Porous Si/eumelanin hybrids are a novel class of organic–inorganic hybrid materials that

hold considerable promise for photovoltaic applications. Current progress toward device setup is,

however, hindered by photocurrent stability issues, which require a detailed understanding of the

mechanisms underlying the buildup and consolidation of the eumelanin–silicon interface. Herein we

report an integrated experimental and computational study aimed at probing interface stability via

surface modification and eumelanin manipulation, and at modeling the organic–inorganic interface

via formation of a 5,6-dihydroxyindole (DHI) tetramer and its adhesion to silicon. The results

indicated that mild silicon oxidation increases photocurrent stability via enhancement of the

DHI–surface interaction, and that higher oxidation states in DHI oligomers create more favorable

conditions for the efficient adhesion of growing eumelanin

Antidormi, Aleandro

Cappellini, Giancarlo

Cardia, Roberto

Colombo, Luciano

D’Ischia, Marco

Melis, Claudio

Mula, Guido

Pinna, Elisa

Sechi, Elisa

International Journal of Molecular Sciences

Porous Si/eumelanin hybrids are a novel class of organic–inorganic hybrid materials that
hold considerable promise for photovoltaic applications. Current progress toward device setup is,
however, hindered by photocurrent stability issues, which require a detailed understanding of the
mechanisms underlying the buildup and consolidation of the eumelanin–silicon interface. Herein we
report an integrated experimental and computational study aimed at probing interface stability via
surface modification and eumelanin manipulation, and at modeling the organic–inorganic interface
via formation of a 5,6-dihydroxyindole (DHI) tetramer and its adhesion to silicon. The results
indicated that mild silicon oxidation increases photocurrent stability via enhancement of the
DHI–surface interaction, and that higher oxidation states in DHI oligomers create more favorable
conditions for the efficient adhesion of growing eumelanin

PINNA, ELISA

MELIS, CLAUDIO

ANTIDORMI, ALEANDRO

CARDIA, ROBERTO

SECHI, ELISA

CAPPELLINI, GIANCARLO

COLOMBO, LUCIANO

MULA, GUIDO

Archivio istituzionale della ricerca - Università di Cagliari

Supplementary information  Deciphering molecular mechanisms of interface buildup and stability in porous Si/eumelanin hybrids  Elisa Pinna 1,2*, Claudio Melis 1,2,* , Aleandro Antidormi 1,2 , Roberto Cardia 1 , Elisa Sechi 1 , Giancarlo Cappellini 1 , Marco d’Ischia 3, Luciano Colombo 1,2 and Guido Mula 1,2 1 Dipartimento di Fisica, Università degli Studi di Cagliari, S.P. 8 km 0.700, 09042 Monserrato (Ca), Italy – e-mail: guido.mula@unica.it 2 Istituto Officina dei Materiali CNR-IOM, unità di Cagliari SLACS, Cittadella Universitaria di Monserrato, S.P. 8 km 0.700, 09042 Monserrato (Ca) – e-mail: luciano.colombo@dsf.unica.it 3 Department of Organic Chemistry and Biochemistry, University of Naples “Federico II”, Via Cintia 4, 80126 Naples, Italy - e-mail: dischia@unina.it * Correspondence: elisa.pinna@dsf.unica.it - +39 070 6754787; claudio.melis@dsf.unica.it - +39 070 6754929 					  Figure S1: Absorbance spectra as a function of time for two different concentrations of DHI in EtOH. (a) 0.25 mg/mL and (b) 0.12 mg/mL. The vertical axis has been kept identical to that of Figure 5 for easier comparison. 43210Absorbance800700600500400300Wavelength (nm)0.25mg DHI in 1mL EtOHAbsorbance spectra recorded every 30'from 0' to 600'(a)43210Absorbance800700600500400300Wavelength (nm)0.12mg DHI in 1mL EtOHAbsorbance spectra recorded every 30'from 0' to 480'(b) Figure S2. Analysis of the evolution of the absorbance spectra of the DHI in EtOH solutions shown in Figure S1 at three different spectral positions: 330 nm, 460 nm and 780 nm. The curves represent the normalized evolution of the absorbance for (a) 0.25 mg/mL and (b) 0.12 mg/mL.   Figure S3. Comparison between the calculated spectra for the PT structure (blue line) and the experimental absorption of 0.25mg/mL solution of DHI in EtOH (red line, curve corresponding to the absorbance of after 600’). (a)(b)PT Figure S4. Comparison of the theoretical/computational spectrum for the PT structure calculated in this work with that reported by Meng and Kaxiras [44]. PTPT

Deciphering Molecular Mechanisms of Interface Buildup and Stability in Porous Si/Eumelanin Hybrids

Elisa Pinna

Claudio Melis

Aleandro Antidormi

Roberto Cardia

Elisa Sechi

Giancarlo Cappellini

Marco d’Ischia

Luciano Colombo

Guido Mula

Crossref

Porous Si/eumelanin hybrids are a novel class of organic-inorganic hybrid materials that hold considerable promise for photovoltaic applications. Current progress toward device setup is, however, hindered by photocurrent stability issues, which require a detailed understanding of the mechanisms underlying the buildup and consolidation of the eumelanin-silicon interface. Herein we report an integrated experimental and computational study aimed at probing interface stability via surface modification and eumelanin manipulation, and at modeling the organic-inorganic interface via formation of a 5,6-dihydroxyindole (DHI) tetramer and its adhesion to silicon. The results indicated that mild silicon oxidation increases photocurrent stability via enhancement of the DHI-surface interaction, and that higher oxidation states in DHI oligomers create more favorable conditions for the efficient adhesion of growing eumelani

D'ISCHIA, MARCO

Archivio della ricerca - Università degli studi di Napoli Federico II

E. Pinna

C. Melis

A. Antidormi

R. Cardia

E. Sechi

G. Cappellini

M. D’Ischia

L. Colombo

G. Mula

Deciphering molecular mechanisms of interface buildup and stability in porous Si/eumelanin hybrids

Porous Si/eumelanin hybrids are a novel class of organic–inorganic hybrid materials that hold considerable promise for photovoltaic applications. Current progress toward device setup is, however, hindered by photocurrent stability issues, which require a detailed understanding of the mechanisms underlying the buildup and consolidation of the eumelanin–silicon interface. Herein we report an integrated experimental and computational study aimed at probing interface stability via surface modification and eumelanin manipulation, and at modeling the organic–inorganic interface via formation of a 5,6-dihydroxyindole (DHI) tetramer and its adhesion to silicon. The results indicated that mild silicon oxidation increases photocurrent stability via enhancement of the DHI–surface interaction, and that higher oxidation states in DHI oligomers create more favorable conditions for the efficient adhesion of growing eumelanin

Marco D’Ischia

Multidisciplinary Digital Publishing Institute

Archivio istituzionale della Ricerca - Scuola Normale Superiore

English

Deciphering Molecular Mechanisms of Interface Buildup and Stability in Porous Si/Eumelanin Hybrids

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Archivio istituzionale della ricerca - Università di Cagliari

Crossref

Archivio della ricerca - Università degli studi di Napoli Federico II

Archivio istituzionale della ricerca - Università di Cagliari

Archivio della ricerca - Università degli studi di Napoli Federico II

Multidisciplinary Digital Publishing Institute

Archivio istituzionale della Ricerca - Scuola Normale Superiore