Jain, T. et al. Heterogeneous sub-Continuum ionic transport in statistically isolated graphene nanopores.
Nature Nanotechnology10, 1053–1057 (2015). DOI:
10.1038/nnano.2015.222Kunz, D. A. et al. Space-Resolved In-Plane Moduli of Graphene Oxide and Chemically Derived Graphene Applying a Simple Wrinkling Procedure.
Advanced Materials25, 1336–1336 (2013). DOI:
10.1002/adma.201370060Nagamanasa, K. H. et al. Liquid-Cell Electron Microscopy of Adsorbed Polymers.
Advanced Materials29, 1703555 (2017). DOI:
10.1002/adma.201703555Chen, X.; Wolff, S.; Zuieva, S. Patterned Assembly of Transition Metal Dichalcogenide/Graphene Heterostructures via Direct Laser Writing.
Advanced Functional Materials35 (2025). DOI:
10.1002/adfm.202425776Chen, R. et al. Co-Percolating Graphene-Wrapped Silver Nanowire Network for High Performance, Highly Stable, Transparent Conducting Electrodes.
Advanced Functional Materials23, 5150–5158 (2013). DOI:
10.1002/adfm.201300124Xue, M.; Mackin, C.; Weng, W.-H.; Zhu, J.; Luo, Y.; Luo, S.-X. L.; et al. Integrated biosensor platform based on graphene transistor arrays for real-time high-accuracy ion sensing.
Nature Communications13 (2022). DOI:
10.1038/s41467-022-32749-4Klusch, N.; Dreimann, M.; Senkler, J.; Rugen, N.; Kühlbrandt, W.; Braun, H.-P. Cryo-EM structure of the respiratory I + III2 supercomplex from Arabidopsis thaliana at 2 Å resolution.
Nature Plants9, 142-156 (2022). DOI:
10.1038/s41477-022-01308-6Ahn, E.; Kim, B.; Park, S.; Erwin, A. L.; Sung, S. H.; Hovden, R. Batch Production of High-Quality Graphene Grids for Cryo-EM: Cryo-EM Structure of Methylococcus capsulatus Soluble Methane Monooxygenase Hydroxylase.
ACS Nano17, 6011-6022 (2023). DOI:
10.1021/acsnano.3c00463Scott, R. J.; Valencia-Acuna, P.; Zhao, H. Spatiotemporal observation of quasi-ballistic transport of electrons in graphene.
ACS nano17, 25368-25376 (2023). DOI:
10.1021/acsnano.3c08816Chen, J.; Sarkar, A.; Rahman, M. S.; Ravel, V.; Franklin, A. D. Robust Memcapacitive Synapse Array for Energy-Efficient Motion Detection.
ACS Nano19, 15974-15982 (2025). DOI:
10.1021/acsnano.5c02340O'Hern, S. C. et al. Selective Molecular Transport through Intrinsic Defects in a Single Layer of CVD Graphene.
ACS Nano6, 10130–10138 (2012). DOI:
10.1021/nn303869mBoutilier, M. S. H. et al. Implications of Permeation through Intrinsic Defects in Graphene on the Design of Defect-Tolerant Membranes for Gas Separation.
ACS Nano8, 841–849 (2014). DOI:
10.1021/nn405537uFritsch, B.; Zech, T. S.; Bruns, M. P.; Körner, A.; Khadivianazar, S.; Wu, M.; et al. Radiolysis-Driven Evolution of Gold Nanostructures - Model Verification by Scale Bridging In Situ Liquid-Phase TEM and X-Ray.
Advanced Science9 (2022). DOI:
10.1002/advs.202202803Bukola, S. et al. Selective Proton/Deuteron Transport through Nafion|Graphene|Nafion Sandwich Structures at High Current Density.
Journal of the American Chemical Society140, 1743–1752 (2018). DOI:
10.1021/jacs.7b10853Qing, R.; Xue, M.; Zhao, J.; Wu, L.; Breitwieser, A.; Smorodina, E.; et al. Scalable biomimetic sensing system with membrane receptor dual-monolayer probe and graphene transistor arrays.
Science Advances9 (2023). DOI:
10.1126/sciadv.adf1402Schweizer, P.; Dolle, C.; Spiecker, E. In situ manipulation and switching of dislocations in bilayer graphene.
Science Advances4 (2018). DOI:
10.1126/sciadv.aat4712Hu, J.; Vanacore, G. M.; Cepellotti, A.; Marzari, N.; Zewail, A. H. Rippling ultrafast dynamics of suspended 2D monolayers, graphene.
Proceedings of the National Academy of Sciences113 (2016). DOI:
10.1073/pnas.1613818113Hwang, M. T. et al. Highly specific SNP detection using 2D graphene electronics and DNA strand displacement.
Proceedings of the National Academy of Sciences113, 7088–7093 (2016). DOI:
10.1073/pnas.1603753113Mccaffrey, D. L. et al. Mechanism of ion adsorption to aqueous interfaces: Graphene/Water vs. air/Water.
Proceedings of the National Academy of Sciences114, 13369–13373 (2017). DOI:
10.1073/pnas.1702760114Miskin, M. Z. et al. Graphene-Based bimorphs for micron-Sized, autonomous origami machines.
Proceedings of the National Academy of Sciences115, 466–470 (2018). DOI:
10.1073/pnas.1712889115Nagel, T.; Wolff, S.; Feng, S.; Weber, H.; Maultzsch, J.; Hauke, F.; et al. Towards precision controlled 2D functional group patterning of graphene via laser writing.
Carbon241, 120376 (2025). DOI:
10.1016/j.carbon.2025.120376Xu, W.; Xie, L.; Ying, Y. Tunable transparent terahertz absorber for sensing and radiation warming.
Carbon214, 118376 (2023). DOI:
10.1016/j.carbon.2023.118376Xu, W.; Xie, L.; Zhu, J.; Tang, L.; Singh, R.; Wang, C.; et al. Terahertz biosensing with a graphene-metamaterial heterostructure platform. Carbon (2019).
Chen, X.-D. et al. High-Quality and efficient transfer of large-Area graphene films onto different substrates.
Carbon56, 271–278 (2013). DOI:
10.1016/j.carbon.2013.01.011Ye, X. et al. Protecting carbon steel from corrosion by laser in situ grown graphene films.
Carbon94, 326–334 (2015). DOI:
10.1016/j.carbon.2015.06.080Zhou, R.; Wang, C.; Huang, Y.; Huang, K.; Wang, Y.; Xu, W.; et al. Label-free terahertz microfluidic biosensor for sensitive DNA detection using graphene-metasurface hybrid structures.
Biosensors and Bioelectronics188, 113336 (2021). DOI:
10.1016/j.bios.2021.113336Alansary, D.; Peckys, D. B.; Niemeyer, B. A.; Jonge, N. D. Detecting single ORAI1 proteins within the plasma membrane reveals higher-order channel complexes.
Journal of Cell Science133 (2020). DOI:
10.1242/jcs.240358Kou, J.-L. et al. Platform for enhanced light–graphene interaction length and miniaturizing fiber stereo devices.
Optica1, 307 (2014). DOI:
10.1364/optica.1.000307Choi, D. et al. Nanopatterned Graphene Field Effect Transistor Fabricated Using Block Co-Polymer Lithography.
Materials Research Letters2, 131–139 (2014). DOI:
10.1080/21663831.2013.876676Xu, W.; Huang, Y.; Zhou, R.; Wang, Q.; Yin, J. Metamaterial-free flexible graphene-enabled terahertz sensors for pesticide detection at bio-interface.
ACS Appl. Mater. Interfaces12, 44281-44287 (2020). DOI:
10.1021/acsami.0c11461Komma, M.; Freiberg, A. T. S.; Abbas, D. Applicability of single-layer graphene as a hydrogen-blocking interlayer in low-temperature PEMFCs.
ACS Appl. Mater. Interfaces (2024). DOI:
10.1021/acsami.4c01254Zheng, G. et al. Improved Transfer Quality of CVD-Grown Graphene by Ultrasonic Processing of Target Substrates: Applications for Ultra-Fast Laser Photonics.
ACS Applied Materials & Interfaces5, 10288–10293 (2013). DOI:
10.1021/am403205vTang, X. et al. Five Orders of Magnitude Reduction in Energy Coupling across Corrugated Graphene/Substrate Interfaces.
ACS Applied Materials & Interfaces6, 2809–2818 (2014). DOI:
10.1021/am405388aYin, Y. et al. Graphene-Activated Optoplasmonic Nanomembrane Cavities for Photodegradation Detection. ACS applied materials & interfaces (2019).
Dolle, C.; Schweizer, P.; Dasler, D.; Gsänger, S.; Maidl, R.; Abellán, G.; et al. Atomically resolved TEM imaging of covalently functionalised graphene.
npj 2D Materials and Applications6 (2022). DOI:
10.1038/s41699-022-00304-wZakiyyan, N.; Mathai, C.; McFarland, J.; Gangopadhyay, S.; Maschmann, M. R. Spallation of isolated aluminum nanoparticles by rapid photothermal heating.
ACS Applied Materials & Interfaces14, 55277-55284 (2022). DOI:
10.1021/acsami.2c18678Bhattarai, A.; Krayev, A.; Temiryazev, A.; Evplov, D.; Crampton, K. T.; Hess, W. P.; et al. Tip-enhanced Raman scattering from nanopatterned graphene and graphene oxide.
Nano Letters18, 4029-4033 (2018). DOI:
10.1021/acs.nanolett.8b01690Li, P. et al. Graphene-Enhanced Infrared Near-Field Microscopy.
Nano Letters14, 4400–4405 (2014). DOI:
10.1021/nl501376aLee, J. et al. Switching Individual Quantum Dot Emission through Electrically Controlling Resonant Energy Transfer to Graphene.
Nano Letters14, 7115–7119 (2014). DOI:
10.1021/nl503587zThareja, V. et al. Electrically Tunable Coherent Optical Absorption in Graphene with Ion Gel.
Nano Letters15, 1570–1576 (2015). DOI:
10.1021/nl503431dDeng, T. et al. Three-dimensional graphene field-effect transistors as high-performance photodetectors. Nano letters (2019).
Hutzler, A. et al. Unravelling the Mechanisms of Gold–Silver Core–Shell Nanostructure Formation by in Situ TEM Using an Advanced Liquid Cell Design. Nano letters 18, no.11 (2018).
Maier, M.; Abbas, D.; Komma, M.; Mu'min, M. S.; Thiele, S.; Böhm, T. A comprehensive study on the ionomer properties of PFSA membranes with confocal Raman microscopy.
Journal of Membrane Science669, 121244 (2023). DOI:
10.1016/j.memsci.2022.121244Tian, Y.; Yu, L.; Zhuang, C.; Zhang, G.; Sun, S. Fast synthesis of Pt single-atom catalyst with high intrinsic activity for hydrogen evolution reaction by plasma sputtering.
Materials Today Energy22, 100877 (2021). DOI:
10.1016/j.mtener.2021.100877Blinco, J. P. Spin-Coated carbon.
Chemical Science, no.9, 12 (2013). DOI:
10.1039/c3sc51396cGuo, C.-C. et al. Experimental Demonstration of Total Absorption over 99% in the Near Infrared for Monolayer-Graphene-Based Subwavelength Structures.
Advanced Optical Materials, 1 Sept. 2016 (2016). DOI:
10.1002/adom.201600481Kafiah, F. M. et al. Monolayer graphene transfer onto polypropylene and polyvinylidenedifluoride microfiltration membranes for water desalination.
Desalination388, 29–37 (2016). DOI:
10.1016/j.desal.2016.02.027Nieto, A. et al. Graphene reinforced metal and ceramic matrix composites: a review.
International Materials Reviews62, 241–302 (2017). DOI:
10.1080/09506608.2016.1219481Wen, C. et al. Assessing kinetics of surface adsorption–desorption of gas molecules via electrical measurements.
Sensors and Actuators B: Chemical223, 791–798 (2016). DOI:
10.1016/j.snb.2015.10.019Li, C. et al. Manipulation of Nonlinear Optical Properties of Graphene Bonded Fiber Devices by Thermally Engineering Fermi-Dirac Distribution.
Advanced Optical Materials5 (2017). DOI:
10.1002/adom.201770103Zhao, J. et al. In situ Optical Study of Gold Nanorod Coupling with Graphene. Advanced Optical Materials 6, no.8 (2018).
Hu, M. et al. Performance Improvement of Graphene/Silicon Photodetectors Using High Work Function Metal Nanoparticles with Plasma Effect. Advanced Optical Materials 6, no.9 (2018).
Andoy, N. M. et al. Graphene-Based Electronic Immunosensor with Femtomolar Detection Limit in Whole Serum. Advanced Materials Technologies 3, no.12 (2018).
Wu, Y.; Yan, Y.; Yang, Y.; Bian, S.; Rivetta, A.; Allen, K.; et al. CryoEM structures of Kv1.2 potassium channels, conducting and non-conducting.
eLife12 (2025). DOI:
10.7554/elife.89459Brown, M. A. et al. Graphene Biotransistor Interfaced with a Nitrifying Biofilm.
Environmental Science & Technology Letters2, 118–122 (2015). DOI:
10.1021/acs.estlett.5b00025Zhang, Q.; Chen, S.; Zhang, S.; Shang, W.; Liu, L.; Wang, M.; et al. Negative differential resistance and hysteresis in graphene-based organic light-emitting devices.
Journal of Materials Chemistry C6, 1926-1932 (1926). DOI:
10.1039/c7tc05148dKorzeniewski, C.; Kitt, J. P.; Bukola, S.; Creager, S. E. Single layer graphene for estimation of axial spatial resolution in confocal Raman microscopy depth profiling.
Anal. Chem.91, 1049-1055 (2018). DOI:
10.1021/acs.analchem.8b04390Jiang, W.-S. et al. Preparation of high-Quality graphene using triggered microwave reduction under an air atmosphere.
Journal of Materials Chemistry C, 2018 (2018). DOI:
10.1039/c7tc03957cFilipiak, M. S.; Vetter, D.; Thodkar, K.; Gutierrez-Sanz, O. Electron transfer from FAD-dependent glucose dehydrogenase to single-sheet graphene electrodes. Electrochimica Acta330, 134998 (2020).
Zeng, Y. et al. Investigate the interface structure and growth mechanism of high quality ZnO films grown on multilayer graphene layers.
Applied Surface Science301, 391–395 (2014). DOI:
10.1016/j.apsusc.2014.02.088Pápa, Z. et al. Spectroscopic ellipsometric investigation of graphene and thin carbon films from the point of view of depolarization effects.
Applied Surface Science421, 714–721 (2017). DOI:
10.1016/j.apsusc.2016.11.231Su, F. et al. Long-term stability of photodetectors based on graphene field-effect transistors encapsulated with Si3N4 layers. Applied Surface Science459 (2018).
Peckys, D. B.; Hirsch, D.; Gaiser, T.; Jonge, N. D. Visualisation of HER2 homodimers in single cells from HER2 overexpressing primary formalin fixed paraffin embedded tumour tissue. Molecular medicine (2019).
Ruiz, I.; Beechem, T. E.; Smith, S.; Dickens, P.; Paisley, E. A.; Shank, J.; et al. Interface defect engineering for improved graphene-oxide-semiconductor junction photodetectors.
ACS Applied Nano Materials2, 6162-6168 (2019). DOI:
10.1021/acsanm.9b00978Periasamy, A.; Ornelas, P.; Bausewein, T.; Mitchell, N.; Zhao, J.; Quinn, L. M.; et al. Structure of an ex vivo Drosophila TOM complex determined by single-particle cryoEM.
IUCrJ12, 49-61 (2025). DOI:
10.1107/s2052252524011011Hui, F. et al. Moving graphene devices from lab to market: advanced graphene-Coated nanoprobes.
Nanoscale8, 8466–8473 (2016). DOI:
10.1039/c5nr06235gWeinberg, F.; Peckys, D. B.; Jonge, N. D. EGFR expression in HER2-driven breast cancer cells.
International Journal of Molecular Sciences21, 9008 (2020). DOI:
10.3390/ijms21239008Eguchi, R.; Hashimoto, A. Multiscale structural analysis of defective graphene in transmission electron microscopy images using persistent homology.
APL Materials14 (2026). DOI:
10.1063/5.0305461Yan, X.; Cao, H.; Li, Y.; Hong, H.; Gosztola, D. J.; Guisinger, N. P.; et al. In situ x-ray studies of growth of complex oxides on graphene by molecular beam epitaxy.
APL Materials10 (2022). DOI:
10.1063/5.0101416Hui, F. Variability of graphene devices fabricated using graphene inks: Atomic force microscope tips.
Surface and Coatings Technology320 (2017). DOI:
10.1016/j.surfcoat.2016.12.020Peckys, D. B.; Gaa, D.; Jonge, N. D. Quantification of EGFR-HER2 heterodimers in HER2-overexpressing breast cancer cells using liquid-phase electron microscopy.
Cells10, 3244 (2021). DOI:
10.3390/cells10113244Demongodin, P.; Dirani, H. E.; Lhuillier, J.; Crochemore, R.; Kemiche, M.; Wood, T.; et al. Ultrafast saturable absorption dynamics in hybrid graphene/Si3N4 waveguides.
APL Photonics4 (2019). DOI:
10.1063/1.5094523Jumaah, A. J.; Roskos, H. G.; Al-Daffaie, S. Novel antenna-coupled terahertz photodetector with graphene nanoelectrodes.
APL Photonics8 (2023). DOI:
10.1063/5.0127264Luo, W.; Doh, W. H.; Law, Y. T.; Aweke, F.; Ksiazek-Sobieszek, A.; Sobieszek, A.; et al. Single-Layer Graphene as an Effective Mediator of the Metal-Support Interaction.
The Journal of Physical Chemistry Letters5, 1837-1844 (2014). DOI:
10.1021/jz500425jFujita, J.; Makino, F.; Asahara, H.; Moriguchi, M.; Kumano, S.; Anzai, I.; et al. Epoxidized graphene grid for highly efficient high-resolution cryoEM structural analysis.
Scientific Reports13 (2023). DOI:
10.1038/s41598-023-29396-0Beechem, T. E.; Shaffer, R. A.; Nogan, J.; Ohta, T.; Hamilton, A. B.; McDonald, A. E.; et al. Self-heating and failure in scalable graphene devices.
Scientific Reports6 (2016). DOI:
10.1038/srep26457Howell, S. W.; Ruiz, I.; Davids, P. S.; Harrison, R. K.; Smith, S. W.; Goldflam, M. D.; et al. Graphene-insulator-semiconductor junction for hybrid photodetection modalities.
Scientific Reports7 (2017). DOI:
10.1038/s41598-017-14934-4Lau, K. Y.; Muhammad, F. D.; Latif, A. A.; Bakar, M. H. A.; Yusoff, Z.; Mahdi, M. A. Passively mode-locked soliton femtosecond pulses employing graphene saturable absorber.
Optics & Laser Technology94, 221-227 (2017). DOI:
10.1016/j.optlastec.2017.03.035Srisonphan, S. et al. Space charge neutralization by electron-Transparent suspended graphene.
Scientific Reports4 (2014). DOI:
10.1038/srep03764Liu, X. et al. Compact Shielding of Graphene Monolayer Leads to Extraordinary SERS-Active Substrate with Large-Area Uniformity and Long-Term Stability.
Scientific Reports5 (2015). DOI:
10.1038/srep17167Khorasaninejad, M. et al. Highly Enhanced Raman Scattering of Graphene using Plasmonic Nano-Structure.
Scientific Reports3 (2013). DOI:
10.1038/srep02936Du, F. et al. Surface stress of graphene layers supported on soft substrate.
Scientific Reports6 (2016). DOI:
10.1038/srep25653Lee, I.-K. et al. The effects of graphene content on the mechanical properties and thermal conductivity of Inconel 718 superalloy brazed using BNi-2/graphene composite filler metal. Results in Physics (2019).
Amsterdam, S. H.; Mane, A. U.; Martinson, A. B. F. Ultrathin amorphous gallium oxide vacuum ultraviolet photodetectors.
ACS Applied Electronic Materials5, 5962-5967 (2023). DOI:
10.1021/acsaelm.3c00918Gao, X.; Yu, X.; Li, B.; Fan, S.; Li, C. Measuring Graphene Adhesion on Silicon Substrate by Single and Dual Nanoparticle-Loaded Blister.
Advanced Materials Interfaces4 (2017). DOI:
10.1002/admi.201601023Zheng, X.; Liu, Y.; Zhen, J.; Qiu, J.; Liu, G. Research on Fabrication of Phononic Crystal Soft-Supported Graphene Resonator.
Nanomaterials14, 130 (2024). DOI:
10.3390/nano14020130Li, C.; Gao, X.; Fan, S.; Wang, D.; Jin, W. Measurement of the adhesion energy of pressurized graphene diaphragm using optical fiber Fabry-Perot interference.
IEEE Sensors Journal16, 3664-3669 (2016). DOI:
10.1109/jsen.2016.2536783Cheng, L.; Qianwen, L.; Tingting, G.; Jun, X.; Shangchun, F.; Wei, J. An ultra-high sensitivity Fabry-Perot acoustic pressure sensor using a multilayer suspended graphene diaphragm.
2015 IEEE SENSORS, 1-4 (2015). DOI:
10.1109/icsens.2015.7370318Wang, J.; Zhu, Z.; Qi, Y.; Li, M. A Novel Crossbeam Structure with Graphene Sensing Element for N/MEMS Mechanical Sensors.
Nanomaterials12, 2101 (2022). DOI:
10.3390/nano12122101Adams, J. D.; Emam, S.; Sun, N.; Ma, Y.; Wang, Q. A molecularly imprinted polymer-graphene sensor antenna hybrid for ultra sensitive chemical detection. IEEE Sensors Journal19, 6571-6577 (2019).
Badokas, K.; Kadys, A.; Augulis, D.; Mickevičius, J. MOVPE growth of GaN via graphene layers on GaN/sapphire templates. Nanomaterials12, 785 (2022).
Hutzler, A. et al. In Situ Liquid Cell TEM Studies on Etching and Growth Mechanisms of Gold Nanoparticles at a Solid–Liquid–Gas Interface. Advanced Materials Interfaces (2019).
Fitri, M. A.; Ota, M.; Hirota, Y.; Uchida, Y.; Hara, K.; Ino, D.; et al. Fabrication of TiO2-Graphene photocatalyst by direct chemical vapor deposition and its anti-Fouling property.
Materials Chemistry and Physics198, 42-48 (2017). DOI:
10.1016/j.matchemphys.2017.05.053Zheng, S.; Zhang, H.; Feng, Z.; Yu, Y.; Zhang, R. Acoustic charge transport induced by the surface acoustic wave in chemical doped graphene. Appl. Phys. Lett.109 (2016).
Yoo, J.-H. et al. Graphene folds by femtosecond laser ablation.
Applied Physics Letters100, 233124 (2012). DOI:
10.1063/1.4724213Longchamp, J.-N. et al. Low-Energy electron transmission imaging of clusters on free-Standing graphene.
Applied Physics Letters101, 113117 (2012). DOI:
10.1063/1.4752717Ye, Q. et al. Polarization-Dependent optical absorption of graphene under total internal reflection.
Applied Physics Letters102. DOI:
10.1063/1.4776694Wang; Yu, Y.; Burke, A. P. J. A large-Area and contamination-Free graphene transistor for liquid-Gated sensing applications.
Applied Physics Letters103, 052103 (2013). DOI:
10.1063/1.4816764Wang, P. et al. Accurate layers determination of graphene on transparent substrate based on polarization-Sensitive absorption effect.
Applied Physics Letters103, 181902 (2013). DOI:
10.1063/1.4827812Joiner, C. A. et al. Cleaning graphene with a titanium sacrificial layer.
Applied Physics Letters104, 223109 (2014). DOI:
10.1063/1.4881886Roy, T. et al. Tunneling characteristics in chemical vapor deposited graphene–hexagonal boron nitride–graphene junctions.
Applied Physics Letters104, 123506 (2014). DOI:
10.1063/1.4870073He, Y. et al. Strongly enhanced Raman scattering of graphene by a single gold nanorod.
Applied Physics Letters107, 053104 (2015). DOI:
10.1063/1.4927759Cao, Z. et al. Nano-Gap between a gold tip and nanorod for polarization dependent surface enhanced Raman scattering.
Applied Physics Letters109, 233103 (2016). DOI:
10.1063/1.4971832Liang, J. et al. Modulation of acousto-Electric current using a hybrid on-Chip AlN SAW/GFET device.
Applied Physics Letters110, 243504 (2017). DOI:
10.1063/1.4986481Woo; Oh, S.; Teizer, A. W. The effect of electron induced hydrogenation of graphene on its electrical transport properties.
Applied Physics Letters103, 041603 (2013). DOI:
10.1063/1.4816475Wu, T. et al. Low-frequency noise in irradiated graphene FETs. Applied Physics Letters 113, no.19 (2018).
Barnard, H. R. et al. Boron nitride encapsulated graphene infrared emitters. Applied Physics Letters 108, no.13 (2016).
Hutzler, A. et al. Generalized approach to design multi-layer stacks for enhanced optical detectability of ultrathin layers. Applied Physics Letters 110, no.2 (2017).
Peng, S.; Lohse, D.; Zhang, X. Microwetting of supported graphene on hydrophobic surfaces revealed by polymerized interfacial femtodroplets.
Langmuir30, 10043-10049 (2014). DOI:
10.1021/la5022774Xu, W.; Wang, Q.; Zhou, R.; Hameed, S.; Ma, Y.; Xie, L. Defect-rich graphene-coated metamaterial device for pesticide sensing in rice. RSC advances (2022).
Bonavolontà, C.; Vettoliere, A.; Pannico, M.; Crisci, T.; Ruggiero, B.; Silvestrini, P.; et al. Investigation of Graphene Single Layer on P-Type and N-Type Silicon Heterojunction Photodetectors.
Sensors24, 6068 (2024). DOI:
10.3390/s24186068Srisonphan; Siwapon; Hongesombut, A. K. Tuning the ballistic electron transport of spatial graphene–metal sandwich electrode on a vacuum-Silicon-Based device.
RSC Advances5, 2032–2037 (2015). DOI:
10.1039/c4ra09503kYe, X. H. et al. Corrosion resistance of graphene directly and locally grown on bulk nickel substrate by laser irradiation.
RSC Advances5, 35384–35390 (2015). DOI:
10.1039/c5ra01267hYokaribas, V. et al. Strain Gauges Based on CVD Graphene Layers and Exfoliated Graphene Nanoplatelets with Enhanced Reproducibility and Scalability for Large Quantities.
Sensors17, 2937 (2017). DOI:
10.3390/s17122937Li, C.; Liu, Q.; Peng, X.; Fan, S. Analyzing the temperature sensitivity of Fabry-Perot sensor using multilayer graphene diaphragm.
Optics Express23, 27494 (2015). DOI:
10.1364/oe.23.027494Goldflam, M. D.; Ruiz, I.; Howell, S. W.; Wendt, J. R.; Sinclair, M. B.; Peters, D. W.; et al. Tunable dual-band graphene-based infrared reflectance filter.
Optics Express26, 8532 (2018). DOI:
10.1364/oe.26.008532Wood, T.; Lhuillier, J.; Kemiche, M.; Demongodin, P.; Vilquin, B.; Romeo, P. R.; et al. Low-voltage, broadband graphene-coated Bragg mirror electro-optic modulator at telecom wavelengths.
Optics Express28, 27506 (2020). DOI:
10.1364/oe.398480Niu, T. et al. Indentation behavior of the stiffest membrane mounted on a very compliant substrate: Graphene on PDMS.
International Journal of Solids and Structures132, 1–8 (2018). DOI:
10.1016/j.ijsolstr.2017.05.038Weinberg, F.; Han, M. K. L.; Dahmke, I. N.; Campo, A. D.; Jonge, N. D. Anti-correlation of HER2 and focal adhesion complexes in the plasma membrane.
PLOS ONE15 (2020). DOI:
10.1371/journal.pone.0234430Mckitterick, C. B. et al. Electron-Phonon cooling in large monolayer graphene devices.
Physical Review B93 (2016). DOI:
10.1103/physrevb.93.075410Yuan, J. et al. Modulation of far-Infrared light transmission by graphene-Silicon Schottky junction.
Optical Materials Express6, 3908 (2016). DOI:
10.1364/ome.6.003908Kafiah, F. et al. Synthesis of Graphene Based Membranes: Effect of Substrate Surface Properties on Monolayer Graphene Transfer.
Materials10, 86 (2017). DOI:
10.3390/ma10010086Nemani, S. K.; Chen, D.; Mohamed, M. H. Stretchable and hydrophobic electrochromic devices using wrinkled graphene and PEDOT: PSS.
Journal of Nanomaterials2018, 1-10 (2018). DOI:
10.1155/2018/3230293Boutilier, M. S. H. et al. Knudsen effusion through polymer-Coated three-Layer porous graphene membranes.
Nanotechnology28, 184003 (2017). DOI:
10.1088/1361-6528/aa680fSchweizer, P.; Denninger, P.; Dolle, C.; Spiecker, E. Low energy nano diffraction (LEND) - A versatile diffraction technique in SEM.
Ultramicroscopy213, 112956 (2020). DOI:
10.1016/j.ultramic.2020.112956Deng, X. et al. Terahertz-Induced photothermoelectric response in graphene-Metal contact structures.
Journal of Physics D: Applied Physics49, 425101 (2016). DOI:
10.1088/0022-3727/49/42/425101Denninger, P.; Schweizer, P.; Spiecker, E. Characterization of extended defects in 2D materials using aperture-based dark-field STEM in SEM.
Micron186, 103703 (2024). DOI:
10.1016/j.micron.2024.103703Becker, A.; Zeller, G.; Lippold, H.; Eren, I. Graphene Structure Modification under Tritium Exposure: 3H Chemisorption Dominates over Defect Formation by beta Radiation.
J. Phys. Chem. C129, 21995-22005 (2025). DOI:
10.1021/acs.jpcc.5c04255Hutzler, A. et al. Large-Area Layer Counting of Two-Dimensional Materials Evaluating the Wavelength Shift in Visible-Reflectance Spectroscopy. The Journal of Physical Chemistry C (2019).
Luo, W.; Zafeiratos, S. Graphene-Coated ZnO and SiO2 as Supports for CoO Nanoparticles with Enhanced Reducibility.
ChemPhysChem17, 3055-3061 (2016). DOI:
10.1002/cphc.201600499xu, W.; Xie, L.; Ying, Y. Active Transparent Terahertz Absorber for Sensing and Radiation Warming.
SSRN (2023). DOI:
10.2139/ssrn.4462405Bao, Y.; Wang, H.; Jia, F.; Wang, B.; Shen, K.; Xie, L.; et al. Transparent terahertz planar platform for radiation warming and CRISPR-assisted label-free sensing.
SSRN (2026). DOI:
10.2139/ssrn.6631398Carmichael, C. P.; Smith, M. S.; Weeks, A. R.; Malocha, D. C. Experimental investigation of surface acoustic wave acoustoelectric effect using a graphene film on lithium niobate.
IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control65, 2205-2207 (2018). DOI:
10.1109/tuffc.2018.2870042Horvath, C. Fabrication and Characterization of Edge-Conformed Graphene-Silicon Waveguides.
IEEE Photonics Technology Letters27, 585–587 (2015). DOI:
10.1109/lpt.2014.2385757Li, C. et al. Insensitivity to Humidity in Fabry–Perot Sensor With Multilayer Graphene Diaphragm. IEEE Photonics Technology Letters 30, no.6 (2018).
Dong, N.; Wang, S.; Jiang, L.; Jiang, Y.; Wang, P.; Zhang, L. Pressure and temperature sensor based on graphene diaphragm and fiber Bragg gratings.
IEEE Photonics Technology Letters30, 431-434 (2018). DOI:
10.1109/lpt.2017.2786292Hu, J. et al. Improvement of the electrical contact resistance at rough interfaces using two dimensional materials.
Journal of Applied Physics118, 215301 (2015). DOI:
10.1063/1.4936366Nashed, R. et al. Ultra-High Mobility in Dielectrically Pinned CVD Graphene.
IEEE Journal of the Electron Devices Society4, 466–472 (2016). DOI:
10.1109/jeds.2016.2595498Lee, F.; Tripathi, M.; Lynch, P.; Dalton, A. B. Configurational effects on strain and doping at graphene-silver nanowire interfaces.
Applied Sciences10, 5157 (2020). DOI:
10.3390/app10155157Abas, A. F.; Lau, K. Y.; Abdulkawi, W. M.; Alresheedi, M. T. Dispersion management and pulse characterization of graphene-based soliton mode-locked fiber lasers. Applied Sciences12, 3288 (2022).
Warren, A. J.; Crawshaw, A. D.; Trincao, J.; Aller, P.; Alcock, S.; Nistea, I.; et al. In vacuo X-ray data collection from graphene-wrapped protein crystals.
Acta Crystallographica Section D Biological Crystallography71, 2079-2088 (2079). DOI:
10.1107/s1399004715014194Eguchi, R.; Hashimoto, A. Quantitative Analysis of Defective Graphene Induced by Electron Irradiation via Persistent Homology.
Microscopy and Microanalysis 31(Supplement_1) (2025). DOI:
10.1093/mam/ozaf048.822Hui, F. et al. Mechanical properties of locally oxidized graphene electrodes.
Archive of Applied Mechanics85, 339–345 (2014). DOI:
10.1007/s00419-014-0957-4Watanabe, H. et al. Layer number dependence of carrier lifetime in graphenes observed using time-Resolved mid-Infrared luminescence.
Chemical Physics Letters637, 58–62 (2015). DOI:
10.1016/j.cplett.2015.07.046Wu, M. et al. Wavelength switchable graphene Q-Switched fiber laser with cascaded fiber Bragg gratings.
Optics Communications368, 81–85 (2016). DOI:
10.1016/j.optcom.2016.01.069Luo, W.; Mélart, C.; Rach, A.; Sutter, C.; Zafeiratos, S. Interaction of bimetallic PtCo layers with bare and graphene-covered ZnO (0001) supports.
Surface Science669, 64-70 (2018). DOI:
10.1016/j.susc.2017.11.001Liu, D.; Wei, S.; Liu, C.; Wang, D. The study on the high-temperature performances of a graphene MEMS pressure sensor.
Journal of Materials Science: Materials in Electronics34 (2023). DOI:
10.1007/s10854-023-10211-5Li, C.; Gao, X.; Guo, T.; Xiao, J.; Fan, S.; Jin, W. Analyzing the applicability of miniature ultra-high sensitivity Fabry-Perot acoustic sensor using a nanothick graphene diaphragm.
Measurement Science and Technology26, 085101 (2015). DOI:
10.1088/0957-0233/26/8/085101Li, C.; Peng, X.; Liu, Q.; Gan, X.; Lv, R.; Fan, S. Nondestructive and in situ determination of graphene layers using optical fiber Fabry-Perot interference.
Measurement Science and Technology28, 025206 (2017). DOI:
10.1088/1361-6501/aa54f8Li, C. et al. Measurement of thermal expansion coefficient of graphene diaphragm using optical fiber Fabry–Perot interference.
Measurement Science and Technology27, 075102 (2016). DOI:
10.1088/0957-0233/27/7/075102Zheng, H. et al. Ultrafine Pt nanoparticle induced doping/Strain of single layer graphene: experimental corroboration between conduction and Raman characteristics.
Journal of Materials Science: Materials in Electronics26, 4746–4753 (2015). DOI:
10.1007/s10854-015-3043-yMorrow, W. K. et al. Role of graphene interlayers in mitigating degradation of Ni/Au ohmic contact morphology on p-Type GaN.
Vacuum128, 34–38 (2016). DOI:
10.1016/j.vacuum.2016.03.004Zhou, R. et al. Large-Energy, narrow-Bandwidth laser pulse at 1645 nm in a diode-Pumped Er:YAG solid-State laser passively Q-Switched by a monolayer graphene saturable absorber.
Applied Optics53, 254 (2014). DOI:
10.1364/ao.53.000254Li, C.; Xiao, J.; Guo, T.; Fan, S.; Jin, W. Interference characteristics in a Fabry-Perot cavity with graphene membrane for optical fiber pressure sensors. Microsystem technologies (2015).
Longchamp, J.-N. et al. Ultraclean freestanding graphene by platinum-Metal catalysis.
Journal of Vacuum Science & Technology B31, 020605 (2013). DOI:
10.1116/1.4793746Liu, S. et al. Atomic emission spectroscopy of electrically triggered exploding nanoparticle analytes on graphene/SiO2/Si substrate.
Journal of Vacuum Science & Technology B34. DOI:
10.1116/1.4964819Hussain, M. et al. The improved piezoelectric properties of ZnO nanorods with oxygen plasma treatment on the single layer graphene coated polymer substrate.
Physica status solidi (a)211, 455–459 (2014). DOI:
10.1002/pssa.201300330Huczko, A. et al. Efficient one-Pot combustion synthesis of few-Layered graphene.
Physica status solidi (b)252, 2412–2417 (2015). DOI:
10.1002/pssb.201552233Fujimoto, A. et al. Disorder and Weak Localization near Charge Neutral Point in Ti-cleaned Single-Layer Graphene. physica status solidi (b) (2019).
Littmann, M.; Reuter, D.; As, D. J. Remote Epitaxy of Cubic Gallium Nitride on Graphene-Covered 3C-SiC Substrates by Plasma-Assisted Molecular Beam Epitaxy.
physica status solidi (b)260 (2023). DOI:
10.1002/pssb.202300034Tsao, Y.-H.; Lee, K.-C.; Chuang, Y.-H.; Chang, G.-E.; Cheng, H. H.; Sun, G.; et al. High-performance, broadband Si photodiode by integrating graphene.
AIP Advances15 (2025). DOI:
10.1063/5.0284896Kuru, C. et al. Enhanced Power Conversion Efficiency of Graphene/Silicon Heterojunction Solar Cells Through NiO Induced Doping.
Journal of Nanoscience and Nanotechnology16, 1190–1193 (2016). DOI:
10.1166/jnn.2016.12079