Measuring Relative Barrier Heights in Molecular Electronic Junctions with Transition Voltage Spectroscopy

Beebe, Jeremy M.; Kim, BongSoo; Frisbie, C. Daniel; Kushmerick, James G.

doi:10.1021/nn700424u

Cited by 263 publications

(454 citation statements)

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“…[34,161,162] Experimentally, it is fairly simple to identify this transition bias (V T ) and indeed, in the study cited, [34,161,162] V T correlated well with the expected barrier height, the difference of the molecular level (highest occupied molecular orbital, HOMO) and the electrode Fermi level as deduced independently by UPS (see, however, Section 5.2). [52,161,162] This approach assumes a roughly linear J-V relation for tunneling transport [161] (i.e., positive ln(J/V 2 ) vs. 1/V slope), and in that case V T indeed indicates a change in transport mechanism to field-emission. However, as the barrier width/height ratio (which we called ''shape factor'' [149,159] ) increases, the tunneling J-V becomes more non-linear.…”

Section: Extracting Insulator Parameters From Current-density-voltagementioning

confidence: 52%

“…[149,159,161,162] One approach postulates that if the applied bias is larger than the barrier height, the transport mechanism changes from direct tunneling to field-emission. [34,161,162] Experimentally, it is fairly simple to identify this transition bias (V T ) and indeed, in the study cited, [34,161,162] V T correlated well with the expected barrier height, the difference of the molecular level (highest occupied molecular orbital, HOMO) and the electrode Fermi level as deduced independently by UPS (see, however, Section 5.2). [52,161,162] This approach assumes a roughly linear J-V relation for tunneling transport [161] (i.e., positive ln(J/V 2 ) vs. 1/V slope), and in that case V T indeed indicates a change in transport mechanism to field-emission.…”

Section: Extracting Insulator Parameters From Current-density-voltagementioning

confidence: 99%

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Molecules on Si: Electronics with Chemistry

et al. 2009

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Basic scientific interest in using a semiconducting electrode in molecule‐based electronics arises from the rich electrostatic landscape presented by semiconductor interfaces. Technological interest rests on the promise that combining existing semiconductor (primarily Si) electronics with (mostly organic) molecules will result in a whole that is larger than the sum of its parts. Such a hybrid approach appears presently particularly relevant for sensors and photovoltaics. Semiconductors, especially Si, present an important experimental test‐bed for assessing electronic transport behavior of molecules, because they allow varying the critical interface energetics without, to a first approximation, altering the interfacial chemistry. To investigate semiconductor‐molecule electronics we need reproducible, high‐yield preparations of samples that allow reliable and reproducible data collection. Only in that way can we explore how the molecule/electrode interfaces affect or even dictate charge transport, which may then provide a basis for models with predictive power.To consider these issues and questions we will, in this Progress Report, review junctions based on direct bonding of molecules to oxide‐free Si. describe the possible charge transport mechanisms across such interfaces and evaluate in how far they can be quantified. investigate to what extent imperfections in the monolayer are important for transport across the monolayer. revisit the concept of energy levels in such hybrid systems.

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Section: Extracting Insulator Parameters From Current-density-voltagementioning

confidence: 52%

Section: Extracting Insulator Parameters From Current-density-voltagementioning

confidence: 99%

Molecules on Si: Electronics with Chemistry

et al. 2009

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“…Their studies revealed that the dominant mechanism of charge transport across these junctions was tunneling for molecular wires shorter than ~ 4 nm, but the mechanism changed to hopping for molecular wires exceeding ~ 4 nm in length. Beebe et al 38,39 showed that A generally accepted mechanism to explain the difference in values of β in "insulating" media is super-exchange tunneling. 44 Interactions of the electrons with the orbitals of the organic molecule increase the probability of tunneling, and make "through-bond" tunneling more efficient than "through-space" tunneling.…”

Section: Mechanisms Of Charge Transport Across Sams Three Different mentioning

confidence: 99%

“…Beebe et al 38,39 described a method to estimate this barrier height. Near zero bias, the barrier shape is rectangular and eq.…”

Section: Mechanisms Of Charge Transport Across Sams Three Different mentioning

confidence: 99%

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A Molecular Half-Wave Rectifier

et al. 2011

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The field of molecular electronics applies the techniques and principles derived from studying inorganic electronic devices to investigating charge transport in organic molecules. While electrical engineers routinely use both alternating current (AC) and direct current (DC) to characterize traditional semiconductor devices, researchers in molecular electronics have, so far, relied mainly on DC measurements. Here, we show that using AC signals to investigate charge transport in self-assembled monolayers (SAMs) yields new information, including information that could not be obtained using DC signals alone, and provides a straightforward means of comparing the performance of molecular diodes against that of diodes based on traditional semiconductor technology.This paper describes half-wave rectification of AC (50 Hz) signals by junctions based on SAMs. These junctions comprised SAMs of 11-(ferrocenyl)-1-undecanethiol (SC 11 Fc) or 11-(biferrocenyl)-1-undecanethiol (SC 11 Fc 2 ), supported on template-stripped Ag (Ag TS ) bottom electrodes, and contacted by top electrodes of eutectic indiumÀgallium (EGaIn, 75.5% Ga and 24.5% In by weight, 15.7 °C melting point, with a superficial layer of Ga 2 O 3 ; Figure 1). 1,2 Similar junctions based on SAMs of 1-undecanethiol (SC 10 CH 3 )-SAMs lacking the ferrocenyl terminal group-did not rectify AC signals.Previous experiments conducted using a DC bias of (1.0 V, and junctions based on SAMs of SC 11 Fc 1 and SC 11 Fc 2 , 3 yielded rectification ratios, R (defined by eq 1, where J is the current density (A/cm 2 ) and V is the voltage (V)), of >10 2 . These high values of R make it possible to conduct physical-organic studies to determine the mechanism(s) of charge transport across these SAMs. We show that these systems-which are, in fact, "molecular diodes"-can substitute for conventional diodes in a simple circuit-a half-wave rectifier (Figure 1)-that converts an input AC signal into an output DC signal. 4These molecular diodes, indeed, provide the basis for halfwave rectifiers. The circuits were stable for 30À40 min of operation, at a frequency of 50 Hz; this interval corresponds to more than 10 5 cycles. At low frequencies (∼1 Hz) and at large input voltages (∼5 V for SC 11 Fc and ∼10 V for SC 11 Fc 2 , see the Results and Discussion section), the junctions broke down more

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