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Creators/Authors contains: "Kioussis, Nicholas"

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  1. ; (, Physical Review B)
    Free, publicly-accessible full text available December 1, 2025
  2. ; ; ; ; (, Physical Review Materials)
  3. ; ; ; ; ; ; ; (, Nano Letters)
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  4. ; ; ; (, The Journal of Physical Chemistry C)
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  5. ; ; ; ; ; (, Crystal Growth & Design)
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  6. ; ; ; ; ; ; ; ; ; ; et al (, Advanced Materials)
    Abstract Antiferromagnetic (AFM) materials are a pathway to spintronic memory and computing devices with unprecedented speed, energy efficiency, and bit density. Realizing this potential requires AFM devices with simultaneous electrical writing and reading of information, which are also compatible with established silicon‐based manufacturing. Recent experiments have shown tunneling magnetoresistance (TMR) readout in epitaxial AFM tunnel junctions. However, these TMR structures are not grown using a silicon‐compatible deposition process, and controlling their AFM order required external magnetic fields. Here are shown three‐terminal AFM tunnel junctions based on the noncollinear antiferromagnet PtMn3, sputter‐deposited on silicon. The devices simultaneously exhibit electrical switching using electric currents, and electrical readout by a large room‐temperature TMR effect. First‐principles calculations explain the TMR in terms of the momentum‐resolved spin‐dependent tunneling conduction in tunnel junctions with noncollinear AFM electrodes. 
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  7. ; ; ; ; (, Physical Review B)
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  8. ; (, Physical Review Letters)
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  9. ; ; ; ; ; ; (, Communications Materials)
    Abstract Magnetic random-access memory (MRAM) based on voltage-controlled magnetic anisotropy in magnetic tunnel junctions (MTJs) is a promising candidate for high-performance computing applications, due to its lower power consumption, higher bit density, and the ability to reduce the access transistor size when compared to conventional current-controlled spin-transfer torque MRAM. The key to realizing these advantages is to have a low MTJ switching voltage. Here, we report a perpendicular MTJ structure with a high voltage-controlled magnetic anisotropy coefficient ~130 fJ/Vm and high tunnel magnetoresistance exceeding 150%. Owing to the high voltage-controlled magnetic anisotropy coefficient, we demonstrate sub-nanosecond precessional switching of nanoscale MTJs with diameters of 50 and 70 nm, using a voltage lower than 1 V. We also show scaling of this switching mechanism down to 30 nm MTJs, with voltages close to 2 V. The results pave the path for the future development and application of voltage-controlled MRAMs and spintronic devices in emerging computing systems. 
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  10. ; ; ; ; ; ; ; ; ; ; et al (, Science Advances)
    The electric field manipulates the spin chirality and skyrmion motion direction in a magnetic heterostructure. 
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