https://orcid.org/0000-0002-5034-5328
References
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- Queiroz Do Amaral L. Changes in aggregate form, size and flexibility along phase sequences in lyotropic liquid crystals. Braz J Phys. 2002;32(2B):540–547.
- Thiele T, Berret J-F, Müller S, et al. Rheology and nuclear magnetic resonance measurements under shear of sodium dodecyl sulfate/decanol/water nematics. J Rheol. 2001;45:29–48.
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- Projects LNLS syncrotron: sAS 824/01, 1103/01, 1316/02 and D11A-SAS 2266/03.
- Riske KA, Amaral LQ, Lamy-Freund MT. Thermal transitions of DMPG bilayers in aqueous solution: sAXS structural studies. Biochim Biophys Acta. 2001;1511:297–308.
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- Spinozzi F, Amaral LQ. Pore model in the melting regime of a lyotropic biomembrane with an anionic phospholipid. Langmuir. 2016;32(50):13556–13565.
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- Pera H, Kleijn JM, Leermakers FAM. On the edge energy of lipid membranes and the thermodynamic stability of pores. J Chem Phys. 2015;142:034101–034114.
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- Wubsheta NH, Wub B, Veerapanenic S, et al. Differential regulation of GUV mechanics via actin network architectures. Biophys J. 2022 (in press). DOI:10.1016/j.bpj.2022.11.026
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- Ochoa C, Gao S, Srivastava S, et al. Foam film stratification studies probe intermicellar interactions. PNAS. 2021;118(25):e2024805118.
- Itri R, Amaral LQ, Mariani P. Structure of the hexagonal phase of the sodium dodecyl sulfate and water system. Phys Rev E. 1996;54:5211–5216.
- Oka T, Ohta N, Hyde ST. Polar–nonpolar interfaces of normal bicontinuous cubic phases in nonionic surfactant/water systems are parallel to the gyroid surface. Langmuir. 2020;36:8687–8694.
- Mariani P, Amaral LQ, Saturni L, et al. Hexagonal-cubic phase transitions in lipid containing systems: epitaxial relationships and cylinder growth. J Phys II. 1994;4:1393–1416. DOI:10.1051/jp2:1994206
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