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1 ive deposition of an electrochromic polymer (polyaniline).
2  of APSA during electropolymerization of the polyaniline.
3 polymerization of aniline to form conductive polyaniline.
4 een pre-modified with the conductive polymer polyaniline.
5 H 5, corresponding to the conductive form of polyaniline.
6  oligoaniline shell on gold nanoparticles to polyaniline.
7 n/off fluorescence switching, reminiscent of polyaniline.
8 d chemical properties typical of para-linked polyanilines.
9 s of emeraldine base polyaniline (PANI) and (polyaniline)(0.5)V(2)O(5) x 1.0 H(2)O have been determin
10 ne-step process involving the pyrolysis of a polyaniline aerogel synthesized in the presence of phyti
11 ges in Raman spectra of boronate-substituted polyaniline after addition of glucose are similar to tho
12 lized conducting copolymer matrix comprising polyaniline and 2-aminobenzylamine.
13                                Nanofibers of polyaniline and oligoanilines of controlled molecular we
14 onsive nanocapsules consisting of conductive polyaniline and polypyrrole shells were successfully syn
15 detection of various small soluble n-mers of polyaniline and silver ion solvent clusters formed from
16 ed from laser ablation of electropolymerized polyaniline and silver thin films, respectively.
17 . nafion, polyphenylenediamine, polypyrrole, polyaniline, and polynaphthol using a novel silica-based
18 rein the redox energies of Al and conducting polyaniline are exploited to design a battery type senso
19                        The second utilized a polyaniline array as a substrate to immobilize a biotiny
20 dispersed active sites are prepared by using polyaniline as a graphene precursor and introducing phen
21 en proposed for the excellent sensitivity of polyaniline as a pH sensor for detection of H(+) ions re
22                            The approach uses polyaniline as a precursor to a carbon-nitrogen template
23 ple electrostatic binding of the antibody to polyaniline as well as a more complex procedure using a
24 nt of nucleation using a conjugated polymer, polyaniline, as an example.
25  oligomers were produced, and the self-doped polyaniline backbone had a longer conjugation length and
26 he switching of amine functionalities in the polyaniline backbone, converting them to imine forms.
27                                   Conducting polyaniline-based chemiresistors on printed polymeric mi
28                In this trial, the ability of polyaniline-based materials (PANI-EB and PANI-ES) was te
29  performance when compared with conventional polyaniline-based sensors, and this was attributed to th
30                                          The polyaniline capsules exhibited delayed release under oxi
31 ic carbon for iodine loading by pyrolysis of polyaniline coated cellulose wiper.
32 tained by thermal activation of a mixture of polyaniline-coated graphene oxide and ammonium hexafluor
33                        Stable suspensions of polyaniline colloids (approximately 115 nm in diameter)
34 was demonstrated that the positively charged polyaniline colloids can be electrophoretically deposite
35 yl acetate) itaconic acid (PANI(PVIA)) doped polyaniline conducting nanobeads (SiO2(LuPc2)PANI(PVIA)-
36 ormed to characterize the interconversion of polyaniline content (from amine to imine) in manno-PANI
37                     Compared with its sulfur-polyaniline core-shell counterparts, the yolk-shell nano
38                                      Being a polyaniline derivative, PAPBA showed an ion-dependent re
39  were first coated with emulsion-polymerized polyaniline/dinonylnaphthalenesulfonic acid (PANI/DNNSA)
40 A caused by shielding of charges on DNA when polyaniline/DNA complexes formed in solution.
41 vals that of pressed pellets of conventional polyaniline doped with acid.
42 was prepared from vitamin B12 (VB12) and the polyaniline-Fe (PANI-Fe) complex, respectively.
43           A novel chiral selective imprinted polyaniline-ferrocene-sulfonic acid film has been electr
44 voltammogram obtained from the experiment on polyaniline film using Fe(2+)/Fe(3+) in HCl as the redox
45 odegrading E. coli cells were immobilized on polyaniline film.
46 cal conductivities in excess of 50 S/cm when polyaniline films are exposed to dichloroacetic acid.
47 xploration of the viscoelastic properties of polyaniline films exposed to aqueous perchloric acid has
48 oating small polymer objects with conductive polyaniline films preventing accumulation of static elec
49 15 nm in diameter) were formed by dispersing polyaniline/formic acid solution into acetonitrile.
50 C3 N) can be attributed to their inherent 2D polyaniline frameworks, which provide large net positive
51 resent a method for controlled deposition of polyaniline from colloidal suspensions.
52 posited on top of an electrosprayed graphene/polyaniline (G/PANI) modified screen printed carbon elec
53                                              Polyaniline in the emeraldine base form functions as a v
54 allenges in developing better products using polyaniline in this new morphology.
55 echanical treatment transforms nonconductive polyaniline into its conductive form.
56                                              Polyaniline is a conducting polymer with incredible prom
57 ant E. coli cells in the microenvironment of polyaniline led to a change in its conductivity, which w
58 e characteristics based on manganese dioxide/polyaniline (MNW/PANI) coaxial nanowire networks.
59                                          The polyaniline-modified nanochannels showed three different
60       The biosensing layer was placed onto a polyaniline-Nafion composite platinum electrode and cove
61  use of a novel ammonium ion-specific copper-polyaniline nano-composite as transducer for hydrolase-b
62 ess was 4,500 times faster when a self-doped polyaniline nanocomposite was fabricated using in situ p
63                           Highly dispersible polyaniline nanofibers can now be reproducibly prepared
64                                      Uniform polyaniline nanofibers readily form using interfacial po
65 iew explores some intriguing applications of polyaniline nanofibers, as well as the advantages and re
66                                              Polyaniline nanofibers, on the other hand, have demonstr
67                     Under flash irradiation, polyaniline nanofibres 'melt' to form a smooth and conti
68 e tumor-targeting rapamycin/DiR loaded lipid-polyaniline nanoparticle (RDLPNP) for dual-modal imaging
69     Correlating the shape and aggregation of polyaniline nanoparticles with the mode of nucleation, a
70 kjet printed ammonia sensor fabricated using polyaniline nanoparticles.
71 ulcanization process by heating a mixture of polyaniline nanotube and sulfur at 280 degrees C.
72                           A novel vulcanized polyaniline nanotube/sulfur composite was prepared succe
73 cluding a continuous electrically conductive polyaniline network, binding with the Si surface through
74 n ether (G-quadruplexes), chemical (pH-doped polyaniline), or biocatalytic (glucose oxidase/urease) t
75 idized microRNA (miRNA)-guided deposition of polyaniline (PAn), a highly sensitive impedimetric miRNA
76 ce of the Al(2)O(3) NPs is modified by ionic polyaniline (PANDB) rather than the conventional silane
77                  Pulsed electrodeposition of polyaniline (PANI) allows the fabrication of flexible, e
78 ee-dimensional structures of emeraldine base polyaniline (PANI) and (polyaniline)(0.5)V(2)O(5) x 1.0
79 horetically deposited nanocomposite films of polyaniline (PANI) and core-shell Ag@AgO nanoparticles (
80 ChE) biosensor was successfully developed on polyaniline (PANI) and multi-walled carbon nanotubes (MW
81                            Nanostructures of polyaniline (PAni) and polypyrrole (PPy) with controlled
82 omposite of camphorsulfonic acid (CSA)-doped polyaniline (PANI) and the room-temperature ionic liquid
83 situ polymerized mesoporous silica-supported polyaniline (PANI) by carbonization of the latter, follo
84                                     Overall, polyaniline (PAni) doped in acidic media has shown metal
85  of the microtiter reader plates well with a polyaniline (PANI) film sensitive for ascorbic acid is p
86 graphene (G), polyvinylpyrrolidone (PVP) and polyaniline (PANI) has been successfully prepared and us
87                                     Graphene-polyaniline (PANI) hybrids are attractive candidates for
88 ding an alpha-amylase specific antibody to a polyaniline (PANI) layer and controlling device assembly
89  composed of mesoporous silica (SBA-15) with polyaniline (PANI) nanostructures within its channel por
90 rbon nanotube (S/SWNT) composite coated with polyaniline (PANI) polymer as polysulfide block to achie
91 he AuNPs-AOx conjugate was encapsulated with polyaniline (PANI) synthesized by oxidative polymerizati
92                                              Polyaniline (PANI) was deposited electrochemically from
93                              In this system, polyaniline (PANI) with pi-pi electronic conjugated syst
94  Composed exclusively of organic components, polyaniline (PANi), graphene, and double-walled nanotube
95              Conducting polymers, especially polyaniline (PAni), have been extensively used in biosen
96 measurements are done by potentiometry using polyaniline (PAni)-based working electrodes and silver/s
97 xidase (HRP)-immobilized conducting polymer, polyaniline (PANI).
98  and rapid bacteria counting method based on polyaniline (PANI)/bacteria thin film was proposed.
99                                      Tubular polyaniline (PANI)/Zn microrockets are described that di
100  growth of a shell of NLO materials (such as polyaniline, PANI) with variable thickness.
101 y using an electrochemical growth of bilayer polyaniline/platinum microtubes within the conically sha
102 es of electronic conducting polymers such as polyaniline, polypyrrole, and poly(3,4-ethylenedioxythio
103  from three types of pi-conjugated polymers: polyaniline, polypyrrole, and polythiophene.
104 ers of conducting polymer nanofibers such as polyaniline, polythiophene, and poly(3-hexylthiophene) c
105                                              Polyaniline possesses a well-defined local atomic arrang
106 ese pores to form a microarray of conductive polyaniline protrusions.
107 to a battery type discharge reaction wherein polyaniline redox energy changes from the conducting to
108                    Homogeneous nucleation of polyaniline results in nanofibers, while heterogeneous n
109 s been found that a Pt electrode coated with polyaniline satisfies all the above requirements.
110  mechanism of the resistance decrease is the polyaniline self-doping, i.e., as an alternative to prot
111 ymerization technique was adapted to produce polyaniline sensing layers doped with poly(4-styrenesulf
112  increase in porosity, for example, when the polyaniline shell is swollen using small amounts of DMF
113 introduced (gold triangular nanoprism core)/(polyaniline shell) nanoparticles (GTNPs@PANI) as an OCT
114 he gaps are bridged with conducting polymer (polyaniline) so that one can measure the conductance of
115 des featuring 4-nm underlayers of sulfonated polyaniline (SPAN) covered with a film containing myoglo
116 mposite through a heating vulcanization of a polyaniline-sulfur core-shell structure.
117           Here, we report the synthesis of a polyaniline-sulfur yolk-shell nanocomposite through a he
118                                            A Polyaniline-Supercapacitor with quinone electrolytes rem
119 s resulting in decreased conductivity of the polyaniline thin film.
120 llustrated by electrophoretically patterning polyaniline thin films onto selected individual micromet
121 xide first oxidizes HRP, which then oxidizes polyaniline, thus resulting in decreased conductivity of
122 ility by preventing the conversion of porous polyaniline to a highly reactive state.
123  for covalent immobilization of human IgG on polyaniline using glutaraldehyde as the cross-linker is
124  of MIP was photochemically grafted over the polyaniline, via N,N'-diethyldithiocarbamic acid benzyl
125 uced grapheme oxide (rGO), vinyl substituted polyaniline (VS-PANI) and lutetium Phthalocyanine (LuPc2
126  a unique tetragonal star-like morphology of polyaniline was applied as a efficient solid phase for s
127                                              Polyaniline was electrodeposited onto the sensors and th
128                                              Polyaniline was electrodeposited onto the sensors and th
129                                              Polyaniline was electrodeposited onto the sensors, and t
130                                              Polyaniline was electropolymerized within these pores to

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