cu concentration in liver at the 5^th and 15^th day of exposure but we observed a decrease by the end of the experiment. Cu was observed in the MT-fraction, and in the high-molecular weight protein fraction.     

Chronotoxicity of a Copper (II) Complex with a Linear Tetradentate Ligand in Mice

In vitro copper (II) complex presents antimitotic effects. In this work, we have studied the in vivo seasonal toxic effects of copper (II), ligand (H₂L) and the complex [Cu(H₂L)(H₂O)₂]Cl₂·4H₂O in male Swiss mice. During spring, an i.p. injection of CuCl₂ in aqueous NaCl (9 g·l^-1) up to 0.05 µmol·kg^-1 b.w. (body weight) killed 60% of the rodents after 6 days. LD100 was up to 0.3 µmol·kg^-1; H₂L was well tolerated, while the complex was 30% lethal with 50 µmol·kg^-1. In autumn, mice were less sensitive to CuCl₂, and both ligand and complex were equally tolerated and this leads to the conclusion that, in vivo, chronotoxicities of copper (II) and complex in NaCl aqueous solutions are quite different in spring and autumn seasons.     

Interactions between metal ions and carbohydrates: the coordination behavior of neutral erythritol to transition metal ions

The single crystals of coordinated complexes of neutral erythritol (C4H10O4) with various transition metal ions were synthesized and studied using FT-IR and single crystal X-ray diffraction analysis. Two CuCl2-erythritol complexes (denoted as CuE(I) and CuE(II)) were obtained. In CuE(I), Cu2+ coordinates with two chloride ions and four OH groups from two erythritol molecules. Two copper centers are linked by one erythritol molecule to form a zigzag chain. For CuE(II), each Cu2+ coordinates with two OH groups from an erythritol molecule and two chloride ions. The crystal of CuE(II) contains complexed and free erythritol, the dimers of [Cu2Cl4(C4H10O4)] further form a [Cu2Cl4(C4H10O4)]infinity chain via secondary Cu...Cl bonds, both the dimer unit of [Cu2Cl4.(C4H10O4)] and non-coordinated C4H10O4 unit exist side by side in the crystal. MnCl2-erythritol complex whose structure is similar to CuE(I) is also acquired. The OH groups of erythritol act as ligand to coordinate to metal ions on one hand, one the other hand, OH groups form hydrogen bonds network that link chain and layer together to build three-dimensional structures.     

The synthesis and characterization of copper(II) squarate chloride

Copper(II) squarate chloride [Cu(H₂C₄O₄)(Cl)]₂, C₃H₇OH has been synthesized by reacting propan- 2-ol solutions of CuCl₂•2H₂O and squaric acid in an inert atmosphere. The complex has been characterized by elemental analysis, spectral analysis and magnetic measurements.     

Copper-Ligand Interactions and Physiological free Radical Processes. Part 2. Influence of Cu2+ Ions on Cu+-Driven Oh Generation and Comparison with Their Effects on Fe2+-Driven Oh Production

In our search to establish a reference ·OH production system with respect to which the reactivity of copper(II) complexes could then be tested, the influence of free Cu²⁺ ions on the Cu⁺/H₂O₂ reaction has been investigated.

This influence depends on the C_Cu²⁺/C_Cu⁺ ratio. At low Cu²⁺ concentrations, ·OH damage to various detector molecules decreases with increasing Cu²⁺ concentrations until C_Cu²⁺/C_Cu⁺ reaches unity. Above this value, ·OH damage increases sharply until C_Cu²⁺/C_Cu⁺ becomes equal to 5 with salicylate and 2 with deoxyribose, ratios for which the protective effect of Cu²⁺ cancels. Finally, at higher concentrations, Cu²⁺ ions logically add their own ·OH production to that normally expected from Cu⁺ ions. The possible origin of this unprecedented alternate effect has been discussed. The possible influence of Cu⁺ ions on the generation of ·OH radicals by water gamma radiolysis has also been tested and, as already established for Cu²⁺ in a previous work, shown to be nonexistent. This definitely confirms that either form of ionised copper cannot scavenge ·OH radicals in the absence of a Iigand.     

Crystal structural, electrochemical and computational studies of two Cu(II) complexes formed by benzotriazole derivatives

Two Cu(II)-containing complexes, [Cu(pbbt)Cl₂]₂ · CH₃OH (1) and [Cu(bbbt)_1.5Cl₂]_n (2) (pbbt = 1,1′-(1,3-propylene)bis-1H-benzotriazole, bbbt = 1,1′-(1,4-butanediyl)bis-1H-benzotriazole), have been synthesized and characterized. Single crystal X-ray diffraction shows that 1 exhibits discrete binuclear structure, in which two Cu(II) ions are bridged together through two Cl⁻ anions and two pbbt ligands. Whereas 2 displays infinitely extended two-dimensional reticulate grid structure with hexagon units in which six Cu(II) ions act as corners and six bbbt ligands serve as sides. The electrochemical studies show that their redox processes in the potential range of 0.1-0.9 V are quasi-reversible and controlled by diffusion. The diffusion coefficients decrease with increase in the molecular weight of the complexes and the size of the molecules. Further investigation exhibits that their electrochemical properties obtained from experiments are consistent with their crystal data and the computed parameters. For example, the observed one-pair well-defined redox waves in the cyclic voltammetry (CV) diagrams correspond to the X-ray diffraction results that all of the Cu(II) ions in the title complexes are equivalent, respectively; the cathodic shifts (as compared with CuCl₂) of the reduction potentials of 1 and 2 are in agreement with the computed results: the LUMO energies of the complexes (−3.789 eV for 1 and −4.330 eV for 2) are higher than that of CuCl₂ (−6.942 eV).     

The amylin peptide implicated in type 2 diabetes stimulates copper-mediated carbonyl group and ascorbate radical formation

Human amylin (hA), which is toxic to islet β-cells, can self-generate H₂O₂, and this process is greatly enhanced in the presence of Cu(II) ions. Here we show that carbonyl groups, a marker of oxidative modification, were formed in hA incubated in the presence of Cu(II) ions or Cu(II) ions plus H₂O₂, but not in the presence of H₂O₂ alone. Furthermore, under similar conditions (i.e., in the presence of both Cu(II) ions and H₂O₂), hA also stimulated ascorbate radical formation. The same observations concerning carbonyl group formation were made when the histidine residue (at position 18) in hA was replaced by alanine, indicating that this residue does not play a key role. In complete contrast to hA, rodent amylin, which is nontoxic, does not generate H₂O₂, and binds Cu(II) ions only weakly, showed none of these properties. We conclude that the hA-Cu(II)/Cu(I) complex is redox active, with electron donation from the peptide reducing the oxidation state of the copper ions. The complex is capable of forming H₂O₂ from O₂ and can also generate ^•OH via Fenton chemistry. These redox properties of hA can explain its ability to stimulate copper-mediated carbonyl group and ascorbate radical formation. The formation of reactive oxygen species from hA in this way could hold the key to a better understanding of the damaging consequences of amyloid formation within the pancreatic islets of patients with type 2 diabetes mellitus.