36. Ultrasound triggered organic mechanoluminescence materials (Invited Review)
W. Wang, A. Tasset, I. Pyatnitskiy, H.G. Mohamed, R. Taniguchi, R. Zhou, M. Rana, P. Lin, S.L.C. Capocyan, A. Bellamkonda, W.C. Sanders, H. Wang, Advanced Drug Delivery Reviews, p.114343 (2022)
35. Design of hydrogel-based wearable EEG electrodes for medical applications (Invited Review)
J.-C. Hsieh, Y. Li, H. Wang, M. Perz, Q. Tang, K.W.K. Tang, I. Pyatnitskiy, R. Reyes, H. Ding, H. Wang, Journal of Materials Chemistry B (2022)
34. Overcoming barrier in non-viral gene delivery for neurological applications (Invited Review)
A. Tasset, A. Bellamkonda, W. Wang, I. Pyatnitskiy, D. Ward, N. Peppas, H. Wang, Nanoscale, 14(10), 3698-3719 (2022).
33. Reversibly photoswitching upconversion nanoparticles for supersensitive photoacoustic molecular imaging
C. Liu, X. Zheng, T. Dai, H. Wang, X. Chen, B. Chen, T. Sun, F. Wang, S. Chu, and J. Rao, Angew. Chem. Int. Ed. e202116802 (2022)
32. 35 challenges in materials science being tackled by PIs under 35(ish) in 2021
B. Aguado, L. J. Bray, S. Caneva, G. D. Martino, C. Fang, Y. Fang, G. Grosso, B. Liao, F. Liu, F. Molina-Lopez, A. Pickel, R. Raman, Q. Smith, C. Tian, H. Wang, H. Wang, S. Wang, Z. Wang, Y. Yang, M. Zhao, Y. Zheng, S. Cranford, Matter, 4, 3804-3810 (2021)
31. Controllable fusion of human brain organoids using acoustofluidics
Z. Ao, H. Cai, Z. Wu, J. Ott, H. Wang, K. Mackie, G. Fuo, Lab on a chip, 21 (4), 688-699 (2021)
30. How is flexible electronics advancing neuroscience research?
Y.Chen, N.J. Rommelfanger, A.I. Mahdi, X.Wu, S.Keene, A.Obaid. A.Salleo, H.Wang*, G.Hong*, Biomaterials, 268, 120559 (2021)
29. Genetically targeted chemical assembly of functional materials in living cells, tissues, and animals
J. Liu, Y.S. Kim, C.E. Richardson, A. Tom, C. Ramakrishnan, F. Birey, T. Katsumata, S. Chen, C. Wang, X. Wang, L.-M. Joubert, Y. Jiang, H. Wang, L.E. Fenno, J.B.-H. Tok, S.P. Pasca, K. Shen, Z. Bao, and K. Deisseroth, Science, 367, 1372-1376, (2020)
28. Sono-optogenetics: a circulation delivered rechargeable light source for minimally invasive optogenetics
X. Wu, X. Zhu, P. Chong, J. Liu, L. N. Andre, K. S. Ong, K. Brinson Jr., A. I. Mahdi, J. Li, L. Fenno, H. Wang* and G. Hong*, PNAS, 116 (52), 26332-26342, (2019)
27. Soft and elastic hydrogel-based microelectronics for localized low-voltage neuromodulation
Y. Liu, J. Liu, S. Chen, T. Lei, Y. Kim, S. Niu, H. Wang, X. Wang, A. M. Foudeh, J. B.-H. Tok, Z. Bao, Nature Biomedical Engineering, 3, 58-68, (2019)
26. Next-generation probes, particles, and proteins for neural interfacing.
J. Rivnay, H. Wang, L. Fenno, K. Deisseroth, G. G. Malliaras,Science Advances, 3, e1601649, (2017)
25. Mechanically Durable and Highly Stretchable Transistors Employing Carbon Nanotube Semiconductor and Electrodes.
A. Chortos, G. I. Koleilat, R. Pfattner, D. Kong, P. Lin, R. Nur, T. Lei, H. Wang, N. Liu, Y.-C. Lai, M.-G. Kim, J. W. Chung, S. Lee, Z. Bao, Advanced Materials, 28, 4441-4448, (2016)
24. Conjugated polymer sorting of semiconducting carbon nanotubes and their electronic applications.
H. Wang, Z. Bao, Nano Today, 10, 737-758, (2016)
23. A skin-inspired organic digital mechanoreceptor.
B. C.-K. Tee and A. Chortos and A. Berndt, A. K. Nguyen, A. Tom, A. McGuire, Z. C. Lin, K. Tien, W.-G. Bae, H. Wang, P. Mei, H.-H. Chou, B. Cui, K. Deisseroth, T. N. Ng, Z. Bao, Science, 350, 313-316, (2015)
22. Shape-Controlled, Self-Wrapped Carbon Nanotube Three-Dimensional Electronics,
H. Wang, Y. Wang, B. C.-K. Tee, K.-P. Kim, J. Lopez, W. Cai, Z. Bao, Advanced Science, 2, 1500103, (2015) (highlighted by Chemical & Engineering News)
21. H-Bonded Supramolecular Polymer for the Selective Dispersion and Subsequent Release of Large-Diameter Semiconducting Single-Walled Carbon Nanotubes.
I. Pochorovski, H. Wang, J. Feldblyum, X. Zhang, A. Antaris, Z. Bao,Journal of the American Chemical Society,137, 4328-4331 (2015)
20. Scalable Assembly of Densely Aligned Single-Walled Carbon Nanotubes using Solution Shearing and their Application to Field-Effect Transistors.
S. Park, G. Pitner, G. Giri, J.-H. Koo, J. Park, K. Kim, H. Wang, R. Sinclair, H.-S. P. Wong, Z. Bao, Advanced Materials, 27, 2656-2662 (2015)
19. Diketopyrrolopyrrole (DPP)-Based Donor-Acceptor Polymers for Selective Dispersion of Large-Diameter Semiconducting Carbon Nanotubes.
T. Lei, Y.-C. Lai, G. Hong, H. Wang, P. Hayoz, R. T. Weitz, C. Chen, H. Dai, Z. Bao, Small, 11, 2946-2954 (2015)
18. N-type conjugated polymer-enabled selective dispersion of semiconducting carbon nanotubes for flexible CMOS-like circuits.
H. Wang, Y. Li, G. Jiménez-Osés, P. Liu, Y. Fang, J. Zhang, Y.-C. Lai, S. Park, L. Chen, K. N. Houk, Z. Bao, Advanced Functional Materials, 25, 1837-1844 (2015)
17. Significant Enhancement of Infrared Photodetector Sensitivity using Semiconducting Single-walled Carbon Nanotube/C60Phototransistor.
S. Park, S. J. Kim, J. H. Nam, G. Pitner, T. H. Lee, A. L. Ayzner, H. Wang, S. W. Fong, M. Vosgueritchian, Y. J. Park, M. L. Brongersma, Z. Bao, Advanced Materials, 27, 759-765 (2015)
16. Solvent effects on polymer sorting of carbon nanotubes with applications in printed electronics.
H. Wang, B. Hsieh, G. Jiménez-Osés, P. Liu, C.J. Tassone, Y. Diao, T. Lei, K.N. Houk, Z. Bao, Small, 11, 126-133 (2015) (Highlighted By Nanotechweb)
15. Highly Stable Carbon Nanotube Top-Gate Transistors with Tunable Threshold Voltage.
H.Wang, B. Cobb, A. Breemen, G. Gelinck, Z.Bao, Advanced Materials, 26, 4588-4593 (2014)
14. Tuning the Threshold Voltage of Carbon Nanotube Transistors by n-type Molecular Doping for Robust and Flexible Complementary Circuits.
H.Wang, P. Wei, Y. Li, J. Han, H. R. Lee, B. D. Naab, N. Liu, C. Wang, E. Adijanto, B. C-K. Tee, S. Morishita, Q. Li, Y. Gao, Y. Cui, Z. Bao, PNAS, 111(13), 4776-4781 (2014) (Highlighted by Stanford News )
13. High-Yield Sorting of Small-Diameter Carbon Nanotubes for Solar Cells and Transistors.
H. Wang, G. I. Koleilat, P. Liu, G. Jiménez-Osés, Y. Lai, M. Vosgueritchian, Y. Fang, S. Park, K. N. Houk, and Z Bao, ACS Nano, 8, 2609-2617 (2014) (Highlighted by Nanotechweb and Stanford GCEP news)
12. Direct Growth of Aligned Graphitic Nanoribbons from a DNA Template by Chemical Vapour Deposition.
A.N. Sokolov, F. L. Yap, N. Liu, K. Kim, L. Ci, O. B. Johnson, H. Wang, M. Vosgueritchian, A. L. Koh, J Chen, J. Park, Z. Bao, Nature Communications, 4, 2402 (2013)
11. Flexible polymer transistors with high pressure sensitivity for application in electronic skin and health monitoring.
G. Schwartz, B. C-K. Tee, J. Mei, A. L. Appleton, D H. Kim, H. Wang, and Z. Bao, Nature Communications, 4, 1859 (2013)
10. Scalable and Selective Dispersion of Semiconducting Arc-Discharged Carbon Nanotubes by Dithiafulvalene/Thiophene Copolymers for Thin Film Transistors.
H. Wang, J. Mei, P. Liu, K. Schmidt, G.J.Oses, S. Osuna, L Fang, C.J. Tassone, A.P. Zoombelt, A.N.Sokolov, K.N.Houk, M.F.Toney, Z. Bao. ACS Nano, 7, 2659-2668 (2013) (Highlighted by Materials 360)
9. Hierarchical nanostructured conducting polymer hydrogel with high electrochemical activity.
L. Pan, G. Yu, D. Zhai, H.R. Lee, W. Zhao, N. Liu, H. Wang, B.C.K. Tee, Y. Shi, Y. Cui, Z. Bao. Proceedings of National Academy of Science, 109 (24), 9287-9292 (2012)
8. Highly Effective Separation of Semiconducting Carbon Nanotubes verified via Short-Channel Devices Fabricated Using Dip-Pen Nanolithography.
S. Park, H.W. Lee, H. Wang, S. Selvarasah, M.R. Dokmeci, Y.J. Park, S.N. Cha, J.M. Kim, Z. Bao, ACS Nano. 6, 2487-2496 (2012)
7. Selective dispersion of high purity semiconducting single-walled carbon nanotubes with regioregular poly(3-alkylthiophene)s.
H.W. Lee, Y. Yoon, S. Park, J.H. Oh, S.H. Hong, L.S Liyanage, H. Wang, S. Morishita, N. Patil, Y.J. Park, J.J. Park, A. Spakowitz, G. Galli, F. Gygi, P. Wong, J. B.-H. Tok, J.M. Kim, and Z. Bao. Nature Communications, 2, 541(2011) (Highlighted by Stanford News)
6. Enhancing the supercapacitor performance of graphene/MnO2 nanostructured electrodes by conductive wrapping.
G. Yu, L. Hu, N. Liu, H. Wang, M. Vosgueritchian, Y. Yang, Y. Cui, Z. Bao, Nano Letters 11, 4438 (2011) (Highlighted by MIT Technology Review, Nanotechweb, PhysicsWorld, Green Car Congress)
5. Solution-processed graphene/MnO2 nanostructured textiles for high-performance electrochemical capacitors.
G. Yu, L. Hu, M. Vosgueritchian, H. Wang, X. Xie, J. R. McDonough, X. Cui, Y. Cui, Z. Bao, Nano Letters 11, 2905 (2011) (Highlighted by Nature News)
4. Carbon Nanotube Nanoelectronic Devices Compatible with Transmission Electron Microscopy.
H. Wang, J. Luo, F. Schaeffel, M. Ruemmeli, G. A. D. Briggs, J. H. Warner, Nanotechnology, 22, 245305 (2011)
3. Electron paramagnetic resonance investigations of purified catalyst-free single-walled carbon nanotubes.
M. Zaka, Y. Ito, H. Wang, W. Yan, A. Robertson, Y. A. Wu, M. H. Rummeli, D. Staunton, T. Hashimoto, J. J. L. Morton, A. Ardavan, G. A. D. Briggs, J. H. Warner, ACS Nano, 4, 7708-7716 (2010)
2. High performance field effect transistors from solution processed carbon nanotubes.
H. Wang, J. Luo, A. Robertson, Y. Ito, W. Yan, V. Lang, M. Zaka, F. Schaffel, M. H. Rummeli, G. A. D. Briggs, J. H. Warner. ACS Nano, 4, 6659-6664 (2010)
1. Ultrahigh secondary electron emission of carbon nanotubes.
J. Luo, J. H. Warner, C. Feng, Y. Yao, Z. Jin, H. Wang, C. Pan, S. Wang, L. Yang, Y. Li, J. Zhang, A. A. R. Watt, L. Peng, J. Zhu, G. A. D. Briggs, Applied Physics Letters, 96, 213113 (2010)