Crystal Chemistry, Band-Gap Red Shift, and Electrocatalytic Activity of Iron-Doped Gallium Oxide Ceramics

Mallesham, B.; Roy, Swadipta; Bose, Saptasree; Nair, Aruna N.; Sreeprasad, T. S.; Shutthanandan, V.; Ramana, C. V.

doi:10.1021/acsomega.9b01604

Cited by 51 publications

(37 citation statements)

References 55 publications

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“…The situation will be even more complex for the engineering of electronic transitions and bandgaps by alloying Ga 2 O 3 , for example with aluminum, [31] iron, [32] or titanium. [33] But nevertheless, related samples can be studied by the nonconventional approach of SPV measurements proposed in this work. For example, several transition energies and broadening parameters have been obtained or estimated for β-Ga 2 O 3 by fitting positive and negative slopes of transient and modulated SPV spectra in the AC regime.…”

Section: Discussionmentioning

confidence: 99%

Surface Photovoltage Spectroscopy over Wide Time Domains for Semiconductors with Ultrawide Bandgap: Example of Gallium Oxide

Dittrich

Fengler

Nickel

2021

Physica Status Solidi (a)

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Semiconductors with ultrawide bandgap (E g ), such as Ga 2 O 3 , can be applied, for example, in power electronics and optoelectronic devices due to their high breakdown voltage and transparency, respectively. [1][2][3] Aside this, semiconductors with ultrawide bandgap are also of increasing interest for solar energy conversion. For example, Ga 2 O 3 layers can serve as passivation, transparent ohmic contact or charge-selective contact layers as shown in solar cells based on Cu(In,Ga)Se 2 , [4] c-Si, [5] or Cu 2 O [6] absorbers, respectively. Furthermore, Ga 2 O 3 is of great interest for photocatalytic water splitting. As very few examples, the role of copper and chromia-based cocatalysts on Ga 2 O 3 , [7] of mixed-phase junctions based on β-Ga 2 O 3 /α-Ga 2 O 3 , [8,9] of zinc and lead dopants in Ga 2 O 3 [10] or of nickel oxide cocatalysts on α-Ga 2 O 3 [11] for photocatalytic activity and photocatalytic water splitting were investigated empirically and by firstprinciple studies, respectively.Electronic states in the bandgap are crucial for the operation of electronic, optoelectronic, solar cell, and photocatalytic devices. Therefore, the characterization of electronic states and the study of their interactions is decisive for the engineering of electronic states and the further development of devices. Energy levels of deep defect states in Ga 2 O 3 were obtained using deeplevel transient spectroscopy (DLTS) [12,13] and Hall effect measurements at high temperatures. [14] Several transition energies were measured by cathodoluminescence spectroscopy. [15] However, reliable data about defect states and electronic transitions in Ga 2 O 3 are sparse and the characterization of electronic transitions and their impact on electronic properties of semiconductors with ultrawide bandgap over the entire E g is often challenging.Surface photovoltage (SPV) techniques provide universal tools for the highly sensitive analysis and investigation of electronic states in semiconductors. [16,17] Recently, for example, transitions and charge transfer processes were studied in c-Si/TiO 2 and CuBi 2 O 4 heterojunctions by transient [18] and modulated [19] SPV spectroscopy, respectively, and the bulk photovoltaic effect has been shown for excitation from defect states in carbon-doped GaN. [20] Incidentally, one SPV spectrum has been shown for Ga 2 O 3 in the work of Gao et al., [15] but in our opinion, the signal-to-noise ratio was insufficient to extract energy levels in a reliable manner.Fast and robust SPV measurements are carried out in the fixed capacitor arrangement [21] for achieving short resolution times (below 1 ns, [22] transient measurements) or high sensitivity (range of 100 nV, [23] modulated measurements). In the fixed capacitor arrangement, an electrode based on a transparent conducting oxide (TCO) and an insulating foil between the sample and the electrode are used for forming the measurement capacitor for capacitive out-coupling of SPV signals. However, optical absorption in the TCO electrode and in the insulating fo...

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Section: Discussionmentioning

confidence: 99%

Surface Photovoltage Spectroscopy over Wide Time Domains for Semiconductors with Ultrawide Bandgap: Example of Gallium Oxide

Dittrich

Fengler

Nickel

2021

Physica Status Solidi (a)

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“…39 Furthermore, in our recent work, we reported an approach to derive electrocatalytic activity, which is otherwise not possible, in oxide materials. 40 Iron-mixed Ga-oxide demonstrated appreciable electrocatalytic activity toward the generation of H 2 through electrocatalytic water splitting. 40 The electrocatalytic activity of Fe-doped Ga-oxide compounds is attributed to the cumulative effect of different mechanisms, such as Fe-doping induced new catalytic centers and enhanced conductivity due to Fe chemical states.…”

Section: Introductionmentioning

confidence: 99%

“…40 Iron-mixed Ga-oxide demonstrated appreciable electrocatalytic activity toward the generation of H 2 through electrocatalytic water splitting. 40 The electrocatalytic activity of Fe-doped Ga-oxide compounds is attributed to the cumulative effect of different mechanisms, such as Fe-doping induced new catalytic centers and enhanced conductivity due to Fe chemical states. 40 In view of these considerations, the present work was focused toward the synthesis, electronic structure determination, and electrocatalytic activity evaluation of Fe, Ta co-doped BFTO compounds.…”

Section: Introductionmentioning

confidence: 99%

“…40 The electrocatalytic activity of Fe-doped Ga-oxide compounds is attributed to the cumulative effect of different mechanisms, such as Fe-doping induced new catalytic centers and enhanced conductivity due to Fe chemical states. 40 In view of these considerations, the present work was focused toward the synthesis, electronic structure determination, and electrocatalytic activity evaluation of Fe, Ta co-doped BFTO compounds. From electrocatalysis point of view, the scientific merit and significance of the present work can be further understood as follows.…”

Section: Introductionmentioning

confidence: 99%

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Electronic Structure, Chemical Bonding, and Electrocatalytic Activity of Ba(Fe_0.7Ta_0.3)O_3−δ Compounds

Ramana

Mallesham

Nair

et al. 2021

ACS Appl. Energy Mater.

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Ba(Fe 0.7 Ta 0.3 )O 3-δ (BFTO) compounds were synthesized using a conventional, high-temperature solid-state ceramic reaction method by varying the sintering temperature (T s = 1200−1350 °C). The crystal structure, electronic structure, and electrocatalytic activity of BFTO compounds were evaluated. The processing temperature induced phase transformations and structural quality influences the electronic structure and electrocatalytic activity of BFTO compounds. At T s = 1200 °C, Ba(Fe 0.7 Ta 0.3 )O 3−δ stabilizes as a mixture of the orthorhombic + rhombohedral phase (Amm2 + R3m). With increasing T s (≥1250 °C), Ba(Fe 0.7 Ta 0.3 )O 3−δ ceramics stabilize in tetragonal + rhombohedral [P4mm + R3m] mixed phase with a variation in the number of respective phases. Highresolution X-ray photoelectron spectroscopy (XPS) of constituent elements, namely, Ba 3d, Fe 2p, Ta 4f, and O 1s levels reveals the electronic structure changes due to changes in the chemical environment resulted from structural transformation. The XPS analyses indicate that the processing temperature significantly influences the chemical environment of Fe and Ta cations in BFTO. The Ba 3d 5/2 core-level XPS spectra indicate that the perovskite phase gradually increases with increasing sintering temperature. The presence of absorption bands that are exclusively due to MO 6 stretching vibration that is connected to Ba ion as well as stretching of M−O bonds in infrared spectroscopy data indicate the structural and chemical quality of the BFTO compounds. The electrocatalytic activity of BFTO was evaluated toward hydrogen evolution reaction (HER) and oxygen reduction reaction (ORR). Though all of the samples demonstrated appreciable electrocatalytic properties, the best electrochemical catalytic activity was shown by BFTO samples sintered at 1350 °C. BFTO-1350 °C showed an onset potential of −0.690 V vs reversible hydrogen electrode (RHE) for HER and an onset potential of 0.73 V vs RHE for ORR indicating its significant electrocatalytic performance. A general increase in activity with sintering temperature is potentially due to the improved structural quality of the BFTO ceramics. In addition to offering the fundamental insights into perovskite materials based on co-doped BaTiO 3 for electrocatalysis, the present work may contribute to the design and development of materials using co-doping of different chemical valence cations for other energy-related applications.

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“…14,18 The electrical breakdown voltage is exceptionally high 8 MV/cm, which in comparison to SiC and GaN, 2.5 and 3.3 MV/cm, respectively, is in multiples. 13,19,20 These properties make -Ga 2 O 3 a suitable candidate for a wide variety of energy, electronic, power, optoelectronics, and catalysis applications, which include solar blind UV-photodetectors, 5,12,14,21 light emitting diodes (LEDs) , 22,23 transparent conducting oxide electrodes (TCOs) , 24,25 photo-and electro-catalysts, [26][27][28] high-temperature sensors, 29,30 high power electronic devices [11][12][13][14]31,32 with a potential to dwarf the existing SiN, Si and GaN devices in terms of performance. On the other hand, the potential for Ga 2 O 3 to derive new properties and phenomena, which can facilitate designing materials especially for energy related applications, is continually evolving.…”

Section: Introductionmentioning

confidence: 99%

Chemical composition tuning induced variable and enhanced dielectric properties of polycrystalline Ga_2‐2xW_xO₃ ceramics

Zade

Rajkumar

Broner

et al. 2020

Engineering Reports

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We report on the tunable and enhanced dielectric properties of tungsten (W) incorporated gallium oxide (Ga 2 O 3) polycrystalline electroceramics for energy and power electronic device applications. The W-incorporated Ga 2 O 3 (Ga 2−2x W x O 3 , 0.00 ≤ x ≤ 0.20; GWO) compounds were synthesized by the high-temperature solid-state chemical reaction method by varying the W-content. The fundamental aspects of the dielectric properties in correlation with the crystal structure, phase, and microstructure of the GWO polycrystalline compounds has been investigated in detail. A detailed study performed ascertains the W-induced changes in the dielectric constant, loss tangent (tan δ) and ac conductivity. It was found that the dielectric constant increases with addition of W in the system as a function of temperature (25 • C-500 • C). Frequency dependence (10 2-10 6 Hz) of the dielectric constant follows the modified Debye model with a relaxation time of ∼20 to 90 μs and a spreading factor of 0.39 to 0.65. The dielectric constant of GWO is temperature independent almost until ∼300 • C, and then increases rapidly in the range of 300 • C to 500 • C. W-induced enhancement in the dielectric constant of GWO is fully evident in the frequency and temperature dependent dielectric studies. The frequency and temperature dependent tan δ reveals the typical behavior of relaxation loses in GWO. Small polaron hopping mechanism is evident in the frequency dependent electrical transport properties of GWO. The remarkable effect of W-incorporation on the dielectric and electrical transport properties of Ga 2 O 3 is explained by a two-layer heterogeneous model consisting of thick grains separated by very thin grain boundaries along with the formation of a Ga 2 O 3-WO 3 composite was able to account for the observed temperature and frequency dependent electrical properties in GWO. The results demonstrate that the structure, electrical and dielectric properties can be tailored by tuning W-content in the GWO compounds.

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Crystal Chemistry, Band-Gap Red Shift, and Electrocatalytic Activity of Iron-Doped Gallium Oxide Ceramics

Cited by 51 publications

References 55 publications

Surface Photovoltage Spectroscopy over Wide Time Domains for Semiconductors with Ultrawide Bandgap: Example of Gallium Oxide

Surface Photovoltage Spectroscopy over Wide Time Domains for Semiconductors with Ultrawide Bandgap: Example of Gallium Oxide

Electronic Structure, Chemical Bonding, and Electrocatalytic Activity of Ba(Fe_0.7Ta_0.3)O_3−δ Compounds

Chemical composition tuning induced variable and enhanced dielectric properties of polycrystalline Ga_2‐2xW_xO₃ ceramics

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Crystal Chemistry, Band-Gap Red Shift, and Electrocatalytic Activity of Iron-Doped Gallium Oxide Ceramics

Cited by 51 publications

References 55 publications

Surface Photovoltage Spectroscopy over Wide Time Domains for Semiconductors with Ultrawide Bandgap: Example of Gallium Oxide

Surface Photovoltage Spectroscopy over Wide Time Domains for Semiconductors with Ultrawide Bandgap: Example of Gallium Oxide

Electronic Structure, Chemical Bonding, and Electrocatalytic Activity of Ba(Fe0.7Ta0.3)O3−δ Compounds

Chemical composition tuning induced variable and enhanced dielectric properties of polycrystalline Ga2‐2xWxO3 ceramics

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Product

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Electronic Structure, Chemical Bonding, and Electrocatalytic Activity of Ba(Fe_0.7Ta_0.3)O_3−δ Compounds

Chemical composition tuning induced variable and enhanced dielectric properties of polycrystalline Ga_2‐2xW_xO₃ ceramics