NRF-CRP23-2019-0005

On-chip Terahertz Topological Photonics for 6G Communication (TERACOMM)

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611 to 620 of 620 Results

Figure 4~d.opj May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM) Unknown - 148.7 KB - MD5: fb662688c47c1a362c4e04690f23fd72 Figure 4(d): THz-H hysteresis in Quartz/Co40Fe40B20(5nm): THz-H hysteresis measured using the TSM system. An opposite phase of THz emission was observed in Qz/CoFeB compared to emission from Qz/CoFeB/Pt or Qz/W/CoFeB/Pt. The effect arises due to spin transport in the negative dir...
Figure S2~a.opj May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM) Unknown - 89.7 KB - MD5: 165d89385c80d9fd40c92ad0f1f1d860 Figure S2(a): Relation between THz amplitude and charge current when the applied magnetic field is parallel to the FM easy axis in CoFeB/Pt : Theoretically calculated terahertz pulse at different field-dependent magnetization states. THz pulse shifted in time axis to show clear r...
Figure S2~b.opj May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM) Unknown - 100.0 KB - MD5: 99062b69287d7da324c5b546418dba87 Figure S2(b): Relation between THz amplitude and charge current when the applied magnetic field is parallel to the FM easy axis in CoFeB/Pt : Measured THz pulse at different field-dependent magnetization states
Figure S2~c.opj May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM) Unknown - 87.4 KB - MD5: f4919ec25b1a39f0460f76880e249c2b Figure S2(c): Relation between THz amplitude and charge current when the applied magnetic field is parallel to the FM easy axis in CoFeB/Pt : Theoretically calculated transient charge current manifested in the HM layer, at different magnetization states
Figure S2~d.opj May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM) Unknown - 59.9 KB - MD5: 32984bfa0e05fc5ad7c547572e713014 Figure S2(d): Relation between THz amplitude and charge current when the applied magnetic field is parallel to the FM easy axis in CoFeB/Pt : Solid black and blue lines demonstrates linear relation between the THz pulse amplitude and charge current amplitude. Experimentally obser...
Figure S5.opj May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM) Unknown - 88.3 KB - MD5: 59b966db15f06b6e3fe9cbb81853b5a3 Figure S5: Relation between THz emission from Qz/W/CoFeB/Pt, Qz/CoFeB/Pt, and Qz/CoFeB, for 0.15mJ/cm2 at saturation magnetic field of 100 Oe.
W_CoFeB_Pt0001.ibw May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM) Unknown - 1.1 MB - MD5: b9469c9a0c31f677fd7bd2b897bdd941 Figure S3(b): AFM file for Qz/W/CoFeB/Pt
W_CoFeB_Pt_1.txt May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM) Plain Text - 1.1 KB - MD5: 3b0b52de1757294642707ba3a7e14e47 Figure S3(b): AFM roughness calculation for Qz/W/CoFeB/Pt
Replication Data for: Temporal loss boundary engineered photonic cavity Mar 23, 2022 - THz metamaterials Longqing, Cong; Han, Jiaguang; Zhang, Weili; Singh, Ranjan, 2022, "Replication Data for: Temporal loss boundary engineered photonic cavity", https://doi.org/10.21979/N9/EXZCGV, DR-NTU (Data), V1 Losses are ubiquitous and unavoidable in nature inhibiting the performance of most optical processes. Manipulating losses to adjust the dissipation of photons is analogous to braking a running car that is as important as populating photons via a gain medium. Here, we introduce th...
Temporal Loss Boundary Engineered Photonic Cavity.opj Mar 23, 2022 - Replication Data for: Temporal loss boundary engineered photonic cavity Unknown - 8.8 MB - MD5: 053a2b9877a3bddd18e2761f7170ccd0 Data corresponding to all the figures. Experimental and simulation data

Figure 4~d.opj

May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM)

Unknown - 148.7 KB -

Figure 4(d): THz-H hysteresis in Quartz/Co40Fe40B20(5nm): THz-H hysteresis measured using the TSM system. An opposite phase of THz emission was observed in Qz/CoFeB compared to emission from Qz/CoFeB/Pt or Qz/W/CoFeB/Pt. The effect arises due to spin transport in the negative dir...

Figure S2~a.opj

May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM)

Unknown - 89.7 KB -

Figure S2(a): Relation between THz amplitude and charge current when the applied magnetic field is parallel to the FM easy axis in CoFeB/Pt : Theoretically calculated terahertz pulse at different field-dependent magnetization states. THz pulse shifted in time axis to show clear r...

Figure S2~b.opj

May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM)

Unknown - 100.0 KB -

Figure S2(b): Relation between THz amplitude and charge current when the applied magnetic field is parallel to the FM easy axis in CoFeB/Pt : Measured THz pulse at different field-dependent magnetization states

Figure S2~c.opj

May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM)

Unknown - 87.4 KB -

Figure S2(c): Relation between THz amplitude and charge current when the applied magnetic field is parallel to the FM easy axis in CoFeB/Pt : Theoretically calculated transient charge current manifested in the HM layer, at different magnetization states

Figure S2~d.opj

May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM)

Unknown - 59.9 KB -

Figure S2(d): Relation between THz amplitude and charge current when the applied magnetic field is parallel to the FM easy axis in CoFeB/Pt : Solid black and blue lines demonstrates linear relation between the THz pulse amplitude and charge current amplitude. Experimentally obser...

Figure S5.opj

May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM)

Unknown - 88.3 KB -

Figure S5: Relation between THz emission from Qz/W/CoFeB/Pt, Qz/CoFeB/Pt, and Qz/CoFeB, for 0.15mJ/cm2 at saturation magnetic field of 100 Oe.

W_CoFeB_Pt0001.ibw

May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM)

Unknown - 1.1 MB -

Figure S3(b): AFM file for Qz/W/CoFeB/Pt

W_CoFeB_Pt_1.txt

May 13, 2022 - Replication Data for: Terahertz Spintronic Magnetometer (TSM)

Plain Text - 1.1 KB -

Figure S3(b): AFM roughness calculation for Qz/W/CoFeB/Pt

Replication Data for: Temporal loss boundary engineered photonic cavity

Mar 23, 2022 - THz metamaterials

Longqing, Cong; Han, Jiaguang; Zhang, Weili; Singh, Ranjan, 2022, "Replication Data for: Temporal loss boundary engineered photonic cavity", https://doi.org/10.21979/N9/EXZCGV, DR-NTU (Data), V1

Losses are ubiquitous and unavoidable in nature inhibiting the performance of most optical processes. Manipulating losses to adjust the dissipation of photons is analogous to braking a running car that is as important as populating photons via a gain medium. Here, we introduce th...

Temporal Loss Boundary Engineered Photonic Cavity.opj

Mar 23, 2022 - Replication Data for: Temporal loss boundary engineered photonic cavity

Unknown - 8.8 MB -

Data corresponding to all the figures. Experimental and simulation data

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