Contribute to the Database
This page lists all the contributors to the UVM Materials Database.
To have your data added to this site, please send an email to david.allemeier@uvm.edu or mwhite25@uvm.edu!
Contributors
B. Ruhstaller, T. Beierlein, H. Riel, S. Karg, J.C. Scott, and W. Riess. Simulating Electronic and Optical Processes in Multilayer Organic Light-Emitting Devices. IEEE JOURNAL OF SELECTED TOPICS IN QUANTUM ELECTRONICS, 2003 9 (3).
Bingjun Wang, Hao Ye, Moritz Riede, and Donal D. C. Bradley
ACS Applied Materials & Interfaces 2021 13 (2), 2919-2931
DOI: 10.1021/acsami.0c18490
- Coated glass substrate - ITO - Work Function
- Unspecified - TFB - HOMO Level
- Unspecified - TFB - LUMO Level
- Bulk - Aluminum - Work Function
C. Lee, D. Moon, and J. Han. "Top Emission Organic Light Emitting Diode with Transparent Cathode,
Ba-Ag Double Layer." Journal of Information Display 7.3 (2006). pp. 23-36.
DOI: https://doi.org/10.1080/15980316.2006.9652009
Chu, Ta-Ya, and Ok-Keun Song. "Hole Mobility of N , N ′ -bis(naphthalen-1-yl)- N , N ′ -bis(phenyl) Benzidine Investigated by Using Space-charge-limited Currents." Applied Physics Letters 90.20 (2007): 203512-03512-3. Web.
DOI: 10.1063/1.2741055
D. Shelhammer, X.A. Cao, N. Liu, H.J. Wang, and Y.M. Zhou. Doping effects and stability of calcium in organic electron-transport materials. Organic Electronics 84 (2020).
DOI: 10.1016/j.orgel.2020.105799
Exciton 2150 Bixby Road Lockbourne, OH 43137
F. Ventsch, M.C. Gather, and K. Meerholz. Towards organic light-emitting diode microdisplays
with sub-pixel patterning. Organic Electronics 11 (2010). pp 57–61.
DOI: 10.1016/j.orgel.2009.09.026
Fong, H H, and S K So. "Hole Transporting Properties of Tris(8-hydroxyquinoline) Aluminum ( Al Q 3 )." Journal of Applied Physics 100.9 (2006): 094502-94502-5. Web.
DOI: 10.1063/1.2372388
G. Li, C. H. Kim, Z. Zhou, J. Shinar, K. Okumoto, and Y. Shirota. Combinatorial study of exciplex formation at the interface between two wide band gap organic semiconductors. Appl. Phys. Lett. 88, 253505 (2006).
DOI: doi.org/10.1063/1.2202391
Handbook of Infrared Optical Materials Paul Klocek CRC Press 1991
Highly Effcient Organic Light-Emitting Diode Using A Low Refractive Index Electron Transport Layer, A. Salehi et al., Adv. Optical Mater., 170019 (2017); DOI: 10.1002/adom.201700197.
DOI: 10.1002/adom.201700197
Jia-Xiu Man, Shou-Jie He, Deng-Ke Wanga, Han-Nan Yanga, Zheng-Hong Lu "Tailoring Mg:Ag functionalities for organic light-emitting diodes" Organic Electronics, Volume 63, Pg. 41-46, 2018
DOI: 10.1016/j.orgel.2018.08.05
Kojima, H. Melting Points of Inorganic Fluorides. Can. J. Chem. 1968, 46, 2968–297
Kurt J. Lesker Company 1925 Route 51 Jefferson Hills, PA 15025 USA
L. S. Hung and C. W. Tang. Interface engineering in preparation of organic surface-emitting diodes. Appl. Phys. Lett. 74, 3209 (1999).
DOI: https://doi.org/10.1063/1.124107
Luminescence Technology Corp 31F-5 No. 99 Sec. 1 Xintai 5th Rd. Xizhi, New Taipei City 22175 Taiwan
M. Cai, T. Xiao, R. Liu, Y.Chen, R. Shinar, and J. Shinar. Indium-tin-oxide-free tris(8-hydroxyquinoline) Al organic light-emitting diodes with 80% enhanced power efficiency. Appl. Phys. Lett. 99, 153303 (2011).
DOI: https://doi.org/10.1063/1.3634210
N. Takada, T. Tsutsui, and S. Saito. Control of emission characteristics in organic thin-film electroluminescent diodes using an optical-microcavity structure. Appl. Phys. Lett. 63, 2032 (1993).
DOI: https://doi.org/10.1063/1.110582
Ossila Ltd, Solpro Business Park Windsor Street, Sheffield S4 7WB, UK
- Thin Film - NBPhen - Melting Point
- Unspecified - TPD - HOMO Level
- Unspecified - TPD - LUMO Level
- Unspecified - T2T - HOMO Level
- Unspecified - T2T - LUMO Level
- Unspecified - 3TPYM - HOMO Level
- Unspecified - 3TPYM - LUMO Level
- Unspecified - 3TPYM - Melting Point
- Bulk - LiF - Melting Point
- Unspecified - NPB - HOMO Level
- Unspecified - NPB - LUMO Level
- Bulk - Zinc - Melting Point
- Unspecified - PCBM - HOMO Level
- Unspecified - PCBM - LUMO Level
- Unspecified - Quartz - Melting Point
- Bulk - Ir(ppy)<sub>3</sub> - Melting Point
- Bulk - (ppy)<sub>2</sub>Ir(acac) - HOMO Level
- Bulk - (ppy)<sub>2</sub>Ir(acac) - LUMO Level
- Bulk - (ppy)<sub>2</sub>Ir(acac) - Melting Point
- Unspecified - DPVBi - HOMO Level
- Unspecified - DPVBi - LUMO Level
- Unspecified - DPVBi - Melting Point
- Unspecified - CuPc - Melting Point
- Unspecified - TCNQ - LUMO Level
- Unspecified - F4-TCNQ - LUMO Level
- Unspecified - F4-TCNQ - HOMO Level
- Unspecified - F4-TCNQ - Melting Point
- Unspecified - BAlq - HOMO Level
- Unspecified - BAlq - LUMO Level
- Unspecified - Ir(piq)<sub>3</sub> - HOMO Level
- Unspecified - Ir(piq)<sub>3</sub> - LUMO Level
- Unspecified - Ir(piq)<sub>3</sub> - Melting Point
- Unspecified - Ir(MDQ)<sub>2</sub>(acac) - HOMO Level
- Unspecified - Ir(MDQ)<sub>2</sub>(acac) - LUMO Level
- Unspecified - TAZ - HOMO Level
- Unspecified - TAZ - LUMO Level
- Unspecified - m-MTDATA - HOMO Level
- Unspecified - m-MTDATA - LUMO Level
- Unspecified - m-MTDATA - Melting Point
- Unspecified - Bebq2 - HOMO Level
- Unspecified - Bebq2 - LUMO Level
- Unspecified - DNTPD - HOMO Level
- Unspecified - DNTPD - LUMO Level
- Unspecified - HAT-CN - HOMO Level
- Unspecified - HAT-CN - LUMO Level
- Unspecified - Liq - HOMO Level
- Unspecified - Liq - LUMO Level
- Unspecified - Liq - Melting Point
- Unspecified - OXD-7 - HOMO Level
- Unspecified - OXD-7 - LUMO Level
- Unspecified - OXD-7 - Melting Point
- Unspecified - P3HT - HOMO Level
- Unspecified - P3HT - LUMO Level
- Unspecified - spiro-MeOTAD - HOMO Level
- Unspecified - spiro-MeOTAD - LUMO Level
- Unspecified - F8BT - HOMO Level
- Unspecified - F8BT - LUMO Level
- Unspecified - fac-Ir(btpy)3 - HOMO Level
- Unspecified - fac-Ir(btpy)3 - LUMO Level
- Unspecified - Ir(mppy)3 - HOMO Level
- Unspecified - Ir(mppy)3 - LUMO Level
- Unspecified - DMQA - HOMO Level
- Unspecified - DMQA - LUMO Level
- Unspecified - DMQA - Melting Point
Park, Hoon, Dong-Sub Shin, Hee-Sung Yu, and Hee-Baik Chae. "Electron Mobility in Tris(8-hydroxyquinoline)aluminum (Alq3) Films by Transient Electroluminescence from Single Layer Organic Light Emitting Diodes." Applied Physics Letters 90.20 (2007): 202103. Web.
DOI: 10.1063/1.2734386
Philip Schulz, Jan O. Tiepelt, Jeffrey A. Christians, Igal Levine, Eran Edri, Erin M. Sanehira, Gary Hodes, David Cahen, and Antoine Kahn
ACS Applied Materials & Interfaces 2016 8 (46), 31491-31499
DOI: 10.1021/acsami.6b10898
DOI: 10.1021/acsami.6b10898
Sigma-Aldrich PO Box 14508 St. Louis, MO 63178 USA
- Thin Film - Alq<sub>3</sub> - HOMO Level
- Thin Film - Alq<sub>3</sub> - LUMO Level
- Bulk - MoO<sub>3</sub> - Melting Point
- Wafer - Silicon - Melting Point
- Unspecified - Silver - Melting Point
- Bulk - Chromium - Melting Point
- Thin film - Calcium - Melting Point
- Thin film - Barium - Melting Point
- Unspecified - PtOEP - HOMO Level
- Unspecified - PtOEP - LUMO Level
- Bulk - Ir(ppy)<sub>3</sub> - HOMO Level
- Bulk - Ir(ppy)<sub>3</sub> - LUMO Level
- Unspecified - CBP - Melting Point
- Unspecified - CBP - HOMO Level
- Unspecified - CBP - LUMO Level
- Unspecified - BCP - HOMO Level
- Unspecified - BCP - LUMO Level
- Unspecified - BCP - Melting Point
- Bulk - LiF - Density
- Dried Coating - PEDOT:PSS - Density
- Unspecified - α-NPD - Melting Point
- Unspecified - Magnesium - Conductivity
- Unspecified - Magnesium - Melting Point
- Unspecified - Magnesium - Density
- Unspecified - spiro-TAD - Melting Point
- Unspecified - TiO<sub>2</sub> - Melting Point
- Unspecified - TiO<sub>2</sub> - Density
- Dried Coating - PEDOT:PSS - Conductivity
- Unspecified - CuPc - HOMO Level
- Unspecified - CuPc - LUMO Level
- Unspecified - CsF - Density
- Unspecified - CsF - Melting Point
- Unspecified - V2O5 - Melting Point
- Unspecified - V2O5 - Density
- Unspecified - FeCl<sub>3</sub> - Melting Point
- Unspecified - TCNQ - Melting Point
- Substrate - Gallium arsenide - Density
- Thin film - TiN - Melting Point
- Thin film - TiN - Density
- Unspecified - ZnPc - HOMO Level
- Unspecified - ZnPc - LUMO Level
- Unspecified - MeO-TPD - Melting Point
- Bulk - Aluminum - Conductivity
- Bulk - Aluminum - Melting Point
- Bulk - Aluminum - Density
- Thin film - Barium - Conductivity
- Thin film - Barium - Density
- Unspecified - BPhen - Melting Point
- Unspecified - BPhen - HOMO Level
- Unspecified - BPhen - LUMO Level
- Unspecified - Cesium - Density
- Unspecified - Cesium - Melting Point
- Unspecified - TPBi - Melting Point
- Unspecified - TPBi - HOMO Level
- Unspecified - TPBi - LUMO Level
- Unspecified - BAlq - Melting Point
- Unspecified - TCTA - Melting Point
- Unspecified - TCTA - HOMO Level
- Unspecified - TCTA - LUMO Level
- Thin film - Calcium - Conductivity
- Thin film - Calcium - Density
- Bulk - Chromium - Conductivity
- Bulk - Chromium - Density
- Powder - ITO - Melting Point
- Powder - ITO - Density
- Unspecified - TAZ - Melting Point
- Unspecified - FIrpic - Melting Point
- Unspecified - FIrpic - HOMO Level
- Unspecified - FIrpic - LUMO Level
- Unspecified - Lithium - Conductivity
- Unspecified - Lithium - Melting Point
- Unspecified - Lithium - Density
- Unspecified - Gold - Conductivity
- Unspecified - Gold - Melting Point
- Unspecified - Gold - Density
- Unspecified - Pe - Melting Point
- Unspecified - DTDCPB - Melting Point
- Unspecified - Tin oxide - Density
- Unspecified - PTCDA - HOMO Level
- Unspecified - PTCDA - LUMO Level
- Unspecified - Nickel oxide - Density
- Unspecified - Silver - Density
- Unspecified - C8-BTBT - Melting Point
- Unspecified - Magnesium oxide - Melting Point
- Unspecified - DNTPD - Melting Point
- Unspecified - P3HT - Melting Point
- Unspecified - Tungsten(VI) oxide - Density
- Unspecified - Silicon nitride - Density
- Unspecified - DCM - Melting Point
- Unspecified - Zinc selenide - Density
- Unspecified - Hafnia - Density
- Unspecified - Tellurium dioxide - Melting Point
- Unspecified - Tellurium dioxide - Density
- Unspecified - spiro-MeOTAD - Melting Point
- Unspecified - TIPS pentacene - Melting Point
- Unspecified - TIPS pentacene - Density
- Unspecified - Magnesium - Density
- Unspecified - DCJTB - Melting Point
- Unspecified - DCJTB - HOMO Level
- Unspecified - DCJTB - LUMO Level
- Unspecified - mCP - Melting Point
- Unspecified - mCP - HOMO Level
- Unspecified - mCP - LUMO Level
- Unspecified - DBP - HOMO Level
- Unspecified - DBP - LUMO Level
Tsai, K.‐W., Hung, M.‐K., Mao, Y.‐H., Chen, S.‐A.. Solution‐Processed Thermally Activated Delayed Fluorescent OLED with High EQE as 31% Using High Triplet Energy Crosslinkable Hole Transport Materials. Adv. Funct. Mater. 2019, 29, 1901025.
DOI: 0.1002/adfm.201901025
Turak, A. On the Role of LiF in Organic Optoelectronics. Electron. Mater. 2021, 2, 198-221. https://doi.org/10.3390/electronicmat2020016
DOI: 10.3390/electronicmat2020016
- Bulk - LiF - Crystal Structure
- Bulk - LiF - Band Gap
- Bulk - LiF - Sublimation Temperature
- Bulk - LiF - Percolation Threshold
Unpublished
W.M.H. Sachtler, G.J.H. Dorgelo, and A.A. Holscher. The work function of gold. Surface Science, 5(2):221–229, 1966.
DOI: 10.1016/0039-6028(66)90083-5
Wen, S. W., Lee, M. T., and Chen, C. H. “Recent Development of Blue Fluorescent OLED Materials and Devices” Journal of Display Technology 1, no. 1 (2005): 90–99. doi:10.1109/JDT.2005.852802
DOI: 10.1109/JDT.2005.852802
Z.T. Liu et al: The characterization of the optical functions of bcp and cbp thin films by spectroscopic ellipsometry. Synthetic Metals, vol. 150, pp. 159–163, 2005.