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1. Large Polarization and Susceptibilities in Artificial Morphotropic Phase Boundary PbZr _{1− x} Ti _x O ₃ Superlattices

   https://doi.org/10.1002/aelm.201901395  

   Lupi, Eduardo; Ghosh, Anirban; Saremi, Sahar; Hsu, Shang‐Lin; Pandya, Shishir; Velarde, Gabriel; Fernandez, Abel; Ramesh, Ramamoorthy; Martin, Lane_W (January 2020, Advanced Electronic Materials)

   Abstract The ability to produce atomically precise, artificial oxide heterostructures allows for the possibility of producing exotic phases and enhanced susceptibilities not found in parent materials. Typical ferroelectric materials either exhibit large saturation polarization away from a phase boundary or large dielectric susceptibility near a phase boundary. Both large ferroelectric polarization and dielectric permittivity are attained wherein fully epitaxial (PbZr_0.8Ti_0.2O₃)_n/(PbZr_0.4Ti_0.6O₃)_2n(n= 2, 4, 6, 8, 16 unit cells) superlattices are produced such that the overall film chemistry is at the morphotropic phase boundary, but constitutive layers are not. Long‐ (n≥ 6) and short‐period (n= 2) superlattices reveal large ferroelectric saturation polarization (P_s= 64 µC cm⁻²) and small dielectric permittivity (ε_r≈ 400 at 10 kHz). Intermediate‐period (n= 4) superlattices, however, exhibit both large ferroelectric saturation polarization (P_s= 64 µC cm⁻²) and dielectric permittivity (ε_r= 776 at 10 kHz). First‐order reversal curve analysis reveals the presence of switching distributions for each parent layer and a third, interfacial layer wherein superlattice periodicity modulates the volume fraction of each switching distribution and thus the overall material response. This reveals that deterministic creation of artificial superlattices is an effective pathway for designing materials with enhanced responses to applied bias. 

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2. Memristive Behavior Enabled by Amorphous–Crystalline 2D Oxide Heterostructure

   https://doi.org/10.1002/adma.202000801  

   Yin, Xin; Wang, Yizhan; Chang, Tzu‐hsuan; Zhang, Pei; Li, Jun; Xue, Panpan; Long, Yin; Shohet, J_Leon; Voyles, Paul_M; Ma, Zhenqiang; et al (April 2020, Advanced Materials)

   Abstract The emergence of memristive behavior in amorphous–crystalline 2D oxide heterostructures, which are synthesized by atomic layer deposition (ALD) of a few‐nanometer amorphous Al₂O₃layers onto atomically thin single‐crystalline ZnO nanosheets, is demonstrated. The conduction mechanism is identified based on classic oxygen vacancy conductive channels. ZnO nanosheets provide a 2D host for oxygen vacancies, while the amorphous Al₂O₃facilitates the generation and stabilization of the oxygen vacancies. The conduction mechanism in the high‐resistance state follows Poole–Frenkel emission, and in the the low‐resistance state is fitted by the Mott–Gurney law. From the slope of the fitting curve, the mobility in the low‐resistance state is estimated to be ≈2400 cm²V⁻¹s⁻¹, which is the highest value reported in semiconductor oxides. When annealed at high temperature to eliminate oxygen vacancies, Al is doped into the ZnO nanosheet, and the memristive behavior disappears, further confirming the oxygen vacancies as being responsible for the memristive behavior. The 2D heterointerface offers opportunities for new design of high‐performance memristor devices. 

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3. Flexible Nanogenerators Based on Enhanced Flexoelectricity in Mn ₃ O ₄ Membranes

   https://doi.org/10.1002/smll.202307167  

   Chowde Gowda, Chinmayee; Cavin, John; Kumbhakar, Partha; Tiwary, Chandra Sekhar; Mishra, Rohan (December 2023, Small)

   Abstract Atomically thin, few‐layered membranes of oxides show unique physical and chemical properties compared to their bulk forms. Manganese oxide (Mn₃O₄) membranes are exfoliated from the naturally occurring mineral Hausmannite and used to make flexible, high‐performance nanogenerators (NGs). An enhanced power density in the membrane NG is observed with the best‐performing device showing a power density of 7.99 mW m⁻²compared to 1.04 µW m⁻²in bulk Mn₃O₄. A sensitivity of 108 mV kPa⁻¹for applied forces <10 N in the membrane NG is observed. The improved performance of these NGs is attributed to enhanced flexoelectric response in a few layers of Mn₃O₄. Using first‐principles calculations, the flexoelectric coefficients of monolayer and bilayer Mn₃O₄are found to be 50–100 times larger than other 2D transition metal dichalcogenides (TMDCs). Using a model based on classical beam theory, an increasing activation of the bending mode with decreasing thickness of the oxide membranes is observed, which in turn leads to a large flexoelectric response. As a proof‐of‐concept, flexible NGs using exfoliated Mn₃O₄membranes are made and used in self‐powered paper‐based devices. This research paves the way for the exploration of few‐layered membranes of other centrosymmetric oxides for application as energy harvesters. 

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4. The Role of Oxygen Transfer in Oxide Heterostructures on Functional Properties

   https://doi.org/10.1002/admi.202101867  

   Corey, Zachary; Han, Henry_H; Kang, Kyeong_Tae; Wang, Xuejing; Lalk, Rebecca_A; Paudel, Binod; Roy, Pinku; Sharma, Yogesh; Yoo, Jinkyoung; Jia, Quanxi; et al (January 2022, Advanced Materials Interfaces)

   Abstract A variety of mechanisms are reported to play critical roles in contributing to the high carrier/electron mobility in oxide/SrTiO₃(STO) heterostructures. By using La_0.95Sr_0.05TiO₃(LSTO) epitaxially grown on different single crystal substrates (such as STO, GdScO₃, LaAlO₃, (LaAlO₃)_0.3(Sr₂AlTaO₆)_0.7, and CeO₂buffered STO) as the model systems, the formation of a conducting substrate surface layer (CSSL) on STO substrate is shown at relatively low growth temperature and high oxygen pressure (725 °C, 5 × 10^–4 Torr), which contributes to the enhanced conductivity of the LSTO/STO heterostructures. Different from the conventional oxygen vacancy model, this work reveals that the formation of the CSSL occurs when growing an oxide layer (LSTO in this case) on STO, while neither annealing nor the growth of an Au layer alone at the exact same growth condition generates the CSSL in STO. It demonstrates that the oxide layer actively pulls oxygen from STO substrate at given growth conditions, leading to the formation of the CSSL. The observations emphasize the oxygen transfer across film/substrate interface during the synthesis of oxide heterostructures playing a critical role in functional properties. 

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5. Interfacial charge transfer and its impact on transport properties of LaNiO ₃ /LaFeO ₃ superlattices

   https://doi.org/10.1126/sciadv.adq6687  

   Wang, Le; Yang, Zhifei; Koirala, Krishna Prasad; Bowden, Mark E; Freeland, John W; Sushko, Peter V; Kuo, Cheng-Tai; Chambers, Scott A; Wang, Chongmin; Jalan, Bharat; et al (December 2024, Science Advances)

   Charge transfer or redistribution at oxide heterointerfaces is a critical phenomenon, often leading to remarkable properties such as two-dimensional electron gas and interfacial ferromagnetism. Despite studies on LaNiO₃/LaFeO₃superlattices and heterostructures, the direction and magnitude of the charge transfer remain debated, with some suggesting no charge transfer due to the high stability of Fe³⁺(3d⁵). Here, we synthesized a series of epitaxial LaNiO₃/LaFeO₃superlattices and demonstrated partial (up to ~0.5 e⁻/interface unit cell) charge transfer from Fe to Ni near the interface, supported by density functional theory simulations and spectroscopic evidence of changes in Ni and Fe oxidation states. The electron transfer from LaFeO₃to LaNiO₃and the subsequent rearrangement of the Fe 3d band create an unexpected metallic ground state within the LaFeO₃layer, strongly influencing the in-plane transport properties across the superlattice. Moreover, we establish a direct correlation between interfacial charge transfer and in-plane electrical transport properties, providing insights for designing functional oxide heterostructures with emerging properties. 

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