| ปี พ.ศ. 2558 |
| 1 |
Chemical energy powered nano/micro/macromotors and the environment |
| 2 |
Inherent electrochemistry of layered post-transition metal halides : the unexpected effect of potential cycling of PbI2 |
| 3 |
Labeling graphene oxygen groups with europium |
| 4 |
Misfit-layered Bi1.85Sr2Co1.85O7.7−δ for the hydrogen evolution Reaction : beyond van der Waals heterostructures |
| 5 |
Thiofluorographene-hydrophilic graphene derivative with semiconducting and genosensing properties |
| ปี พ.ศ. 2557 |
| 6 |
Rational design of carboxyl groups perpendicularly attached to a graphene sheet : a platform for enhanced biosensing applications |
| 7 |
Regeneration of a conjugated sp2 graphene system through selective defunctionalization of epoxides by using a proven synthetic chemistry mechanism |
| 8 |
Biomimetic artificial inorganic enzyme-free self-propelled microfish robot for selective detection of Pb2+ in water |
| 9 |
Cytotoxicity profile of highly hydrogenated graphene |
| 10 |
Oxygen-free highly conductive graphene papers |
| 11 |
Fluorographites (CFx)n exhibit improved heterogeneous electron-transfer rates with increasing level of fluorination : towards the sensing of biomolecules |
| 12 |
Cytotoxicity profile of highly hydrogenated graphene |
| 13 |
Towards graphane applications in security: the electrochemical detection of trinitrotoluene in seawater on hydrogenated graphene |
| 14 |
Capacitance of p- and n-doped graphenes is dominated by structural defects regardless of the dopant type |
| 15 |
Cytotoxicity of exfoliated transition-metal dichalcogenides (MoS2, WS2, and WSe2) is lower than that of graphene and its analogues |
| 16 |
Graphene oxides prepared by Hummers’, Hofmann’s, and Staudenmaier’s methods : dramatic influences on heavy-metal-ion adsorption |
| 17 |
Graphene oxides : transformations in natural waters over a period of three months |
| 18 |
Mycotoxins : simultaneous detection of zearalenone and citrinin by voltammetry on edge plane pyrolytic graphite electrode |
| 19 |
Direct voltammetric determination of redox-active iron in carbon nanotubes |
| 20 |
Heteroatom modified graphenes : electronic and electrochemical applications |
| 21 |
Iridium-catalyst-based autonomous bubble-propelled graphene micromotors with ultralow catalyst loading |
| 22 |
Precise tuning of the charge transfer kinetics and catalytic properties of MoS2 materials via electrochemical methods |
| 23 |
Lithium intercalation compound dramatically influences the electrochemical properties of exfoliated MoS2 |
| 24 |
Simultaneous anodic and cathodic voltammetric detection of patulin and ochratoxin A on well-defined carbon electrodes |
| 25 |
Light and atmosphere affect the quasi-equilibrium states of graphite oxide and graphene oxide powders |
| ปี พ.ศ. 2556 |
| 26 |
Electrocatalytic effect of ZnO nanoparticles on reduction of nitroaromatic compounds |
| 27 |
Self-propelled nanojets via template electrodeposition |
| 28 |
Concentric bimetallic microjets by electrodeposition |
| 29 |
Large-scale quantification of CVD graphene surface coverage |
| 30 |
Poisoning of bubble propelled catalytic micromotors : the chemical environment matters |
| 31 |
Unscrolling of multi-walled carbon nanotubes : towards micrometre-scale graphene oxide sheets |
| 32 |
Unusual inherent electrochemistry of graphene oxides prepared using permanganate oxidants |
| 33 |
Transition metal (Mn, Fe, Co, Ni)-doped graphene hybrids for electrocatalysis |
| 34 |
Thrombin aptasensing with inherently electroactive graphene oxide nanoplatelets as labels |
| 35 |
An insight into the hybridization mechanism of hairpin DNA physically immobilized on chemically modified graphenes |
| 36 |
The toxicity of graphene oxides : dependence on the oxidative methods used |
| 37 |
Artificial micro-cinderella based on self-propelled micromagnets for the active separation of paramagnetic particles |
| 38 |
Biomarkers detection on hydrogenated graphene surfaces : towards applications of graphane in biosensing |
| 39 |
Biorecognition on graphene : physical, covalent, and affinity immobilization methods exhibiting dramatic differences |
| 40 |
“Metal-free” catalytic oxygen reduction reaction on heteroatom-doped graphene is caused by trace metal impurities |
| 41 |
Blood proteins strongly reduce the mobility of artificial self-propelled micromotors |
| 42 |
Carcinogenic organic residual compounds readsorbed on thermally reduced graphene materials are released at low temperature |
| 43 |
Could carbonaceous impurities in reduced graphenes be responsible for some of their extraordinary electrocatalytic activities? |
| 44 |
Detection of silver nanoparticles on a lab-on-chip platform |
| 45 |
Halogenation of graphene with chlorine, bromine, or iodine by exfoliation in a halogen atmosphere |
| 46 |
Highly hydrogenated graphene through microwave exfoliation of graphite oxide in hydrogen plasma : towards electrochemical applications |
| 47 |
Precise tuning of surface composition and electron-transfer properties of graphene oxide films through electroreduction |
| 48 |
Selective removal of hydroxyl groups from graphene oxide |
| 49 |
Concurrent phosphorus doping and reduction of graphene oxide |
| 50 |
Transition metal-depleted graphenes for electrochemical applications via reduction of CO2 by lithium |
| 51 |
Chemically modified graphenes as detectors in lab-on-chip device |
| 52 |
Surfactant capsules propel interfacial oil droplets: an environmental cleanup strategy |
| 53 |
Surfactant capsules propel interfacial oil droplets : an environmental cleanup strategy |
| ปี พ.ศ. 2555 |
| 54 |
Nanoporous carbon as a sensing platform for DNA detection : the use of impedance spectroscopy for hairpin-DNA based assay |
| 55 |
Impedimetric immunoglobulin G immunosensor based on chemically modified graphenes |
| 56 |
Graphene, carbon nanotubes and nanoparticles in cell metabolism |
| 57 |
Thermally reduced graphenes exhibiting a close relationship to amorphous carbon |
| 58 |
Noble metal (Pd, Ru, Rh, Pt, Au, Ag) doped graphene hybrids for electrocatalysis |
| 59 |
High-pressure hydrogenation of graphene : towards graphane |
| 60 |
Electroactivity of graphene oxide on different substrates |
| 61 |
Inherently electroactive graphene oxide nanoplatelets as labels for single nucleotide polymorphism detection |
| 62 |
Electrochemical properties of carbon nanodiscs |
| 63 |
Stripping voltammetry at chemically modified graphenes |
| 64 |
Impedimetric thrombin aptasensor based on chemically modified graphenes |
| 65 |
Graphenes prepared by Staudenmaier, Hofmann and Hummers methods with consequent thermal exfoliation exhibit very different electrochemical properties |
| 66 |
Detection of DNA hybridization on chemically modified graphene platforms |
| 67 |
Metal-based impurities in graphenes : application for electroanalysis |
| 68 |
Comparison of the electroanalytical performance of chemically modified graphenes (CMGs) using uric acid |
| 69 |
Graphane electrochemistry : electron transfer at hydrogenated graphenes |
| 70 |
Graphene/carbon nanotube composites not exhibiting synergic effect for supercapacitors : the resulting capacitance being average of capacitance of individual components |
| 71 |
Oxidation of DNA bases is influenced by their position in the DNA strand |
| 72 |
Surfactants show both large positive and negative effects on observed electron transfer rates at thermally reduced graphenes |
| 73 |
Reynolds numbers exhibit dramatic influence on directionality of movement of self-propelled systems |
| 74 |
Influence of parent graphite particle size on the electrochemistry of thermally reduced graphene oxide |
| 75 |
Introducing dichlorocarbene in graphene |
| 76 |
Micromotors with built-in compasses |
| 77 |
Impurities in graphenes and carbon nanotubes and their influence on the redox properties |
| 78 |
Lithium aluminum hydride as reducing agent for chemically reduced graphene oxides |
| 79 |
Renewal of sp2 bonds in graphene oxides via dehydrobromination |
| 80 |
Graphene oxide reduction by standard industrial reducing agent : thiourea dioxide |
| 81 |
Graphene for impedimetric biosensing |
| 82 |
Chemically reduced graphene contains inherent metallic impurities present in parent natural and synthetic graphite |
| 83 |
Metallic impurities in graphenes prepared from graphite can dramatically influence their properties |
| 84 |
90 years of polarography : back to the future |
| 85 |
Bioavailability of metallic impurities in carbon nanotubes is greatly enhanced by ultrasonication |
| 86 |
Graphite oxides : effects of permanganate and chlorate oxidants on the oxygen composition |
| 87 |
Nanographite impurities in carbon nanotubes : their influence on the oxidation of insulin, nitric oxide, and extracellular thiols |
| 88 |
Nucleic acid functionalized Graphene for biosensing |
| 89 |
On oxygen-containing groups in chemically modified graphenes |
| 90 |
Redox-active nickel in carbon nanotubes and its direct determination |
| 91 |
Friedel-Crafts acylation on graphene |
| 92 |
Graphene sheet orientation of parent material exhibits dramatic influence on Graphene properties |
| 93 |
Inherent electrochemistry and activation of chemically modified graphenes for electrochemical applications |
| 94 |
Macroscopic self-propelled objects |
| 95 |
Nanoporous carbon materials for electrochemical sensing |
| 96 |
The inherent electrochemistry of nickel/nickel-oxide nanoparticles |
| 97 |
Gold nanospacers greatly enhance the capacitance of electrochemically reduced graphene |
| 98 |
Graphenes prepared by Hummers, Staudenmaier and Hofmann methods for analysis of TNT-based nitroaromatic explosives in seawater |
| 99 |
Oxidation of DNA bases influenced by the presence of other bases |
| 100 |
Size dependant electrochemical behavior of silver nanoparticles with sizes of 10, 20, 40, 80 and 107 nm |
| 101 |
Liquid–liquid interface motion of a capsule motor powered by the interlayer Marangoni effect |
| 102 |
Reduction pathways of 2,4,6-trinitrotoluene : an electrochemical and theoretical study |
| ปี พ.ศ. 2554 |
| 103 |
Electrochemistry of folded graphene edges |
| 104 |
Graphene in biosensing |
| 105 |
Graphene materials preparation methods have dramatic influence upon their capacitance |
| 106 |
Surfactants used for dispersion of graphenes exhibit strong influence on electrochemical impedance spectroscopic response |
| 107 |
Number of graphene layers exhibiting an influence on oxidation of DNA bases : analytical parameters |
| 108 |
Voltammetry of carbon nanotubes and graphenes : excitement, disappointment, and reality |
| ปี พ.ศ. 2553 |
| 109 |
Graphene for electrochemical sensing and biosensing |
| 110 |
Graphene-based electrochemical sensor for detection of 2,4,6-trinitrotoluene (TNT) in seawater: the comparison of single-, few-, and multilayer graphene nanoribbons and graphite microparticles |
