Fibres from different structural parts of the coconut palm tree (Cocos nucifera, linn.) have been examined for properties such as size, density, electrical resistivity, ultimate fracture mode, microfibrillar angle as well as cellulose and lignin contents of these fibres have been determined. The observed properties have been related to the internal structure and chemical composition of the fibres. Some potential uses of these fibres have been I isted .tensile strength, initial modulus and percentage elongation. The stress-strain diagrams, --
A methodology is described for introducing a thin layer of covalently attached benzaldehyde on glassy carbon surfaces using aryl diazonium chemistry. Usually the electroreduction of aryl diazonium salts leads to the formation of an ill-defined multilayer because of the involvement of highly reactive aryl radicals that can add to already-grafted aryl groups. However, in this study we used a two-step "formation-degradation" procedure to solve this problem with the first step consisting of an electrografting of an aryl diazonium salt of a long-chain and bulky alkyl hydrazone onto a glassy carbon surface. The design of the hydrazone group serves to minimize multilayer formation by greatly diminishing the grafting rate after the first-layer formation and at the same time preventing radical additions from taking place at the inner aryl ring. Another valuable property of the hydrazone group is that it easily can be deprotected to the corresponding aldehyde by acid hydrolysis (i.e., the degradation step). In this manner, a thin and well-defined film of covalently attached benzaldehyde with an estimated coverage of 4 x 10(-10) mol cm(-2) was formed. The electrochemical responses of benzaldehyde were highly reproducible and largely independent of grafting medium (water or DMSO) and along with that also the thickness of the initially grafted film. AFM and contact angle measurements support the findings. The "formation-degradation" approach thus lays the foundation for carrying out further functionalization reactions in a controlled manner.
A novel single step method is developed for patterning multiple proteins within self‐assembled binary colloidal crystal patterns. Self‐assembly takes place by confining the suspensions in which either one or both types of particles are coated separately with proteins prior to mixing. This method offers precise control over the spacing between the proteins and the pattern size over large areas without any involvement of expensive lithographic techniques.
Graphene
quantum dots (GQDs) are zero-dimensional materials that
exhibit characteristics of both graphene and quantum dots. Herein,
we report a rapid, relatively green, one-pot synthesis of size-tunable
GQDs from graphene oxide (GO) by a sonochemical method with intermittent
microwave heating, keeping the reaction temperature constant at 90
°C. The GQDs were synthesized by oxidative cutting of GO using
KMnO4 as an oxidizing agent within a short span of time
(30 min) in an acid-free condition. The synthesized GQDs were of high
quality and exhibited good quantum yield (23.8%), high product yield
(>75%), and lower cytotoxicity (tested up to 1000 μg/mL).
Furthermore,
the as-synthesized GQDs were demonstrated as excellent fluorescent
probes for bioimaging and label-free sensing of Fe(III) ions, with
a detection limit as low as 10 × 10–6 M.
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