Inorganic–organic interfaces in hybrid solar cells

Niederhausen, Jens; Mazzio, Katherine A.; MacQueen, Rowan W.

doi:10.1088/2516-1075/ac23a3

Cited by 28 publications

(25 citation statements)

References 446 publications

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“…The functionality of virtually all organic and hybrid (opto-)electronic devices depends on interface energetics, and a thorough understanding of energy-level alignment mechanisms at organic-metal and organic-organic interfaces is indispensable for further efficiency improvements [1][2][3][4][5]. For example, the energy-level offset at the donor-acceptor interface in organic photovoltaic devices is crucial for exciton dissociation [6][7][8]; chemisorbed molecular monolayers on metals can tune the substrate work functions by an interfacial charge transfer [9,10] and allow, consequently, to lower charge injection barriers into electrodes [11,12].…”

Section: Introductionmentioning

confidence: 99%

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Advanced characterization of organic–metal and organic–organic interfaces: from photoelectron spectroscopy data to energy-level diagrams

et al. 2022

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Organic-metal and organic-organic interfaces account for the functionality of virtually all organic optoelectronic applications and the energy-level alignment is of particular importance for device performance. Often the energy-level alignment is simply estimated by metal work functions and ionization energies and electron affinities of the organic materials. However, various interfacial effects such as push back, mirror forces (also known as screening), electronic polarization or charge transfer affect the energy-level alignment. We perform X-ray and ultraviolet photoelectron spectroscopy (XPS and UPS) measurements on copper-hexadecafluorophthalocyanine (F16CuPc) and titanyl-phthalocyanine (TiOPc) thin films on Ag(111) and use TiOPc bilayers to decouple F16CuPc layers from the metal substrate. Even for our structurally well-characterized model interfaces and by stepwise preparation of vacuum-sublimed samples, a precise assignment of vacuum-level and energy-level shifts remains challenging. Nevertheless, our results provide guidelines for the interpretation of XPS and UPS data of organic-metal and organic-organic interfaces.

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Section: Introductionmentioning

confidence: 99%

“…(1) The push-back effect decreases the VL at both interfaces (figures 1(a) and (b)) upon deposition of the contact layer (1 ML) [5,42]. (2) The bond dipole increases the VL due to interfacial charge transfer at the chemisorptive interface (figure 1(a)) [39,43].…”

Section: Introductionmentioning

confidence: 99%

Advanced characterization of organic–metal and organic–organic interfaces: from photoelectron spectroscopy data to energy-level diagrams

et al. 2022

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“…The electronic interactions in h OI materials have been extensively studied particularly for sensing, energy storage and energy conversion applications ( Kumar et al, 2018 ; Singh et al, 2019 ; Duan et al, 2020 ; Niederhausen et al, 2021 ; Rathnayake et al, 2021 ; Zhang et al, 2021 ). The electronic interactions in these h OI materials and interfaces are mostly via proximity of the π -cloud of the organic phase with the inorganic surface, and thus Class I h OI materials are the most studied for these purposes.…”

Section: Mixed Ionic-electronic Transport Of H Oi ...mentioning

confidence: 99%

Hybrid Organic-Inorganic Materials and Interfaces With Mixed Ionic-Electronic Transport Properties: Advances in Experimental and Theoretical Approaches

et al. 2022

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The main goal of this mini-review is to provide an updated state-of-the-art of the hybrid organic-inorganic materials focusing mainly on interface phenomena involving ionic and electronic transport properties. First, we review the most relevant preparation techniques and the structural features of hybrid organic-inorganic materials prepared by solution-phase reaction of inorganic/organic precursor into organic/inorganic hosts and vapor-phase infiltration of the inorganic precursor into organic hosts and molecular layer deposition of organic precursor onto the inorganic surface. Particular emphasis is given to the advances in joint experimental and theoretical studies discussing diverse types of computational simulations for hybrid-organic materials and interfaces. We make a specific revision on the separately ionic, and electronic transport properties of these hybrid organic-inorganic materials focusing mostly on interface phenomena. Finally, we deepen into mixed ionic-electronic transport properties and provide our concluding remarks and give some perspectives about this growing field of research.

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“…The energy-level alignment (ELA) at the ubiquitous interfaces of (opto-)electronic applications is decisive for device performance [1][2][3]. Actually, hybrid organic-inorganic interfaces can add functionality to devices, e.g., they can serve as charge-carrier selective contacts for photovoltaic cells [4,5] and thin layers of organic semiconductors (OSCs) can tune ELA at such interfaces [6]. The ELA between inorganic semiconductors like Si and OSCs can be rather complex, e.g., for rodlike organic semiconductors like pentacene or tetracene the orientation of the long molecular axis with respect to the surface ('standing' or 'lying' molecules) is decisive for ELA [7,8].…”

Section: Introductionmentioning

confidence: 99%

“…The ELA between inorganic semiconductors like Si and OSCs can be rather complex, e.g., for rodlike organic semiconductors like pentacene or tetracene the orientation of the long molecular axis with respect to the surface ('standing' or 'lying' molecules) is decisive for ELA [7,8]. In the absence of chemical interaction, ELA is mainly determined by the substrate work function (WF) and the ionization energy (IE) and electron affinity (EA) of the OSC thin film [3,5]. In addition to these quantities also the width of the density of states (DOS) of the frontier molecular orbitals (highest occupied molecular orbital, HOMO and lowest unoccupied molecular orbital, LUMO) of the OSC thin film plays an important role for ELA, in particular, if Fermi-level pinning is involved [9,10].…”

Section: Introductionmentioning

confidence: 99%

Energetic disorder impacts energy-level alignment of alpha-sexithiophene on hydrogen-terminated silicon and silicon oxide

Chen¹,

Hu²,

Wang³

et al. 2022

Mater. Res. Express

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The energy-level alignment at hybrid organic-inorganic interfaces is decisive for the performance of (opto-)electronic devices. We use ultraviolet and X-ray photoelectron spectroscopy (UPS and XPS) to measure the energy-level alignment of vacuum-sublimed -sexithiophene (6T) thin films with HF-etched n-type Si(100) and with Si with a native oxide layer (SiOx). The 6T thin films induce a small (<0.1 eV) downwards band bending into both substrates as shown by XPS. The well-ordered growth of 6T on Si leads to a relatively narrow density of states (DOS) distribution of the highest occupied molecular orbital (HOMO) as shown by UPS. Furthermore, the Fermi-level comes to lie at rather mid-gap position and, consequently, no energy-level bending occurs in the 6T layer. Structural disorder in the 6T thin film on SiOx leads to a broad HOMO DOS distribution and to tailing states into the energy gap. Consequently, downwards energy-level bending (by around 0.20 eV) takes place in the 6T layer.

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Inorganic–organic interfaces in hybrid solar cells

Cited by 28 publications

References 446 publications

Advanced characterization of organic–metal and organic–organic interfaces: from photoelectron spectroscopy data to energy-level diagrams

Advanced characterization of organic–metal and organic–organic interfaces: from photoelectron spectroscopy data to energy-level diagrams

Hybrid Organic-Inorganic Materials and Interfaces With Mixed Ionic-Electronic Transport Properties: Advances in Experimental and Theoretical Approaches

Energetic disorder impacts energy-level alignment of alpha-sexithiophene on hydrogen-terminated silicon and silicon oxide

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