Conger, C. P.Süzer, Şefik2016-02-082016-02-0820090743-7463http://hdl.handle.net/11693/22834A single layer of the Cationic polyelectrolyte poly(allyamine) hydrochloride (PAH) deposited, using the layer-by-layer technique, on a silicon substrate containing 5 nm oxide layer is investigated by XPS while applying an external potential bias to the sample to control and manipulate the charge built-up on the oxide layer. Under application of a -10 V bias, the oxide layer is positively charged due to Photoemission process, evidenced by the measured Si2p binding energy of 104.4 eV. Application of a +10 V bias attracts the low energy neutralizing electrons, stemming from a hot filament, and leads to a negatively charged oxide layer, also evidenced by the measured Si2p binding energy of 102.9 eV. The single polyelectrolyte overlayer also responds to this polarity change of the oxide layer underneath by displaying a somewhat larger shifts both in the C1s and Nls peaks. In addition to the shifts in the positions, the N1s peaks undergo a significant intensity depletion, mostly on the positively charged -N+ component. We interpret this intensity depletion to be the result of reorientation of some of the dangling positively charged groups by moving toward the negatively charged oxide underlayer. To our knowledge this is the first time that a chemically specific response to an electrical stimuli is reported using XPS. A bilayer LbL film consisting of PAH and PSS, exhibits even a larger charging shift, but this time no intensity alteration is observed, most probably due to locking of the -N+ groups by the -SO3 + counterions of the second layer. © 2009 American Chemical Society.EnglishAtomsBinding sitesHot electronsNuclear energyPolyelectrolytesPolymersPotential energySemiconducting silicon compoundsSilicon compoundsSubstratesX ray photoelectron spectroscopyBi layersCationic polyelectrolytesCounter-ionsElectrical stimulusExternal potentialsHot filamentsIntensity alterationsLayer-by-layer techniquesLow energiesOxide layersPhotoemission processPolarity changesPolyelectrolyte layersPositively chargedSecond layersSilicon substratesSingle layersSubstrate chargingUnderlayerXpsBinding energyChemistrySpectroscopyElectrolytesMolecular probesSilicon dioxideSpectrum analysisArticle10.1021/la803305w