Corresponding author* Co-first author#
Corresponding author* Co-first author#
Force sensing with a graphene nanomechanical resonator coupled to photonic crystal guided resonances
Heng Lu, Tingting Li, Hui Hu, FengNan Chen, Ti Sun, Ying Yan, Chinhua Wang, and Joel Moser*.
Submitted. Main Text
A few-layer graphene nanomechanical resonator driven by digitally modulated video signals
Ce Zhang, Heng Lu, Chen Yang, YuBin Zhang, FengNan Chen, Ying Yan, and Joel Moser*.
Submitted. Main Text Supplemental Material Nanomechanical Video#1 Nanomechanical Video#2 Nanomechanical Video#3
Hysteretic responses of nanomechanical resonators based on crumpled few-layer graphene
Heng Lu, Chen Yang, Ce Zhang, YuBin Zhang, FengNan Chen, Yue Ying, Zhuo-Zhi Zhang, Xiang-Xiang Song, Guang-Wei Deng, Ying Yan, and Joel Moser*.
Applied Physics Letters 126, 223502 (2025) [featured article, 2025]. Main Text Supplemental Material
Symmetry breaking of large-amplitude parametric oscillations in few-layer graphene nanomechanical resonators
Chen Yang, YuBin Zhang, Heng Lu, Ce Zhang, FengNan Chen, Ying Yan, Fei Xue, Alexander Eichler, and Joel Moser*.
Physical Review Applied 23, 054036 (2025). Main Text
High-quality-factor viscoelastic nanomechanical resonators from moiré superlattices
Qin-Yang Zeng#, Gui-Xin Su#, Ai-Sheng Song#, Zhi-Yue Xu, Yue Ying, Zhuo-Zhi Zhang, Xiang-Xiang Song, Guang-Wei Deng, Joel Moser*, Tian-Bao Ma, Ping-Heng Tan*, and Xin Zhang*.
Nature Communications 16, Article number: 3793 (2025). Main Text Supplemental Material
Tailoring the light-matter interaction for high-fidelity holonomic gate operations in multiple systems
ZhiHuang Kang, ShuTong Wu, KunJi Han, JiaMin Qiu, Joel Moser, Jie Lu, and Ying Yan*.
Journal of the Optical Society of America B 42 (1), 168–179 (2024). Main Text
Graphene nanomechanical vibrations measured with a phase-coherent software-defined radio.
Ce Zhang, YuBin Zhang, Chen Yang, Heng Lu, FengNan Chen, Ying Yan, and Joel Moser*.
Communications Engineering 3, Article number: 45 (2024). Main Text Supplemental Material
Sliding nanomechanical resonators.
Y. Ying#, Z.-Z. Zhang#, Joel Moser*, Z.-J. Su, X.-X. Song*, and G.-P. Guo*.
Nature Communications 13, Article number: 6392 (2022). Main Text Supplemental Material
Mesoscopic physics of nanomechanical systems.
A. Bachtold*, J. Moser*, and M. I. Dykman*.
Reviews of Modern Physics 94, 045005 (2022). Main Text
Parallel Measurements of Vibrational Modes in a Few-Layer Graphene Nanomechanical Resonator Using Software-Defined Radio Dongles.
H. Lu, C. Yang, Y. Tian, J. Wang, C. Zhang, Y. Zhang, F. Chen, Y. Yan, and J. Moser*.
IEEE Access 10, 69981–69991 (2022). Main Text Supplemental Material Original TaiHu Mei song Demodulated TaiHu Mei Demodulated Sonnet Demodulated Musical
See also a report about our work here:
Imaging vibrations of electromechanical few layer graphene resonators with a moving vacuum enclosure.
H. Lu, C. Yang, Y. Tian, J. Lu, F. Xu, C. Zhang, F. Chen, Y. Yan, K. G. Schaedler, C. Wang, F. H. L. Koppens, A. Reserbat-Plantey*, and J. Moser*.
Precision Engineering 72, 769–776 (2021). Main Text Supplemental Material
Absorbance and optical responsivity of two-dimensional mechanical resonators at oblique incidence.
W. Mao, C. Yang, H. Lu, J. Lu, L. Wan, F. Chen, Y. Yan*, and J. Moser*.
Physics Letters A 383 (23), 2755–2760 (2019). Main Text
Robust pulses for high fidelity non-adiabatic geometric gate operations in an off-resonant three-level system.
Y. Yan*, J. Lu, L. Wan, J. Moser*.
Physics Letters A 383 (7), 600–606 (2019). Main Text
Inverse engineering of shortcut pulses for high fidelity initialization on qubits closely spaced in frequency.
Y. Yan, Y. Li, A. Kinos, A. Walther, C. Shi, L. Rippe, J. Moser, S. Kroll, and X. Chen*.
Optics Express 27 (6), 8267–8282 (2019). Main Text
Vibration detection schemes based on absorbance tuning in monolayer molybdenum disulfide mechanical resonators.
F. Chen#, C. Yang#, W. Mao#, H. Lu, K. G Schaedler, A. Reserbat-Plantey, J. Osmond, G. Cao, X. Li, C. Wang, Y. Yan*, and J. Moser*.
2D Materials 6 (1), 011003 (2018). Main Text Supplemental Material
Energy-dependent path of dissipation in nanomechanical resonators.
J. Guettinger, A. Noury, P. Weber, A. M. Eriksson, C. Lagoin, J. Moser, C. Eichler, A. Wallraff, A. Isacsson, and A. Bachtold*.
Nature Nanotechnology 12 (7), 631–636 (2017). Main Text Supplemental Material
Interplay of driving and frequency noise in the spectra of vibrational systems.
Y. Zhang, J. Moser, J. Guettinger, A. Bachtold, and M. I. Dykman*.
Physical Review Letters 113 (25), 255502 (2014). Main Text
Nanotube mechanical resonators with quality factors of up to 5 million.
J. Moser, A. Eichler, Guettinger, M. I. Dykman, and A. Bachtold*.
Nature Nanotechnology 9 (12), 1007–1011 (2014). Main Text Supplemental Material
Symmetry breaking in a mechanical resonator made from a carbon nanotube.
A. Eichler, J. Moser, M. I. Dykman, and A. Bachtold*.
Nature Communications 4, Article number: 2843 (2013). Main Text Supplemental Material
Ultrasensitive force detection with a nanotube mechanical resonator.
J. Moser, J. Guettinger, A. Eichler, M. J. Esplandiu, D. E. Liu, M. I. Dykman, and A. Bachtold*.
Nature Nanotechnology 8 (7), 493–496 (2013). Main Text Supplemental Material
Controlled assembly of graphene sheets and nanotubes: Fabrication of suspended multi-element all-carbon vibrational structures.
I. Tsoutsios, J. Moser, J. A. Plaza, and A. Bachtold*.
Journal of Applied Physics 114 (10), 104310 (2013). Main Text Supplemental Material
Nanomechanical resonators based on nanotubes and graphene.
J. Moser, A. Eichler, J. Chaste, and A. Bachtold.
IEEE Technical Digest, TRANSDUCERS & EUROSENSORS XXVII, p. 657 (2013). Main Text
A nanomechanical mass sensor with yoctogram resolution.
J. Chaste, A. Eichler, J. Moser, G. Ceballo, R. Rurali, and A. Bachtold*.
Nature Nanotechnology 7 (5), 301–304 (2012). Main Text Supplemental Material
Nonlinear damping in mechanical resonators made from carbon nanotubes and graphene.
A. Eichler#, J. Moser#, J. Chaste, M. Zdrojek, I. Wilson-Rae, and A. Bachtold*.
Nature Nanotechnology 6 (6), 339–342 (2011). Main Text Supplemental Material
High-frequency nanotube mechanical resonators.
J. Chaste, M. Sledzinska, M. Zdrojek, J. Moser, and A. Bachtold*.
Applied Physics Letters 99 (21), 213502 (2011). Main Text Supplemental Material
The morphology of graphene sheets treated in an ozone generator.
H. Tao*, J. Moser, F. Alzina, Q. Wang, and C. M. Sotomayor-Torres.
Journal of Physical Chemistry C 115 (37), 18257–18260 (2011). Main Text
Parametric amplification and self-oscillation in a carbon nanotube resonator.
A. Eichler, J. Chaste, J. Moser, and A. Bachtold*.
Nano Letters 11 (7), 2699–2703 (2011). Main Text Supplemental Material
Probing the electron-phonon coupling in ozone-doped graphene by Raman spectroscopy.
F. Alzina*, H. Tao, J. Moser, Y. Garcia, A. Bachtold, and C. M. Sotomayor-Torres.
Physical Review B 82 (7), 075422 (2010). Main Text
Damaging Graphene with Ozone Treatment: A Chemically Tunable Metal-Insulator Transition.
N. Leconte, J. Moser, P. Ordejon, H. Tao, A. Lherbier, A. Bachtold, F. Alsina, C. M. Sotomayor Torres, J.-C. Charlier, and S. Roche*.
ACS Nano 4 (7), 4033–4038 (2010). Main Text
Magnetotransport in disordered graphene exposed to ozone: From weak to strong localization.
J. Moser, H. Tao, S. Roche, F. Alzina, C. M. Sotomayor Torres, and A. Bachtold*.
Physical Review B 81 (20), 205445 (2010). Main Text
Fabrication of large addition energy quantum dots in graphene.
J. Moser and A. Bachtold*.
Applied Physics Letters 95 (17), 173506 (2009). Main Text
Transport properties of graphene in the high-current limit.
A. Barreiro, M. Lazzeri, J. Moser, F. Mauri, and A. Bachtold*.
Physical Review Letters 103 (7), 076601 (2009). Main Text
Influence of the macroscopic shape of the tip on the contrast in scanning polarization force microscopy images.
G. M. Sacha, M. Cardellach, J. J. Segura, J. Moser, A. Bachtold, J. Fraxedas, and A. Verdaguer.
Nanotechnology 20 (28), 285704 (2009). Main Text
Charging and discharging of graphene in ambient conditions studied with scanning probe microscopy.
A. Verdaguer*, M. Cardellach, J. J. Segura, G. M. Sacha, J. Moser, M. Zdrojek, A. Bachtold, and J. Fraxedas.
Applied Physics Letters 94 (23), 233105 (2009). Main Text
Interaction-mediated asymmetries of the quantized Hall effect.
A. Siddiki*, J. Horas, J. Moser, W. Wegscheider and S. Ludwig.
Europhysics Letters 88 (1), 17007 (2009). Main Text
Nanotube based thermal motors: sub-nanometer motion of cargoes driven by thermal gradients.
A. Barreiro, R. Rurali, E. R. Hernandez, J. Moser, T. Pichler, L. Forro, and A. Bachtold*.
Science 320 (5877), 775–778 (2008). Main Text Supplemental Material.
Investigations on unconventional aspects in the quantum Hall regime of narrow gate defined channels.
J. Horas, A. Siddiki, J. Moser, W. Wegscheider, and S. Ludwig.
Physica E: Low-dimensional Systems and Nanostructures 40, 1130–1132 (2008). Main Text
The environment of graphene probed by electrostatic force microscopy.
J. Moser, A. Verdaguer, D. Jimenez, A. Barreiro, and A. Bachtold*.
Applied Physics Letters 92 (12), 123507 (2008). Main Text
Current-induced cleaning of graphene.
J. Moser*, A. Barreiro, and A. Bachtold*.
Applied Physics Letters 91 (16), 163513 (2007). Main Text
Donor binding energy and thermally activated persistent photoconductivity in high mobility (001) AlAs quantum wells.
S. Dasgupta, C. Knaak, J. Moser, M. Bichler, S. F. Roth, A. Fontcuberta i Morral, G. Abstreiter, and M. Grayson*.
Applied Physics Letters 91 (14), 142120 (2007). Main Text
Disordered AlAs wires: Temperature-dependent resonance areas within the Fermi-liquid paradigm.
J. Moser*, S. Roddaro, D. Schuh, M. Bichler, V. Pellegrini, and M. Grayson.
Physical Review B 74 (19), 193307 (2006). Main Text
Cleaved-edge-overgrown aluminum arsenide quantum wires.
J. Moser*, T. Zibold, D. Schuh, M. Bichler, F. Ertl, G. Abstreiter, M. Grayson, S. Roddaro, and V. Pellegrini.
Applied Physics Letters 87 (5), 052101 (2005). Main Text
Individual free-standing carbon nano-fibers addressable on the 50 nm scale.
J. Moser, R. Panepucci, Z. P. Huang, W. Z. Li, Z. F. Ren, A. Usheva, and M. J. Naughton.
Journal of Vacuum Science and Technology B 21 (3), 1004–1007 (2003). Main Text
YY1-DNA interaction results in a significant change of electronic context as measured by capacitance.
C. H. Choi, J. Moser, N. Sabourin, K. Blagoev, M. J. Naughton, and A. Usheva.
Biophysical Chemistry 103 (2), 109–115 (2003). Main Text
Fabrication of Air Bridges using Electron Beam Lithography.
M. A. Gritz, M. Metzler, J. Moser, D. Spencer, and G. D. Boreman.
Journal of Vacuum Science and Technology B 21 (1), 332–334 (2003). Main Text
Zero bias conductance peak in an SNS weak link bicrystal of the triplet superconductor (TMTSF)2ClO4.
H. I. Ha, J. I. Oh, J. Moser, and M. J. Naughton.
Synthetic Metals 137 (1), 1215–1216 (2003). Main Text
Synthesis and Properties of Superconductor RuSr2GdCu2O8.
D. Z. Wang, H. I. Ha, J. I. Oh, J. Moser, J. G. Wen, M. J. Naughton, and Z. F. Ren.
Physica C 384 (1), 137–142 (2003). Main Text
Efficient multiphoton polymerization for the fabrication of 3-dimensional microstructures.
T. Baldacchini, R. A. Farrer, J. Moser, J. T. Fourkas, and M. J. Naughton.
Synthetic Metals 135–136, 11 (2003). Main Text
Intersubband transport in quantum wells in strong magnetic fields mediated by single- and two-electron scattering.
K. Kempa, Y. Zhou, J. R. Engelbrecht, P. Bakshi, H. I. Ha, J. Moser, M. J. Naughton, J. Ulrich, G. Strasser, E. Gornik, and K. Unterrainer.
Physical Review Letters 88 (22), 226803 (2002). Main Text
Multiphoton photopolymerization with a Ti:sapphire oscillator.
T. Baldacchini, H. Chen, R. A. Farrer, M. J. R. Previte, J. Moser, M. J. Naughton, and J. T. Fourkas.
Proc. SPIE 4633, 136 (2002). Main Text
Fabrication of Free-Standing Carbon Nanotube Arrays in Large Scale.
Z. P. Huang, J. Moser, M. Sennett, H. Gibson, M. J. Naughton, J. G. Wen, and Z. F. Ren.
Mat. Res. Soc. Symp. Proc. 633, A13.22 (2002). Main Text
The case for universality of the phase diagram of the Fabre and Bechgaard salts.
H. Wilhelm, D. Jaccard, R. Duprat, C. Bourbonnais, D. Jerome, J. Moser, C. Carcel, and J. M. Fabre.
European Physical Journal B 21 (2), 175–183 (2001). Main Text
From spin-Peierls to superconductivity: (TMTTF)2PF6 under high pressure.
D. Jaccard, H. Wilhelm, D. Jerome, J. Moser, C. Carcel, and J. M. Fabre.
Journal of Physics-Condensed Matter 13 (4), L89–L95 (2001). Main Text
Exploring the field-induced spin density wave phase of the organic conductor (TMTSF)2ClO4.
W. Kang, O. H. Chung, J. Moser, H. Kang, and D. Jerome.
Synthetic Metals 120, 1073 (2001). Main Text
Hall effect in the normal phase of the organic superconductor (TMTSF)2PF6.
J. Moser*, J. R. Cooper, D. Jerome, B. Alavi, S. E. Brown, and K. Bechgaard.
Physical Review Letters 84 (12), 2674–2677 (2000). Main Text
Transverse transport in organic conductors: possible evidence for a Luttinger liquid.
J. Moser*, M. Gabay, P. Auban-Senzier, D. Jerome, K. Bechgaard, and J. M. Fabre.
European Physical Journal B 1, 39–46 (1998). Main Text
Dissipative and conservative nonlinearity in carbon nanotube and graphene mechanical resonators.
J. Moser, A. Eichler, B. Lassagne, J. Chaste, Y. Tarakanov, J. Kinaret, I. Wilson-Rae, and A. Bachtold.
In Fluctuating Nonlinear Oscillators: From Nanomechanics to Quantum Superconducting Circuits, Oxford University Press (2011), pp. 341–361, ISBN-13: 9780199691388. Main Text
Pressure-induced superconductivity in the spin-Peierls compound (TMTTF)2PF6.
H. Wilhelm, D. Jaccard, D. Jerome, J. Moser, R. Duprat, and C. Bourbonnais.
In Frontiers of High Pressure Research II: Application of High Pressure to Low-Dimensional Novel Electronic Materials, Springer (2001), pp. 423–435, ISBN: 978-94-010-0520-3. Main Text
Static and dynamic analysis of electrostatically driven graphene nanomechanical drum resonators based on finite element models.
Ce Zhang, YuBin Zhang, Chen Yang, FengNan Chen, Heng Lu, Ying Yan, and Joel Moser*.
Proc. SPIE 12921, 1292116 (2023). Main Text
Resonant frequency decay in graphene nanomechanical resonators fabricated by focused ion beam lithography.
Y. Xian, W. Song, H. Lu, F. Chen, C. Yang, Y. Tian, Y. Yan, Y. Ying, Z.-Z. Zhang, X.-X. Song, and J. Moser*.
Proc. SPIE 12556, 1255602, AOPC 2022 (2022). Main Text
Fabrication of graphene nanomechanical resonators using focused ion beam lithography.
W. Song, Y. Xian, H. Lu, F. Chen, C. Zhang, Y. Zhang, Y. Yan, and J. Moser*.
Proc. SPIE 12556, 1255603, AOPC 2022 (2022). Main Text
A new flexible radio frequency microstrip used in a cryostat.
F.-Q. Xu, H. Lu, C. Yang, Y. Tian, F. Chen, Y. Yan, and J. Moser*.
Proc. IEEE 42–45, ECIE 2021 (2021). Main Text
A method for measuring the width of a focused laser beam in reflection.
J. Lu, H. Lu, A. Reserbat-Plantey, C. Yang, Y. Tian, F. Chen, Y. Yan, and J. Moser*.
Proc. SPIE 11562, 1156205, AOPC 2020 (2020). Main Text
Optimized fabrication and detection of nanomechanical resonators based on graphene membranes.
Y. Tian, C. Yang, H. Lu, F. Chen, F.-Q. Xu, J. Lu, Y.-L. Xian, W. Song, Y. Yan, and J. Moser*.
Proc. SPIE 11617, 1161732, OMTA 2020 (2020). Main Text
Nonadiabatic robust pulses for creating superposition states in a resonant three-level system.
L. Wan, Y. Yan, and J. Moser*.
Proc. SPIE 11339, 113390D, AOPC 2019 (2019). Main Text
Oblique incidence reflectance of resonators based on suspended two-dimensional membranes.
W. Mao, C. Yang, H. Lu, J. Lu, F. Chen, L. Wan, Y. Yan, and J. Moser*.
Proc. SPIE 11064, 110640W, TFPA 2019 (2019). Main Text
Optical responsivity of mechanical resonators based on suspended membranes of graphene and transition metal dichalcogenides.
F. Chen, W. Mao, C. Yang, H. Lu, K. G. Schaedler, A. Reserbat-Plantey, J. Osmond, G. Cao, X. Li, C. Wang, Y. Yan, and J. Moser*.
Proc. SPIE 10840, 1084008, AOMATT 2018 (2019). Main Text
Joel Moser, Ying Yan, FanQie Xu, Heng Lu, FengNan Chen.
Heng Lu, Joel Moser, FengNan Chen.
Heng Lu, Joel Moser, FengNan Chen.
FanQie Xu, Heng Lu, Ying Yan, Joel Moser, FengNan Chen.
FanQie Xu, Heng Lu, Ying Yan, Joel Moser, FengNan Chen.
Heng Lu, Joel Moser, Ying Yan, FengNan Chen.