Talk:Polyaniline
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Polyaniline and conductive Polymer
[edit]Dear "materialscientist". Please explain what was wrong with my editing of these two subjects which you mainly undid a short while after I edited. I trust my updating was correct (e.g., the use of polyaniline dispersions in printed circuit board manufacturing is widespread). Moreover, the article which I cited (http://www.mdpi.com/2073-4360/2/4/786/) has a high relevance for the understanding of properties and applications of Polyaniline (and conductive polymers in general). There are many other citations in these 2 articles which do not necessarily represent a correct description for Polyaniline / conductive polymers, and even those which I do not agree to, I do not remove them; that would be scientifically unfair and biased. Please incorporate the articvle reference again to offer the readers the chance to build their own opinion. 80.187.110.107 (talk) 12:47, 3 January 2011 (UTC)
- The edits made by 80.187.110.107 appear to have merit except for the deletion of reference to the Li 2006 study which is unexplained in the edit summary. The references cited should be respected. This user should get a user account and should report possible conflicts of interest (for example being an active researcher in the field). The edit made by Materialscientist appears sloppy , it contains much more than just deleting the reference?— Preceding unsigned comment added by V8rik (talk • contribs)
- This discussion was continued at Talk:Conductive polymer. In short, an editor (likely on a floating IP) was promoting addition of a new theory based on unreliable (for such claims) source, presenting a recent primary research article as a review. Materialscientist (talk) 23:46, 1 February 2011 (UTC)
More edits, April 2012
[edit]The article was partly a vehicle to support the cause of PProctor and others who often complain about the Nobel prize that they should have gotten, it seems instead of others for the conductive polymers. Their method is to build up a "history" section that tries to diminish the work of McDiarmid and Heeger by highlighting the fact that many conductive polymers and organic materials were known in the early 60's and 50's. The point of this kind of correcting history essay is just lost on most readers who just want to read about polyaniline. So I removed the articles to polypyrrole and polyacetylene (except the general reviews to conductive polymers). Otherwise the article does not discuss the chemical structure or degree of protonation very much. A lot of the article was about applications, but I have not been able to identify any. We really need to address the structural and chemical aspects of polyaniline in this article.--Smokefoot (talk) 13:04, 16 April 2012 (UTC)
External links modified
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Excised content to be re-considered
[edit]Wikipedia has two guidelines that apply to the material below. Conflict of interest WP:COI and WP:SECONDARY.--Smokefoot (talk) 14:39, 11 February 2018 (UTC)
Since the second half of 70s, J. J. Langer has begun systematic research on electrical properties at Organic Semiconductor Laboratory (UAM Poznań, Poland). <ref name="Langer">{{cite journal|last1=Langer|first1=Jerzy J.|title=Unusual properties of the aniline black. Does the superconductivity exist at room temperature?|journal=Solid State Communications|date=1978|volume=26|page=839|ref=20}}</ref><ref name="Langer1">{{cite journal|last1=Langer|first1=Jerzy J.|title=Aniline black as an unusual organic semiconductor. II|journal=Materials Science|date=1981|volume=7|page=223}}</ref><ref name="Langer2">{{cite journal|last1=Langer|first1=Jerzy J.|title=Aniline black. III. Electrical properties of polymers obtained by anodic oxidation|journal=Materials Science|date=1984|volume=10|page=173}}</ref><ref name="Langer3">{{cite journal|last1=Langer|first1=Jerzy J.|title=Conformations of aniline black (polyaniline) molecules|journal=Synthetic Metals|date=1987|volume=20|page=35}}</ref><ref name="Langer4">{{cite journal|last1=Langer|first1=Jerzy J.|title=An unusual diamagnetism in aniline black (polyaniline)|journal=Journal of Molecular Electronics|date=1989|volume=5|page=103}}</ref><ref name="Langer5">{{cite journal|last1=Langer|first1=Jerzy J.|title=N-substituted polyanilines. I. Poly(N-methylaniline) and related copolymers|journal=Synthetic Metals|date=1990|volume=35|page=295}}</ref><ref name="Langer6">{{cite journal|last1=Langer|first1=Jerzy J.|title=N-substituted polyanilines. II. Photoacoustic and FTIR spectra of poly(N-methylaniline) and related copolyme|journal=Synthetic Metals|date=1990|volume=35|page=301}}</ref><ref name="Langer7">{{cite journal|last1=Langer|first1=Jerzy J.|title=A process leading to the domain structure of aniline black (polyaniline|journal=Synthetic Metals|date=1990|volume=36|page=35}}</ref><ref name="Langer8">{{cite journal|last1=Langer|first1=Jerzy J.|last2=Czajkowski|first2=Igor|title=Polyaniline microrods|journal=Adv. Mat. Opt.& Electronics|date=1997|volume=7|page=149}}</ref> Subsequent to his investigation of other highly-conductive organic materials, MacDiarmid demonstrated the conductive states of polyaniline which arose upon protonic doping of the emeraldine form of polyaniline.<ref name=Chiang>{{cite journal|last=Chiang|first=J.C.|author2=MacDiarmid, A. G. |title='Polyaniline': Protonic Acid Doping of the Emeraldine Form to the Metallic Regime|doi=10.1016/0379-6779(86)90070-6|journal=Synthetic Metals|year=1986|volume=1|issue=13|pages=193}}</ref> Conductive polymers such as polyaniline remain of widespread interest,<ref>{{cite journal|doi=10.1103/RevModPhys.73.681|title=Nobel Lecture: Semiconducting and metallic polymers: The fourth generation of polymeric materials|journal=Reviews of Modern Physics|volume=73|issue=3|pages=681|year=2001|last1=Heeger|first1=Alan|bibcode=2001RvMP...73..681H}}</ref> providing an opportunity to address fundamental issues of importance to condensed matter physics, including, for example, the metal-insulator transition,<ref>{{cite journal|doi=10.1103/PhysRevB.68.245106|title=Applicability of the localization-interaction model to magnetoconductivity studies of polyaniline films at the metal-insulator boundary|journal=Physical Review B|volume=68|issue=24|pages=245106|year=2003|last1=Tzamalis|first1=G.|last2=Zaidi|first2=N.|last3=Monkman|first3=A.|bibcode=2003PhRvB..68x5106T}}</ref> the [[Peierls transition|Peierls Instability]] and [[quantum decoherence]],<ref>{{cite journal|doi=10.1103/PhysRevB.82.144201|title=Crucial role of decoherence for electronic transport in molecular wires: Polyaniline as a case study|journal=Physical Review B|volume=82|issue=14|pages=144201|year=2010|last1=Cattena|first1=Carlos J.|last2=Bustos-Marún|first2=Raúl A.|last3=Pastawski|first3=Horacio M.|bibcode=2010PhRvB..82n4201C}}</ref> the light emission, including SRS LED<ref name="Langer13">{{cite journal|last1=Langer|first1=Jerzy J.|last2=Miładowski|first2=Bartosz|last3=Golczak|first3=Sebastian|last4=Langer|first4=Krzysztof|last5=Stefaniak|first5=Piotr|last6=Adamczak|first6=Anna|last7=Andrzejewska|first7=Magdalena|last8=Sójka|first8=Lucyna|last9=Kalisz|first9=Magdalena|title=Non-linear optical effects (SRS) in nanostructured polyaniline LED|journal=J. Mater. Chem.|date=2010|volume=20|page=3859}}</ref> and random laser electrically powered<ref name="Langer14">{{cite journal|last1=Kalisz|first1=Magdalena|last2=Golczak|first2=Sebastian|last3=Frąckowiak|first3=Ewelina|last4=Langer|first4=Krzysztof|last5=Langer|first5=Jerzy J.|title=Laser action induced in a nanostructured polyaniline LED|journal=J. Mater. Chem. C|date=2016|volume=4|page=6634}}</ref>. <ref name="Langer10">{{cite journal|last1=Langer|first1=Jerzy J.|last2=Langer|first2=Krzysztof|last3=Barczyński|first3=Piotr|last4=Warchoł|first4=Jerzy|last5=Bartkowiak|first5=Kamila|title=NEW "ONOFF"-TYPE NANOBIODETECTOR|journal=Biosensors and Bioelectronics|date=2009|volume=24|page=2947}}</ref><ref name="Langer11">{{cite journal|last1=Langer|first1=Krzysztof|last2=Barczyński|first2=Piotr|last3=Baksalary|first3=Katarzyna|last4=Filipiak|first4=Marian|last5=Golczak|first5=Sebastian|last6=Langer|first6=Jerzy J.|title=A fast and sensitive continuous flow nanobiodetector based on polyaniline nanofibrils|journal=Microchimica Acta|date=2007|volume=159|page=201}}</ref><ref name="Langer12">{{cite journal|last1=Langer|first1=Jerzy J.|last2=Langer|first2=Krzysztof|last3=Michalski|first3=Aleksander|last4=Zabrocka|first4=Longina|last5=Kocik|first5=Janusz|title=Nanobiodetector for spore forming bacteria|journal=Fianl Reports of DARPA Projects|date=2012|page=37}}</ref>. The different colors, charges and conformations of the multiple oxidation states also make the material promising for applications such as [[actuators]], [[supercapacitors]] and [[electrochromics]]. Although polyaniline has been historically considered as a battery material, its intrinsic pseudocapacitive behavior has shifted the energy storage potential to supercapacitors.<ref>{{cite journal|doi=10.1016/j.jpowsour.2017.02.054 |title=Polyaniline Supercapacitors |journal=Journal of Power Sources |volume=347 |pages=86 |year=2017 |last1=Eftekhari |first1=A |last2=Lei |first2=L |last3=Yang |first3=Y}}</ref> Polyaniline is, in fact, the most common conductive polymer for the fabrication of supercapacitors. An interesting feature of polyaniline, as well as other conducting polymers, is the versatility in manufacturing [[electrically conducting yarn]]s, antistatic coatings, electromagnetic shielding, and flexible electrodes. Polyaniline an attractive for acid/base chemical vapor sensors, supercapacitors and biosensors<ref name="Langer9">{{cite journal|last1=Zabrocka|first1=Longina|last2=Langer|first2=Krzysztof|last3=Michalski|first3=Aleksander|last4=Kocik|first4=Janusz|last5=Langer|first5=Jerzy J.|title=A microfluidic device for real-time monitoring of Bacillus subtilis bacterial spores during germination based on non-specific physicochemical interactions on the nanoscale level|journal=Lab on a Chip|date=2015|volume=15|page=274}}</ref> Attractive fields for current and potential utilization of polyaniline is in [[antistatic]]s, charge dissipation or electrostatic dispersive (ESD) coatings and blends, [[electromagnetic interference shielding]] (EMI), [[anticorrosive]] coatings, hole injection layers,<ref>{{cite journal|doi=10.1063/1.2748864 |title=Combination of a polyaniline anode and doped charge transport layers for high-efficiency organic light emitting diodes |journal=Journal of Applied Physics |volume=101 |issue=12 |pages=124509 |year=2007 |last1=Fehse |first1=Karsten |last2=Schwartz |first2=Gregor |last3=Walzer |first3=Karsten |last4=Leo |first4=Karl |bibcode=2007JAP...101l4509F }}</ref> transparent conductors, [[indium tin oxide]] replacements, [[actuators]], chemical vapor and solution based sensors, electrochromic coatings (for color change windows, mirrors etc.), PEDOT-PSS replacements, toxic metal recovery, [[catalysis]], [[fuel cells]] and active electronic components such as for [[non-volatile memory]].
Start of Process section
[edit]The synthesis of polyaniline nanostructures is facile.[13]
The definition of facile is "(especially of a theory or argument) appearing neat and comprehensive only by ignoring the true complexities of an issue; superficial." How the synthesis of polyaniline appears, or seems to be, is subjective and irrelevant. It sounds like someone copied and pasted the lead sentence of one paragraph of a research paper describing the process. It works as a lead sentence, as presumably it would be followed by enumeration and explanation of the "true complexities". As a standalone sentence, however, it's vacuous.
Using surfactant dopants, the polyaniline can be made dispersible and hence useful for practical applications. Bulk synthesis of polyaniline nanofibers, which has been researched extensively.[14]
This is a broad generalization, which again sounds excised from more substantive material. Why are we talking about applications in a section headed "Process"? The second sentence isn't a sentence at all.