testimonials.bib

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@Article{C9CP00203K,
  author    = {McCluskey, Andrew R. and Sanchez-Fernandez, Adrian and Edler, Karen J. and Parker, Stephen C. and Jackson, Andrew J. and Campbell, Richard A. and Arnold, Thomas},
  title     = {Bayesian determination of the effect of a deep eutectic solvent on the structure of lipid monolayers},
  journal   = {Phys. Chem. Chem. Phys.},
  year      = {2019},
  volume    = {21},
  pages     = {6133-6141},
  abstract  = {In this work{,} we present the first example of the self-assembly of phospholipid monolayers at the interface between air and an ionic solvent. Deep eutectic solvents are a novel class of environmentally friendly{,} non-aqueous{,} room temperature liquids with tunable properties{,} that have wide-ranging potential applications and are capable of promoting the self-assembly of surfactant molecules. We use a chemically-consistent Bayesian modelling of X-ray and neutron reflectometry measurements to show that these monolayers broadly behave as they do on water. This method allows for the monolayer structure to be determined{,} alongside the molecular volumes of the individual monolayer components{,} without the need for water-specific constraints to be introduced. Furthermore{,} using this method we are able to better understand the correlations present between parameters in the analytical model. This example of a non-aqueous phospholipid monolayer has important implications for the potential uses of these solvents and for our understanding of how biomolecules behave in the absence of water.},
  doi       = {10.1039/C9CP00203K},
  issue     = {11},
  publisher = {The Royal Society of Chemistry},
}

@Article{McCluskey2019,
  author   = {{McCluskey}, Andrew R. and {Grant}, James and {Smith}, Andrew J. and {Rawle}, Jonathan L. and {Barlow}, David J. and {Lawrence}, M. Jayne and {Parker}, Stephen C. and {Edler}, Karen J.},
  title    = {{Assessing molecular simulation for the analysis of lipid monolayer reflectometry}},
  journal  = {Journal of Physics Communications},
  year     = {2019},
  volume   = {3},
  pages    = {075001},
  month    = Jan,
  doi      = {10.1088/2399-6528/ab12a9},
  keywords = {Condensed Matter - Soft Condensed Matter},
}

@Article{Nelson2019,
  author   = {Andrew R. J. Nelson and Stuart W. Prescott},
  title    = {refnx: neutron and X-ray reflectometry analysis in Python},
  journal  = {Journal of Applied Crystallography},
  year     = {2019},
  volume   = {52},
  number   = {1},
  pages    = {193-200},
  month    = feb,
  abstract = {refnx is a model-based neutron and X-ray reflectometry data analysis package written in Python. It is cross platform and has been tested on Linux, macOS and Windows. Its graphical user interface is browser based, through a Jupyter notebook. Model construction is modular, being composed from a series of components that each describe a subset of the interface, parameterized in terms of physically relevant parameters (volume fraction of a polymer, lipid area per molecule etc.). The model and data are used to create an objective, which is used to calculate the residuals, log-likelihood and log-prior probabilities of the system. Objectives are combined to perform co-refinement of multiple data sets and mixed-area models. Prior knowledge of parameter values is encoded as probability distribution functions or bounds on all parameters in the system. Additional prior probability terms can be defined for sets of components, over and above those available from the parameters alone. Algebraic parameter constraints are available. The softwares offers a choice of fitting approaches, including least-squares (global and gradient-based optimizers) and a Bayesian approach using a Markov-chain Monte Carlo algorithm to investigate the posterior distribution of the model parameters. The Bayesian approach is useful for examining parameter covariances, model selection and variability in the resulting scattering length density profiles. The package is designed to facilitate reproducible research; its use in Jupyter notebooks, and subsequent distribution of those notebooks as supporting information, permits straightforward reproduction of analyses.},
  doi      = {10.1107/S1600576718017296},
}

@Article{Johnson2019,
  author  = {E. Johnson and T. Murdoch and I. Gresham and B. Humphreys and S. W. Prescott and A. Nelson and G. B. Webber and E. Wanless},
  title   = {Temperature dependent specific ion effects in mixed salt environments on a thermoresponsive poly(oligoethylene glycol methacrylate) brush},
  journal = {Physical Chemistry Chemical Physics},
  year    = {2019},
  volume  = {21},
  pages   = {4650 - 4662},
  doi     = {10.1039/C8CP06644B},
}

@Article{Appel2019,
  author   = {Christian Appel and Björn Kuttich and Lukas Stühn and Robert W. Stark and Bernd Stühn},
  title    = {Structural Properties and Magnetic Ordering in 2D Polymer Nanocomposites: Existence of Long Magnetic Dipolar Chains in Zero Field},
  journal  = {Langmuir},
  year     = {2019},
  volume   = {35},
  pages    = {13180 - 12191},
  abstract = {The existence of magnetic dipolar nanoparticle chains at zero field has been predicted theoretically for decades, but these structures are rarely observed  experimentally. A prerequisite is a permanent magnetic moment on the particles forming the chain. Here we report on the observation of magnetic dipolar chains of spherical iron oxide nanoparticles with a diameter of 12.8 nm. The nanoparticles are embedded in an ultrathin polymer film. Due to the high viscosity of the polymer matrix, the dominating aggregation mechanism is driven by dipolar interactions. Smaller iron oxide nanoparticles (8 nm) show no permanent magnetic moment and do not form chains but compact aggregates. Mixed monolayers of iron oxide nanoparticles and polymer at the air−water interface are characterized by Langmuir isotherms and in situ X-ray reflectometry (XRR). The combination of the particles with a polymer leads to a stable polymer nanocomposite film at the air−water interface. XRR experiments show that nanoparticles are immersed in a thin polymer matrix of 2 nm. Using atomic force microscopy (AFM) on Langmuir−Blodgett films, we measure the lateral distribution of particles in the film. An analysis  of single structures within transferred films results in fractal dimensions that are in excellent agreement with 2D simulations.},
  doi      = {10.1021/acs.langmuir.9b02094},
}

@misc{mccluskey2019using,
    title={Using Bayesian model selection to advise neutron reflectometry analysis from Langmuir-Blodgett monolayers},
    author={Andrew R. McCluskey and Thomas Arnold and Joshaniel F. K. Cooper and Tim Snow},
    year={2019},
    eprint={1910.10581},
    archivePrefix={arXiv},
    primaryClass={cond-mat.soft}
}

@article{Pospelov:ge5067,
author = "Pospelov, Gennady and Van Herck, Walter and Burle, Jan and Carmona Loaiza, Juan M. and Durniak, C{\'{e}}line and Fisher, Jonathan M. and Ganeva, Marina and Yurov, Dmitry and Wuttke, Joachim",
title = "{{\it BornAgain}: software for simulating and fitting grazing-incidence small-angle scattering}",
journal = "Journal of Applied Crystallography",
year = "2020",
volume = "53",
number = "1",
pages = "262--276",
month = "Feb",
doi = {10.1107/S1600576719016789},
abstract = {{\it BornAgain} is a free and open-source multi-platform software framework for simulating and fitting X-ray and neutron reflectometry, off-specular scattering, and grazing-incidence small-angle scattering (GISAS). This paper concentrates on GISAS. Support for reflectometry and off-specular scattering has been added more recently, is still under intense development and will be described in a later publication. {\it BornAgain} supports neutron polarization and magnetic scattering. Users can define sample and instrument models through Python scripting. A large subset of the functionality is also available through a graphical user interface. This paper describes the software in terms of the realized non-functional and functional requirements. The web site https://www.bornagainproject.org/ provides further documentation.},
keywords = {grazing-incidence small-angle scattering (GISAS), X-ray scattering, neutron scattering, simulation, software},
}

@article{freychet2020morphology,
  title={Morphology of poly (lactide)-block-poly (dimethylsiloxane)-block-polylactide high-$\chi$ triblock copolymer film studied by grazing incidence small-angle X-ray scattering},
  author={Freychet, Guillaume and Maret, Mireille and Fernandez-Regulez, Marta and Tiron, Raluca and Gharbi, Ahmed and Nicolet, Celia and Gergaud, Patrice},
  journal={Journal of Polymer Science},
  volume={58},
  number={15},
  pages={2041--2050},
  year={2020},
  doi="10.1002/pol.20200196",
  publisher={Wiley Online Library}
}

@article{refId0,
	author = {{Gerelli, Yuri}},
	title = {Applications of neutron reflectometry in biology},
	doi={10.1051/epjconf/202023604002},
	journal = {EPJ Web Conf.},
	year = 2020,
	volume = 236,
	pages = "04002",
}

@article{McCluskey_2020,
	doi = {10.1088/2632-2153/ab94c4},
	year = 2020,
	month = {jul},
	publisher = {{IOP} Publishing},
	volume = {1},
	number = {3},
	pages = {035002},
	author = {Andrew R McCluskey and Joshaniel F K Cooper and Tom Arnold and Tim Snow},
	title = {A general approach to maximise information density in neutron reflectometry analysis},
	journal = {Machine Learning: Science and Technology},
	abstract = {Neutron and x-ray reflectometry are powerful techniques facilitating the study of the structure of interfacial materials. The analysis of these techniques is ill-posed in nature requiring the application of model-dependent methods. This can lead to the over- and under- analysis of experimental data when too many or too few parameters are allowed to vary in the model. In this work, we outline a robust and generic framework for the determination of the set of free parameters that are capable of maximising the information density of the model. This framework involves the determination of the Bayesian evidence for each permutation of free parameters; and is applied to a simple phospholipid monolayer. We believe this framework should become an important component in reflectometry data analysis and hope others more regularly consider the relative evidence for their analytical models.}
}

@MastersThesis{simonne2019diffraction,
  title={Diffraction investigation of the Half-Heusler to Full-Heusler transition in Ni2-xMnSb},
  url = {http://dsimonne.eu/Documents/MasterThesisSimonne.pdf},
  author={Simonne, David},
  year={2019},
  school={Technical University of Munich},
}

@article{johnson2020enrichment,
  doi = {10.1021/acs.langmuir.0c01502},
  title = {Enrichment of Charged Monomers Explains Non-monotonic Polymer Volume Fraction Profiles of Multi-stimulus Responsive Copolymer Brushes},
  author = {Johnson, Edwin C and Willott, Joshua D and Gresham, Isaac J and Murdoch, Timothy J and Humphreys, Ben A and Prescott, Stuart W and Nelson, Andrew and de Vos, Wiebe M and Webber, Grant B and Wanless, Erica J},
  journal = {Langmuir},
  year = {2020},
  publisher = {ACS Publications}
}

@article{andersson2020solid,
  doi = {10.1016/j.ymeth.2020.09.005},
  title = {Solid-supported lipid bilayers--A versatile tool for the structural and functional characterization of membrane proteins},
  author = {Andersson, Jakob and Bilotto, Pierluigi and Mears, Laura LE and Fossati, Stefan and Ramach, Ulrich and K{\"o}per, Ingo and Valtiner, Markus and Knoll, Wolfgang},
  journal = {Methods},
  volume = {180},
  pages = {56--68},
  year = {2020},
  publisher = {Elsevier}
}

@misc{carmona2020towards,
  title={Towards Reflectivity profile inversion through Artificial Neural Networks},
  author={Carmona-Loaiza, Juan Manuel},
  eprint={2010.07634},
  archivePrefix={arXiv},
  year={2020},
  primaryClass={cond-mat.soft}
}

@Article{Robertson2020,
  author  = {Hayden Robertson and Edwin C. Johnson and Isaac J. Gresham and Stuart W. Prescott and Andrew Nelson and Erica J. Wanless and Grant B. Webber},
  title   = {Competitive specific ion effects in mixed salt solutions on a thermoresponsive polymer brush},
  journal = {Journal of Colloid and Interface Science},
  year    = {2020},
  doi     = {10.1016/j.jcis.2020.10.092},
}

@article{gresham2020structure,
  title={Structure and Hydration of Asymmetric Polyelectrolyte Multilayers as Studied by Neutron Reflectometry: Connecting Multilayer Structure to Superior Membrane Performance},
  author={Gresham, Isaac J and Reurink, Dennis M and Prescott, Stuart W and Nelson, Andrew RJ and de Vos, Wiebe M and Willott, Joshua D},
  journal={Macromolecules},
  year={2020},
  publisher={ACS Publications},
  doi = {10.1021/acs.macromol.0c01909},
}

@article{cheema2020insect,
  title={Insect Odorant Receptor Nanodiscs for Sensitive and Specific Electrochemical Detection of Odorant Compounds},
  author={Cheema, Jamal Ahmed and Aydemir, Nihan and Carraher, Colm and Khadka, Roshan and Colbert, Damon and Lin, Harris T and Nelson, Andrew and Kralicek, Andrew and Travas-Sejdic, Jadranka},
  journal={Sensors and Actuators B: Chemical},
  pages={129243},
  year={2020},
  publisher={Elsevier},
  doi={10.1016/j.snb.2020.129243},
}

@article{boyd2020comparison,
  title={A comparison between the structures of reconstituted salivary pellicles and oral mucin (MUC5B) films},
  author={Boyd, Hannah and Gonzalez-Martinez, Juan F and Welbourn, Rebecca JL and Gutfreund, Philipp and Klechikov, Alexey and Robertsson, Carolina and Wickstr{\"o}m, Claes and Arnebrant, Thomas and Barker, Robert and Sotres, Javier},
  journal={Journal of Colloid and Interface Science},
  year={2021},
  publisher={Elsevier},
  volume = {584},
  pages = {660--668},
  doi = {10.1016/j.jcis.2020.10.124},
}

@article{aoki2020neutron,
  title={Neutron Reflectometry Tomography for Imaging and Depth Structure Analysis of Thin Films with In-Plane Inhomogeneity},
  author={Aoki, Hiroyuki and Ogawa, Hiroki and Takenaka, Mikihito},
  journal={Langmuir},
  year={2020},
  publisher={ACS Publications},
  doi={10.1021/acs.langmuir.0c02744},
}


@article{johnson214direction,
  title={The direction of influence of specific ion effects on a pH and temperature responsive copolymer brush is dependent on polymer charge},
  author={Johnson, Edwin C and Gresham, Isaac J and Prescott, Stuart W and Nelson, Andrew and Wanless, Erica J and Webber, Grant B},
  journal={Polymer},
  volume={214},
  pages={123287},
  year={2021},
  publisher={Elsevier},
  doi={10.1016/j.polymer.2020.123287},
}

@misc{henning2021aluminum,
  title={Aluminum Oxide at the Monolayer Limit via Oxidant-free Plasma-Assisted Atomic Layer Deposition on GaN},
  author={Henning, Alex and Bartl, Johannes D and Zeidler, Andreas and Qian, Simon and Bienek, Oliver and Jiang, Chang-Ming and Paulus, Claudia and Rieger, Bernhard and Stutzmann, Martin and Sharp, Ian D},
  eprint={2102.03642},
  archivePrefix={arXiv},
  year={2021},
}

@article{gresham2021geometrical,
  title={Geometrical Confinement Modulates the Thermoresponse of a Poly (N-isopropylacrylamide) Brush},
  author={Gresham, Isaac J and Humphreys, Ben A and Willott, Joshua D and Johnson, Edwin C and Murdoch, Timothy J and Webber, Grant B and Wanless, Erica J and Nelson, Andrew RJ and Prescott, Stuart W},
  journal={Macromolecules},
  year={2021},
  publisher={ACS Publications},
  doi={10.1021/acs.macromol.0c02775},
}

@misc{durant2021determining,
  title={Determining the maximum information gain and optimising experimental design in neutron reflectometry using the Fisher information},
  author={Durant, James H and Wilkins, Lucas and Butler, Keith and Cooper, Joshaniel FK},
  archivePrefix={arXiv},
  eprint={2103.08973},
  year={2021},
}

@article{Gresham:vg5136,
author = {Gresham, Isaac J. and Murdoch, Timothy J. and Johnson, Edwin C. and Robertson, Hayden and Webber, Grant B. and Wanless, Erica J. and Prescott, Stuart W. and Nelson, Andrew R. J.},
title = {Quantifying the robustness of the neutron reflectometry technique for structural characterization of polymer brushes},
journal = {Journal of Applied Crystallography},
year = {2021},
volume = {54},
number = {3},
doi = {10.1107/S160057672100251X},
url = {https://doi.org/10.1107/S160057672100251X},
abstract = {Neutron reflectometry is the foremost technique for {\it in situ} determination of the volume fraction profiles of polymer brushes at planar interfaces. However, the subtle features in the reflectometry data produced by these diffuse interfaces challenge data interpretation. Historically, data analyses have used least-squares approaches that do not adequately quantify the uncertainty of the modeled profile and ignore the possibility of other structures that also match the collected data (multimodality). Here, a Bayesian statistical approach is used that permits the structural uncertainty and multimodality to be quantified for polymer brush systems. A free-form model is used to describe the volume fraction profile, minimizing assumptions regarding brush structure, while only allowing physically reasonable profiles to be produced. The model allows the total volume of polymer and the profile monotonicity to be constrained. The rigor of the approach is demonstrated via a round-trip analysis of a simulated system, before it is applied to real data examining the well characterized collapse of a thermoresponsive brush. It is shown that, while failure to constrain the interfacial volume and consider multimodality may result in erroneous structures being derived, carefully constraining the model allows for robust determination of polymer brush compositional profiles. This work highlights that an appropriate combination of flexibility and constraint must be used with polymer brush systems to ensure the veracity of the analysis. The code used in this analysis is provided, enabling the reproduction of the results and the application of the method to similar problems.},
keywords = {structural characterization, Markov-chain Monte Carlo, uncertainty, diffuse interfaces, multimodality},
}

@article{ronneburg2021solid,
  title={Solid Electrolyte Interphase Layer Formation during Lithiation of Single-Crystal Silicon Electrodes with a Protective Aluminum Oxide Coating},
  author={Ronneburg, Arne and Silvi, Luca and Cooper, Joshaniel and Harbauer, Karsten and Ballauff, Matthias and Risse, Sebastian},
  journal={ACS Applied Materials \& Interfaces},
  year={2021},
  doi = {10.1021/acsami.1c01725},
  publisher={ACS Publications},
}

@article{mironov2021towards,
  title={Towards automated analysis for neutron reflectivity},
  author={Mironov, Daniil and Durant, James H and Mackenzie, Rebecca and Cooper, Joshaniel FK},
  journal={Machine Learning: Science and Technology},
  volume={2},
  number={3},
  pages={035006},
  year={2021},
  doi={10.1088/2632-2153/abe7b5},
  publisher={IOP Publishing}
}

@article{esashi2021influence,
  title={Influence of surface and interface roughness on X-ray and extreme ultraviolet reflectance: A comparative numerical study},
  author={Esashi, Yuka and Tanksalvala, Michael and Zhang, Zhe and Jenkins, Nicholas W and Kapteyn, Henry C and Murnane, Margaret M},
  journal={OSA Continuum},
  volume={4},
  number={5},
  pages={1497--1518},
  year={2021},
  publisher={Optical Society of America}
}

@article{doucet2021machine,
  title={Machine learning for neutron reflectometry data analysis of two-layer thin films},
  author={Doucet, Mathieu and Archibald, Richard K and Heller, William T},
  journal={Machine Learning: Science and Technology},
  volume={2},
  number={3},
  pages={035001},
  year={2021},
  publisher={IOP Publishing}
}

@article{kihara2021cellular,
  title={Cellular interactions with polystyrene nanoplastics—The role of particle size and protein corona},
  author={Kihara, Shinji and Ashenden, Alexander and Kaur, Manmeet and Glasson, Judith and Ghosh, Sunandita and van der Heijden, Nadine and Brooks, Anna ES and Mata, Jitendra P and Holt, Stephen and Domigan, Laura J and others},
  journal={Biointerphases},
  volume={16},
  number={4},
  pages={041001},
  year={2021},
  doi={10.1116/6.0001124},
  publisher={American Vacuum Society}
}

@article{boyd2021effect,
  title={Effect of nonionic and amphoteric surfactants on salivary pellicles reconstituted in vitro},
  author={Boyd, Hannah and Gonzalez-Martinez, Juan F and Welbourn, Rebecca JL and Ma, Kun and Li, Peixun and Gutfreund, Philipp and Klechikov, Alexey and Arnebrant, Thomas and Barker, Robert and Sotres, Javier},
  journal={Scientific Reports},
  volume={11},
  number={1},
  pages={1--12},
  year={2021},
  doi={10.1038/s41598-021-92505-4},
  publisher={Nature Publishing Group}
}

@article{bialaslight,
  title={Light-Gated Control of Conformational Changes in Polymer Brushes},
  author={Bialas, Sabrina and Krappitz, Tim and Walden, Sarah L and Kalayci, Kubra and Kodura, Daniel and Frisch, Hendrik and MacLeod, Jennifer M and Nelson, Andrew and Michalek, Lukas and Barner-Kowollik, Christopher},
  journal={Advanced Materials Technologies},
  pages={2100347},
  year={2021},
  doi={10.1002/admt.202100347},
  publisher={Wiley Online Library}
}

@article{köhler2021nanostructural,
  title={Nanostructural Characterization of Cardiolipin-Containing Tethered Lipid Bilayers Adsorbed on Gold and Silicon Substrates for Protein Incorporation},
  author={Köhler, Sebastian and Fragneto, Giovanna and Alcaraz, Jean-Pierre and Nelson, Andrew and Martin, Donald K and Maccarini, Marco},
  journal={Langmuir},
  year={2021},
  doi={10.1021/acs.langmuir.1c00119},
  publisher={ACS Publications}
}

@article{andersson2021increasing,
  title={Increasing Antibiotic Susceptibility: The Use of Cationic Gold Nanoparticles in Gram-Negative Bacterial Membrane Models},
  author={Andersson, Jakob and Fuller, Melanie and Ashenden, Alex and Holt, Stephen A and Köper, Ingo},
  journal={Langmuir},
  year={2021},
  doi={10.1021/acs.langmuir.1c01150},
  publisher={ACS Publications}
}

@misc{durant2021optimising,
  title={Optimising experimental design in neutron reflectometry},
  author={Durant, James H and Wilkins, Lucas and Cooper, Joshaniel FK},
  archivePrefix={arXiv},
  eprint={2108.05605},
  year={2021}
}

@article{gao2021effect,
  title={Effect of dendrimer surface groups on the properties of phosphorescent emissive films},
  author={Gao, Mile and Jang, Junhyuk and Mai, Van TN and Ranasinghe, Chandana Sampath Kumara and Chu, Ronan and Burn, Paul L and Gentle, Ian R and Pivrikas, Almantas and Shaw, Paul E},
  journal={Organic Electronics},
  pages={106321},
  year={2021},
  doi={10.1016/j.orgel.2021.106321},
  publisher={Elsevier}
}

@phdthesis{mothander2021grazing,
  title={Grazing incidence small angle neutron scattering as a tool to study curved biomembranes on nanostructured surfaces},
  author={Mothander, Karolina},
  year={2021},
  keywords = "GISANS, Reflectometry, Neutron scattering, Phospholipid, supported lipid bilayer, Nanowires, confocal microscopy, QCM-D",
  isbn = "978-91-7422-830-4",
  school={Lund University}
}

@article{gao2021effect2,
  title={Effect of host generation on the luminescent and charge transporting properties of solution processed OLEDs},
  author={Gao, Mile and Jang, Junhyuk and Leitner, Tanja and Mai, Van TN and Ranasinghe, Chandana SK and Chu, Ronan and Burn, Paul L and Pivrikas, Almantas and Shaw, Paul E},
  journal={Advanced Materials Interfaces},
  pages={2100820},
  year={2021},
  doi={10.1002/admi.202100820},
  publisher={Wiley Online Library}
}

@article{hong2021distributions,
  title={Distributions of Deuterated Polystyrene Chains in Perforated Layers of Blend Films of a Symmetric Polystyrene-block-poly (methyl methacrylate)},
  author={Hong, Jia-Wen and Jian, Yi-Qing and Liao, Yin-Ping and Hung, Hsiang-Ho and Huang, Tzu-Yen and Nelson, Andrew and Tsao, I-Yu and Wu, Chun-Ming and Sun, Ya-Sen},
  journal={Langmuir},
  year={2021},
  doi={10.1021/acs.langmuir.1c02132},
  publisher={ACS Publications}
}

@article{bartl2021modular,
  title={Modular Assembly of Vibrationally and Electronically Coupled Rhenium Bipyridine Carbonyl Complexes on Silicon},
  author={Bartl, Johannes D and Thomas, Christopher and Henning, Alex and Ober, Martina F and Savasci, Gökcen and Yazdanshenas, Bahar and Deimel, Peter S and Magnano, Elena and Bondino, Federica and Zeller, Patrick and others},
  journal={Journal of the American Chemical Society},
  year={2021},
  doi={10.1021/jacs.1c09061},
  publisher={ACS Publications}
}

@article{gao2021effect3,
  title={Effect of dendron structure on the luminescent and charge transporting properties of solution processed dendrimer-based OLEDs},
  author={Gao, Mile and Mai, Van TN and Jang, Junhyuk and Ranasinghe, Chandana Sampath Kumara and Chu, Ronan and Burn, Paul L and Gentle, Ian R and Pivrikas, Almantas and Shaw, Paul E},
  journal={Journal of Materials Chemistry C},
  year={2021},
  doi={10.1039/D1TC03949K},
  publisher={Royal Society of Chemistry}
}

@article{ikami2021multilayered,
  title={Multilayered Lamellar Materials and Thin Films by Instant Self-Assembly of Amphiphilic Random Copolymers},
  author={Ikami, Takaya and Watanabe, Yuki and Ogawa, Hiroki and Takenaka, Mikihito and Yamada, Norifumi L and Ouchi, Makoto and Aoki, Hiroyuki and Terashima, Takaya},
  journal={ACS Macro Letters},
  volume={10},
  pages={1524--1528},
  year={2021},
  doi={10.1021/acsmacrolett.1c00571},
  publisher={ACS Publications}
}

@article{aoki2021deep,
  title={Deep learning approach for an interface structure analysis with a large statistical noise in neutron reflectometry},
  author={Aoki, Hiroyuki and Liu, Yuwei and Yamashita, Takashi},
  journal={Scientific Reports},
  volume={11},
  number={1},
  pages={1--9},
  year={2021},
  doi={10.1038/s41598-021-02085-6},
  publisher={Nature Publishing Group}
}

@article{saadeh2021time,
  title={Time-frequency analysis assisted determination of ruthenium optical constants in the sub-EUV spectral range 8 nm--23.75 nm},
  author={Saadeh, Qais and Naujok, Philipp and Philipsen, Vicky and H{\"o}nicke, Philipp and Laubis, Christian and Buchholz, Christian and Andrle, Anna and Stadelhoff, Christian and Mentzel, Heiko and Sch{\"o}nstedt, Anja and others},
  journal={Optics Express},
  volume={29},
  number={25},
  pages={40993--41013},
  year={2021},
  doi={10.1364/OE.426029},
  publisher={Optical Society of America}
}

@incollection{holt2022using,
  title={Using refnx to Model Neutron Reflectometry Data from Phospholipid Bilayers},
  author={Holt, Stephen A and Oliver, Tara E and Nelson, Andrew RJ},
  booktitle={Membrane Lipids},
  pages={179--197},
  year={2022},
  doi={10.1007/978-1-0716-1843-1_15},
  publisher={Springer}
}

@article{ferrie2021sliding,
  title={Sliding Silicon-based Schottky diodes: Maximizing Triboelectricity with Surface Chemistry},
  author={Ferrie, Stuart and Le Brun, Anton P and Krishnan, Gowri and Anderson, Gunther and Darwish, Nadim and Ciampi, Simone},
  journal={Nano Energy},
  pages={106861},
  year={2021},
  doi={10.1016/j.nanoen.2021.106861},
  publisher={Elsevier}
}

@article{mccoy2021spontaneous,
  title={Spontaneous surface adsorption of aqueous graphene oxide by synergy with surfactants},
  author={McCoy, Thomas Malcolm and Armstrong, Alexander J and Moore, Jackson E and Holt, Stephen and Tabor, Rico and Routh, Alexander},
  journal={Physical Chemistry Chemical Physics},
  year={2021},
  doi={10.1039/D1CP04317J},
  publisher={Royal Society of Chemistry}
}

@article{ferron2022characterization,
  title={Characterization of the Interfacial Orientation and Molecular Conformation in a Glass-Forming Organic Semiconductor},
  author={Ferron, Thomas J and Thelen, Jacob L and Bagchi, Kushal and Deng, Chuting and Gann, Eliot and de Pablo, Juan J and Ediger, MD and Sunday, Daniel F and DeLongchamp, Dean M},
  journal={ACS Applied Materials \& Interfaces},
  year={2022},
  doi={10.1021/acsami.1c19948},
  publisher={ACS Publications}
}

@article{gonzalez2022muc5b,
  title={MUC5B mucin films under mechanical confinement: a combined neutron reflectometry and atomic force microscopy study},
  author={Gonzalez-Martinez, Juan F and Boyd, Hannah and Gutfreund, Philipp and Welbourn, Rebecca JL and Robertsson, Carolina and Wickstr{\"o}m, Claes and Arnebrant, Thomas and Richardson, Robert M and Prescott, Stuart W and Barker, Robert and others},
  journal={Journal of Colloid and Interface Science},
  year={2022},
  doi={10.1016/j.jcis.2022.01.096},
  publisher={Elsevier}
}

@Comment{jabref-meta: databaseType:bibtex;}