1. Z.S. Walbrun, C.Y. Wong (2023) In Situ Measurement of Evolving Excited-State Dynamics During Deposition and Processing of Organic Films by Single-Shot Transient Absorption. Annu. Rev. Phys. Chem. 74: In press.
2. Z.S. Walbrun, L.C. Leibfried, A.R. Hoban, B.C. Rasmussen, T.J. Wiegand, C.J. Collison, C.Y. Wong (2022) Effect of thermal annealing on aggregation of a squaraine thin film. MRS Adv. 7: 239-244.
3. J.C. Sadighian, C.Y. Wong (2021) Just scratching the surface: In situ and surface-specific characterization of perovskite nanocrystal growth. J. Phys. Chem. C 125: 20772-20782 ACS Editors’ Choice.
4. Y. Hassan*†, J. H. Park*, M.L. Crawford, A. Sadhanala, J.C. Sadighian, E. Mosconi, R. Shivanna, M. Jeong, C. Yang, J. Lee, H. Choi, S.H. Park, M.H. Song, F. De Angelis, C.Y. Wong†, R.H. Friend, B.R. Lee†, H.J. Snaith† (2021) Ligand engineered bandgap stability in mixed-halide perovskite nanocrystals for efficient and colour-stable light emitting diodes. Nature 591: 72-77.
5. K.S. Wilson, Z.S. Walbrun, C.Y. Wong (2021) Single-shot transient absorption spectroscopy techniques and design principles. Spectrochim Acta A 253: 119557.
6. M.L. Sosa, C.Y. Wong (2020) Revealing the evolving mixture of molecular aggregates during organic film formation using simulations of in situ absorbance. J. Chem. Phys. 153: 214902.
7. J.C. Sadighian, K.S. Wilson, M.L. Crawford, C.Y. Wong (2020) Single-Shot Transient Absorption of Nascent Perovskite Nanocrystals. Ultrafast Phenomena XXII: Tu3A.6.
8. J.C. Sadighian, K.S. Wilson, M.L. Crawford, C.Y. Wong (2020) Evolving Stark Effect During Growth of Perovskite Nanocrystals Measured Using Transient Absorption. Front. Chem. 8: 585853.
9. J.C. Sadighian, K.S. Wilson, M.L. Crawford, C.Y. Wong (2020) Understanding Perovskite Nanocrystal Growth Using In Situ Transient Absorption Spectroscopy. Proc. SPIE 11464: 114640K.
10. L. Huang, C.Y. Wong, E. Grumstrup (2020) Time-Resolved Microscopy: A New Frontier in Physical Chemistry. J. Phys. Chem. A 124: 5997-5998.
11. M.L. Crawford, J.C. Sadighian, Y. Hassan, H.J. Snaith, C.Y. Wong (2020) Spectral shifts upon halide segregation in perovskite nanocrystals observed via transient absorption spectroscopy. MRS Adv. 5(51): 2613-2621.
12. J.C. Sadighian, M.L. Crawford, T.W. Suder, C.Y. Wong (2020) Surface ligation stage revealed through polarity-dependent fluorescence during perovskite nanocrystal growth. J. Mater. Chem. C 8: 7041-7050.
13. K.S. Wilson, A.N. Mapile, C.Y. Wong (2020) Broadband single-shot transient absorption spectroscopy. Opt. Exp. 28: 11339-11355.
14. J.C. Sadighian, M.L. Crawford, C.Y. Wong (2019) In situ transient absorption spectroscopy of organometal halide perovskite nanoparticles. Proc. Mat. Sci. Tech. 960-963.
15. K.S. Wilson, M.L. Sosa, M.N. Scott, C.Y. Wong (2019) In Situ Measurement of the Excited State Dynamics of Evolving Materials Systems in OSA Advanced Photonics Congress (AP) 2019, OSA Technical Digest (Optical Society of America, 2019), paper NoT1B.4.
16. J.C. Sadighian, M.L. Crawford, C.Y. Wong (2019) Rapid sampling during synthesis of lead halide perovskite nanocrystals for spectroscopic measurement. MRS Adv. 4(36): 1957-1964.
17. K.S. Wilson, M.N. Scott, C.Y. Wong (2019) Excited state dynamics of organic semiconductors measured with shot-to-shot correction of scatter and photoluminescence. Synth. Met. 250: 115-120. (Early Career Leaders Special Issue)
18. M.L. Sosa, R.B. Pandit, K.S. Wilson, C.Y. Wong (2018) Composition of molecular aggregates during film formation revealed using simulated absorption spectra. Proc. SPIE, Physical Chemistry of Semiconductor Materials and Interfaces XVII 10724: 1072403.
19. K.S. Wilson, C.Y. Wong (2018) In Situ Measurement of Exciton Dynamics During Thin-Film Formation Using Single-Shot Transient Absorption. J. Phys. Chem. A 122: 6438-6444
20. K.S. Wilson, M.N. Scott, C.Y. Wong (2018) Single-shot transient absorption spectroscopy of an organic film. MRS. Adv. 3: 3453-3457
21. K.S. Wilson, C.Y. Wong (2018) Single-shot transient absorption spectroscopy with a 45 ps pump-probe time delay range. Opt. Lett. 43: 371-374.
22. K.S. Wilson, C.Y. Wong (2017) Calibrating a spatially encoded time delay for transient absorption spectroscopy. Proc. SPIE, Physical Chemistry of Semiconductor Materials and Interfaces XVI 10348: 1034805.

Prior to U. Oregon

1. C.Y. Wong, B.D. Folie, B.L. Cotts, N.S. Ginsberg (2015) Discerning Variable Extents of Interdomain Orientational and Structural Heterogeneity in Solution-Cast Polycrystalline Organic Semiconducting Thin Films. J. Phys. Chem. Lett. 6: 3155-3162.
2. C.Y. Wong, B.L. Cotts, H. Wu, N.S. Ginsberg (2015) Exciton dynamics reveal aggregates with intermolecular order at hidden interfaces in solution-cast organic semiconducting films. Nat. Commun. 6: 5946.
3. S. Sharifzadeh, C.Y. Wong, H. Wu, B.L. Cotts, L. Kronik, N.S. Ginsberg, J.B. Neaton (2015) Relating the physical structure and optoelectronic function of crystalline TIPS-pentacene. Adv. Funct. Mater. 25: 2038-2046.
4. C.Y. Wong, S.B. Penwell, B.L. Cotts, R. Noriega, H. Wu, N.S. Ginsberg (2013) Revealing exciton dynamics in a small-molecule organic semiconducting film with subdomain transient absorption microscopy. J. Phys. Chem. C 117: 22111-22122.
5. C.Y. Wong, R.M. Alvey, D.B. Turner, K.E. Wilk, D.A. Bryant, P.M.G. Curmi, R.J. Silbey, G.D. Scholes (2012) Electronic coherence lineshapes reveal hidden excitonic correlations in photosynthetic light harvesting. Nat. Chem. 4: 396-404.
6. M.H.J. Oh, M.R. Salvador, C.Y. Wong, G.D. Scholes (2011) Three-pulse photon-echo peak shift spectroscopy and its application for the study of salvation and nanoscale excitons. ChemPhysChem 12: 88-100.
7. C.Y. Wong, G.D. Scholes (2010) Biexcitonic fine structure of CdSe nanocrystals probed by polarization dependent two-dimensional photon echo spectroscopy. J. Phys. Chem. A 115: 3797-3806.
8. C.Y. Wong, G.D. Scholes (2010) Using two-dimensional photon echo spectroscopy to probe the fine structure of the ground state biexciton of CdSe nanocrystals. J. Luminesc. 131: 366-374.
9. E. Collini,* C.Y. Wong,* K.E. Wilk, P.M.G. Curmi, P. Brumer, G.D. Scholes (2010) Coherently wired light-harvesting in photosynthetic marine algae and ambient temperature. Nature 463: 644-647.
10. J. Kim, C.Y. Wong, G.D. Scholes (2009) Exciton fine structure and spin relaxation in semiconductor colloidal quantum dots. Acc. Chem. Res. 42: 1037-1046.
11. C.Y. Wong, C. Curutchet, S. Tretiak, G.D. Scholes (2008) Ideal dipole approximation fails to predict electronic coupling and energy transfer between semiconducting single-wall carbon nanotubes. J. Chem. Phys. 130: 081104.
12. C.Y. Wong,* J. Kim,* P.S. Nair, M.C. Nagy, G.D. Scholes (2008) Relaxation in the exciton fine structure of semiconductor nanocrystals. J. Phys. Chem. C 113: 795-811.
13. J. Kim, P.S. Nair, C.Y. Wong, G.D. Scholes (2007) Sizing up the exciton in complex shaped semiconductor nanocrystals. Nano Lett. 7: 3884-3890.
14. J. Kim, C.Y. Wong, P.S. Nair, K.P. Fritz, S. Kumar, G.D. Scholes (2006) Mechanism and origin of exciton spin relaxation in CdSe nanorods. J. Phys. Chem. B 110: 25371-25382.
15. G.D. Scholes, J. Kim, C.Y. Wong, V.M. Huxter, P.S. Nair, K.P. Fritz, S. Kumar (2006) Nanocrystal shape and the mechanism of exciton spin relaxation. Nano Lett. 6: 1765-1771.
16. G.D. Scholes, J. Kim, C.Y. Wong (2006) Exciton spin relaxation in quantum dots measured using ultrafast transient polarization grating spectroscopy. Phys. Rev. B 73: 195325.
17. C.Y. Wong, P.J.A. Ruttink, P.C. Burgers, J.K. Terlouw (2004) The isomerization of [H2O-C=O]•+ and [HC(=O)OH]•+ into [HO-C-OH]•+: proton-transport catalysis by CO. Chem. Phys. Lett. 390: 176-180.
18. C.Y. Wong, P.J.A. Ruttink, P.C. Burgers, J.K. Terlouw (2004) The ionic isomerization [HCOH]•+ – [CH2=O]•+: proton-transport catalysis by CO and CO2. Chem. Phys. Lett. 387: 204-208.
19. R. Srikanth, K. Bhanuprakash, R. Srinivas, C.Y. Wong, J.K. Terlouw (2004) Protonated silanoic acid HSi(OH)2+ and its neutral counterpart: a tandem mass spectrometric and CBS-QB3 computational study. J. Mass Spectrom. 39: 303-311.
20. L.N. Heydorn, C.Y. Wong, R. Srinivas, J.K. Terlouw (2003) The isobaric ions CH3O-P=O•+ and CH3O-P-NH2+ and their neutral counterparts: A tandem mass spectrometry and CBS-QB3 computational study. Int. J. Mass Spectrom. 225: 11-23.