Plasmonic Photosensitization of a Wide Band Gap Semiconductor: Converting Plasmons to Charge Carriers

Mubeen, Syed; Hernandez‐Sosa, Gerardo; Moses, D.; Lee, Joun; Moskovits, Martin

doi:10.1021/nl203457v

Cited by 396 publications

(337 citation statements)

References 35 publications

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“…First, Tatsuma et al [37,38,45] and other workers [42,46] proposed that the photoexcited electrons in the metal nanoparticles transferred from the metal particle to the TiO2 conduction band since the photoresponse of these metal-TiO2 diode structures was consistent with the absorption spectra of Au or Ag nanoparticles. Second, Kamat et al [43,44] and Li et al [47] have suggested that the noble metal nanoparticles act as electron sinks or traps in the metal-TiO2 diode structures to accumulate the photogenerated electrons, which could minimize charge recombination in the semiconductor films.…”

Section: Review Of Metal-insulator-metal (Mim) Diodesmentioning

confidence: 94%

“…However, in these recent metal-TiO2 Schottky diode structures [37][38][39][40][41][42][43][44][45][46][47], it would appear that the barrier layer was actually quite a bit thicker than 10 nm (probably in excess of 1 um) and further details was unable to be found in these papers. Semi-classical models did not account for non-equilibrium energy distributions of carriers, or do so through a localize lattice temperature.…”

Section: Theoretical Modeling Of Ag-tio2-ti Mim Diodesmentioning

confidence: 98%

“…Furthermore, different explanations have been presented about the role of metal nanoparticles in the observed improvement in light conversion efficiency. These include (i) metal nanoparticles increased absorption due to surface plasmons and light trapping effects [41], (ii) metal nanoparticles functioned as electron donor promoting electron transfer from metal to semiconductor [37,38,42] and (iii) metal nanoparticles served as electron trapping media that can minimize the surface charge recombination in semiconductor [43 , 44].…”

Section: Review Of Metal-insulator-metal (Mim) Diodesmentioning

confidence: 99%

See 2 more Smart Citations

Plasmonic Rectenna for Efficient Conversion of Light into Electricity

Chen¹,

Liu²,

Alemu³

2012

Plasmonics - Principles and Applications

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Section: Review Of Metal-insulator-metal (Mim) Diodesmentioning

confidence: 94%

Section: Theoretical Modeling Of Ag-tio2-ti Mim Diodesmentioning

confidence: 98%

Section: Review Of Metal-insulator-metal (Mim) Diodesmentioning

confidence: 99%

See 1 more Smart Citation

Plasmonic Rectenna for Efficient Conversion of Light into Electricity

Chen¹,

Liu²,

Alemu³

2012

Plasmonics - Principles and Applications

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“…A spectroscopic transition, which normally takes place in the UV, can in this case be excited by visible light 35 . The electron has sufficient energy to cross the space charge layer 105,106 , resulting in a significant photocurrent 107,108 . The hole remaining in the metal close to the Fermi level assists the mechanistically complex oxidation reactions at the Au surface, with the reduction reactions possibly driven unconventionally at the semiconductor 109 .…”

Section: Supplementary Led Illuminationmentioning

confidence: 99%

Capturing Irradiation with Nanoantennae: Plasmon‐Induced Enhancement of Photoelectrolysis

2017

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In solving the energy challenge of solar irradiation′s inconsistency, a desirable approach is mimicking nature′s photosynthesis by collecting and storing solar energy via water splitting. TiO2 is a promising candidate, a wide‐gap semiconductor with low cost, high efficiencies in the UV region, and photostability. Its shortcomings in the visible spectrum can be improved via band gap engineering, mainly co‐catalyst doping, thereof Au nanoparticles. In contrast, we deposit a structured semiconductor on a plasmonic‐active co‐catalyst: we reverse the species order with respect to illumination and achieve a patterned structure for both species in which TiO2 pillars are grown on a Raman‐active Au substrate. The pillars act as antennae, coupling incoming light absorption while feeding on the substrate′s plasmonic effects. The aforementioned system shows impressive incident‐photon‐to‐current efficiencies (IPCEs) in the visible region, along with increased photocurrents in the UV and red shifts depending on deposition depth, diameter, and annealing temperature. We were able to tune the system′s photoresponse by changing the nanostructure geometry and therewith tuned the resonance to the incoming irradiation.

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“…Due to the strongly enhanced EM field at the nanowire gaps, this system were also used in plasmonic catalysis, such as water splitting and the reaction of PATP to DMAB 94, 95, 96. In this remote sensing system, the silver nanowire array was used as a probe, which can be attached to a catheter or an optical fiber to collect remote SERS signals in biological cell or liquids 55.…”

Section: Plasmonic Waveguide For Remote‐excitationmentioning

confidence: 99%

Propagating Surface Plasmon Polaritons: Towards Applications for Remote‐Excitation Surface Catalytic Reactions

et al. 2015

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Plasmonics is a well‐established field, exploiting the interaction of light and metals at the nanoscale; with the help of surface plasmon polaritons, remote‐excitation can also be observed by using silver or gold plasmonic waveguides. Recently, plasmonic catalysis was established as a new exciting platform for heterogeneous catalytic reactions. Recent reports present remote‐excitation surface catalytic reactions as a route to enhance the rate of chemical reactions, and offer a pathway to control surface catalytic reactions. In this review, we focus on recent advanced reports on silver plasmonic waveguide for remote‐excitation surface catalytic reactions. First, the synthesis methods and characterization techniques of sivelr nanowire plasmonic waveguides are summarized, and the properties and physical mechanisms of plasmonic waveguides are presented in detail. Then, the applications of plasmonic waveguides including remote excitation fluorescence and SERS are introduced, and we focus on the field of remote‐excitation surface catalytic reactions. Finally, forecasts are made for possible future applications for the remote‐excitation surface catalysis by plasmonic waveguides in living cells.

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Plasmonic Photosensitization of a Wide Band Gap Semiconductor: Converting Plasmons to Charge Carriers

Cited by 396 publications

References 35 publications

Plasmonic Rectenna for Efficient Conversion of Light into Electricity

Plasmonic Rectenna for Efficient Conversion of Light into Electricity

Capturing Irradiation with Nanoantennae: Plasmon‐Induced Enhancement of Photoelectrolysis

Propagating Surface Plasmon Polaritons: Towards Applications for Remote‐Excitation Surface Catalytic Reactions

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