Negative differential resistance in polymer tunnel diodes using atomic layer deposited, TiO2 tunneling barriers at various deposition temperatures
Atomic layer deposition (ALD) presents a method to deposit uniform and conformal thin-film layers with a high degree of control and repeatability. Quantum functional devices that provide opportunities in low-power molecular and organic based memory and logic via thin metal-oxide tunneling layer were...
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oai:animorepository.dlsu.edu.ph:faculty_research-30122023-01-11T03:41:32Z Negative differential resistance in polymer tunnel diodes using atomic layer deposited, TiO2 tunneling barriers at various deposition temperatures Guttman, Jeremy J. Chambers, Conner B. Villagracia, Al Rey C. Santos, Gil Nonato C. Berger, Paul R. Atomic layer deposition (ALD) presents a method to deposit uniform and conformal thin-film layers with a high degree of control and repeatability. Quantum functional devices that provide opportunities in low-power molecular and organic based memory and logic via thin metal-oxide tunneling layer were previously reported by Yoon et al. [1]. Demonstrated here area polymer tunnel diodes (PTD) with high negative differential resistance (NDR) using an ALD deposited tunneling layer grown between 250 °C – 350 °C. A critical relationship between deposition temperature, oxygen vacancy concentration and room temperature NDR is presented. In this work, for a TiO2 deposition temperature of 250 °C, the peak NDR voltage position (Vpeak) and associated peak current density (Jpeak) are ∼4.3 V and −0.14 A/cm2, respectively, with a PVCR as high as 1.69 while operating at room temperature. The highest PVCR recorded was 4.89 ± 0.18 using an ALD deposition temperature of 350 °C. The key advantages of the ALD process used in fabrication of PTDs are increased repeatability and manufacturability. © 2017 Elsevier B.V. 2017-08-01T07:00:00Z text https://animorepository.dlsu.edu.ph/faculty_research/2013 Faculty Research Work Animo Repository Atomic layer deposition Tunnel diodes Titanium dioxide Tunneling (Physics) Conjugated polymers Physics |
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Atomic layer deposition Tunnel diodes Titanium dioxide Tunneling (Physics) Conjugated polymers Physics |
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Atomic layer deposition Tunnel diodes Titanium dioxide Tunneling (Physics) Conjugated polymers Physics Guttman, Jeremy J. Chambers, Conner B. Villagracia, Al Rey C. Santos, Gil Nonato C. Berger, Paul R. Negative differential resistance in polymer tunnel diodes using atomic layer deposited, TiO2 tunneling barriers at various deposition temperatures |
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Atomic layer deposition (ALD) presents a method to deposit uniform and conformal thin-film layers with a high degree of control and repeatability. Quantum functional devices that provide opportunities in low-power molecular and organic based memory and logic via thin metal-oxide tunneling layer were previously reported by Yoon et al. [1]. Demonstrated here area polymer tunnel diodes (PTD) with high negative differential resistance (NDR) using an ALD deposited tunneling layer grown between 250 °C – 350 °C. A critical relationship between deposition temperature, oxygen vacancy concentration and room temperature NDR is presented. In this work, for a TiO2 deposition temperature of 250 °C, the peak NDR voltage position (Vpeak) and associated peak current density (Jpeak) are ∼4.3 V and −0.14 A/cm2, respectively, with a PVCR as high as 1.69 while operating at room temperature. The highest PVCR recorded was 4.89 ± 0.18 using an ALD deposition temperature of 350 °C. The key advantages of the ALD process used in fabrication of PTDs are increased repeatability and manufacturability. © 2017 Elsevier B.V. |
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text |
| author |
Guttman, Jeremy J. Chambers, Conner B. Villagracia, Al Rey C. Santos, Gil Nonato C. Berger, Paul R. |
| author_facet |
Guttman, Jeremy J. Chambers, Conner B. Villagracia, Al Rey C. Santos, Gil Nonato C. Berger, Paul R. |
| author_sort |
Guttman, Jeremy J. |
| title |
Negative differential resistance in polymer tunnel diodes using atomic layer deposited, TiO2 tunneling barriers at various deposition temperatures |
| title_short |
Negative differential resistance in polymer tunnel diodes using atomic layer deposited, TiO2 tunneling barriers at various deposition temperatures |
| title_full |
Negative differential resistance in polymer tunnel diodes using atomic layer deposited, TiO2 tunneling barriers at various deposition temperatures |
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Negative differential resistance in polymer tunnel diodes using atomic layer deposited, TiO2 tunneling barriers at various deposition temperatures |
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Negative differential resistance in polymer tunnel diodes using atomic layer deposited, TiO2 tunneling barriers at various deposition temperatures |
| title_sort |
negative differential resistance in polymer tunnel diodes using atomic layer deposited, tio2 tunneling barriers at various deposition temperatures |
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Animo Repository |
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2017 |
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https://animorepository.dlsu.edu.ph/faculty_research/2013 |
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