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63,821 to 63,830 of 70,482 Results

Figure 5 c Efield_150_Sm_with MOS2.bmp May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices Bitmap Image - 5.3 MB - MD5: 848247b777030393e3f277a25f733834 Data Numerically calculated E-ﬁeld distributions in the TASR metamaterial structure at the Fano resonance frequency for TASR with MoS2, without optical pump.
Figure 5 d E field 250_62.7 microJcm-2.bmp May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices Bitmap Image - 5.3 MB - MD5: 3ea3d5919ad08f55f162a74829c14080 Data Numerically calculated E-ﬁeld distributions in the TASR metamaterial structure at the Fano resonance frequency for TASR with optically pumped MoS2 with low pump ﬂuence (63.5 µJ cm−2).
Figure 5 e E_field_400Sm_ 254 microJcm-2.bmp May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices Bitmap Image - 5.3 MB - MD5: 5a4162852acdf38eeed3342df0be9065 Data Numerically calculated E-ﬁeld distributions in the TASR metamaterial structure at the Fano resonance frequency for TASR with optically pumped MoS2 with high pump ﬂuence (254 µJ cm−2).
Figure 6a b c.opj May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices Unknown - 234.2 KB - MD5: 5013eb22bcc91f414d5132508b092d75 Data Experimentally measured photo-carrier relaxation dynamics and corresponding biexponential fitting of the drop-casted MoS2 ﬁlm on a quartz substrate performed using the OPTP measurements at excitation pump ﬂuence a) 63.5 µJ cm−2 b) 127 µJ cm−2 c) 254 µJ cm−2
Raw data_Figure 6a_Fitting 50 mW -62.7 microJcm-2.opj May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices Unknown - 192.6 KB - MD5: a64d5def83ea50e493898709df707aff Data Carrier carrier dynamics and corresponding bi-exponential fitting at 63.5 microJ/cm-2
Raw data_Figure 6b_ Fitting 100 mW-127 microJcm-2.opj May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices Unknown - 554.4 KB - MD5: 23702caa4e55725efb25cfebc66b9e8d Data Carrier carrier dynamics and corresponding bi-exponential fitting at 127 microJ/cm-2
Raw data_Figure 6c Fitting 200 mW_254 microJcm-2.opj May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices Unknown - 727.8 KB - MD5: 375f7254acb64dd1a27e19acfe55a4c4 Data Carrier carrier dynamics and corresponding bi-exponential fitting at 254 microJ/cm-2
Read Me.txt May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices Plain Text - 2.2 KB - MD5: d865503f4ad39cd5ca8cf67e7d564a4e Documentation Description of uploaded figures
Yogesh Kumar Srivastava (Nanyang Technological University) May 11, 2020School of Physical and Mathematical Sciences (SPMS) Appointment: Research Fellow (Former) Research topics: • Superconductors • Terahertz spectroscopy • Fano resonance • Low dimensional materials
1) readme.txt May 10, 2020 - Related data for: Heterogeneous Transfer Learning for Thermal Comfort Modeling Plain Text - 951 B - MD5: 4d6325dbb435dcb15ef59dd446c394d5 Documentation This

Figure 5 c Efield_150_Sm_with MOS2.bmp

May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices

Bitmap Image - 5.3 MB -

Data

Numerically calculated E-ﬁeld distributions in the TASR metamaterial structure at the Fano resonance frequency for TASR with MoS2, without optical pump.

Figure 5 d E field 250_62.7 microJcm-2.bmp

May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices

Bitmap Image - 5.3 MB -

Data

Numerically calculated E-ﬁeld distributions in the TASR metamaterial structure at the Fano resonance frequency for TASR with optically pumped MoS2 with low pump ﬂuence (63.5 µJ cm−2).

Figure 5 e E_field_400Sm_ 254 microJcm-2.bmp

May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices

Bitmap Image - 5.3 MB -

Data

Numerically calculated E-ﬁeld distributions in the TASR metamaterial structure at the Fano resonance frequency for TASR with optically pumped MoS2 with high pump ﬂuence (254 µJ cm−2).

Figure 6a b c.opj

May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices

Unknown - 234.2 KB -

Data

Experimentally measured photo-carrier relaxation dynamics and corresponding biexponential fitting of the drop-casted MoS2 ﬁlm on a quartz substrate performed using the OPTP measurements at excitation pump ﬂuence a) 63.5 µJ cm−2 b) 127 µJ cm−2 c) 254 µJ cm−2

Raw data_Figure 6a_Fitting 50 mW -62.7 microJcm-2.opj

May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices

Unknown - 192.6 KB -

Data

Carrier carrier dynamics and corresponding bi-exponential fitting at 63.5 microJ/cm-2

Raw data_Figure 6b_ Fitting 100 mW-127 microJcm-2.opj

May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices

Unknown - 554.4 KB -

Data

Carrier carrier dynamics and corresponding bi-exponential fitting at 127 microJ/cm-2

Raw data_Figure 6c Fitting 200 mW_254 microJcm-2.opj

May 11, 2020 - Replication Data for: MoS2 for Ultrafast All‐Optical Switching and Modulation of THz Fano Metaphotonic Devices