M. Martincic and G. Tobias, Expert Opln. Drug Dellv, vol.12, pp.563-581, 2015.

C. J. Serpe11, K. Kostarelos, and B. G. Davis, ACS Cent Set, vol.2, pp.190-200, 2016.

J. Xjao, X. Pan, S. Guo, P. Ren, and X. Bao, J . Am. Chem. Soc, vol.137, pp.477-482, 2015.

R. H. Baughman, A. A. Zakhldov, and W. A. De-heer, Science, vol.297, pp.787-792, 2002.

M. V. Kharlamova, Prog. Mater. Set, vol.77, pp.12-211, 2016.

J. Xu, G. Sloan, S. Brown, V. C. Balley, . Wijjjams et al., Chem. Commun, pp.2427-2428, 2000.

M. Hart, J. Chen, A. Mlchaelldes, A. Sella, M. S. Shaffer et al., Angew. Chem. lnl Ed, vol.57, pp.11649-11653, 2018.

S. Van-bezouw, D. H. Arias, R. Wy, S. Camb-re, A. J. Ferguson et al., ACS Nano, vol.12, pp.6881-94, 2018.

G. Chlmowa, M. Sendova, E. Flahaut, D. Churochkln, and S. Bhattacharyya, J. Appl. Phys, vol.110, p.123708, 2011.

C. Lin, B. T. Chu, G. Tob-ias, S. Sahakalkan, S. Roth et al., Nanotechnology, vol.20, p.105703, 2009.

L. Cabana, M. Bourgognon, J. T. Wang, A. Prottl, R. Kllppsteln et al., Small, vol.12, pp.2893-2905, 2016.

J. S. Bendall, A. Ille, M. E. Welland, J. Sloan, and M. L. Green, J . Phys. Chem. B, vol.110, pp.6569-6573, 2006.

R. Ghunalm, D. Damm, A. Wolf, B. Lubk, M. Buchner et al., Nanomaterlals, vol.8, p.576, 2018.

P. V. Medeiros, J. M. Marks, A. Wynn, Q. M. Vasylenko, D. Ramasse et al., ACS Nano, vol.11, pp.6178-6185, 2017.

E. Flahaut, J. Sloan, S. Frledrlchs, A. I. Kirkland, K. S. Coleman et al., Chem. Mater, vol.18, pp.2059-2069, 2006.

M. Monthloux, E. Flahaut, and J. P. Cleuziou, J . Mater. Res, vol.21, pp.2774-2793, 2011.

A. Nie, B. Gallbert, E. Soula, J. Flahaut, M. Sloan et al., carbon, vol.110, pp.48-50, 2016.

S. C. Tsang, Y. K. Chen, P. J. Harris, and M. L. Green, Nature, vol.372, pp.159-162, 1994.

Y. K. Chen, A. Chu, J. Cook, M. L. Green, P. J. Hanis et al., J . Mater. Chem, vol.7, pp.54-549, 1997.

J. Sloan, G. Matthewman, C. Dyer-smith, A. Y. Sung, Z. Uu et al., ACS Nano, vol.2, pp.966-976, 2008.

E. Dujardln, T. W. Ebbesen, H. Hlura, K. Tan, and . Lgakl, Science, vol.265, pp.1850-1852, 1994.

J. Sloan, D. M. Wright, H. G. Woo, S. Balley, G. Brown et al., J .L. Hutch ison, M.LH. Green, Chem. Commun, pp.699-700, 1999.

Y. K. Chen, M. L. Green, and S. C. Tsang, Chem. Commun, pp.2489-2490, 1996.

M. Martincic, E. Pach, B. Ballesteros, and G. Tobias, Phys. Chem. Chem. Phys, vol.17, pp.31662-31669, 2015.

M. Klerkowlcz, J. M. Gonzalez-dominguez, E. Pach, S. Sandoval, B. Ballesteros et al., ACS Sustain. Chem. Eng, vol.5, pp.1-2508, 2017.

B. Ballesteros, G. Tob-ias, M. H. Ward, and M. L. Green, J . Phys. Chem. C, vol.113, pp.2653-2656, 2009.

G. Brown, S. R. Balley, M. Novotny, R. Carter, E. Flahaut et al., Appl. Phys. A, vol.76, pp.457-462, 2003.

L. Shao, G. Tobias, Y. Huh, and M. L. Green, Carbon, vol.44, pp.285-2858, 2006.

M. Martincic, S. Vranlc, E. Pach, S. Sandoval, B. Ballesteros et al., carbon, vol.141, pp.782-793, 2019.

V. Sanz, C. Tllmactu, B. Soula, E. Flahaut, H. M. Coley et al., Carbon, vol.49, pp.5348-5358, 2011.

P. Lukslrlkul, B. Ballesteros, G. Tobias, M. G. Moloney, and M. L. Green, Carbon, vol.48, pp.1912-1917, 2010.

L. Shao, T. W. Un, G. Tobias, and M. L. Green, Chem. Commun, pp.2164-2166, 2008.

J. Sloan, M. C. Novotny, S. R. Balley, G. Brown, C. Xu et al., Chem. Phys. Lett, vol.329, pp.61-65, 2000.

R. R. Meyer, J. Sloan, R. E. Dunln-borkowskl, A. I. Kirkland, M. C. Novotny et al., Science, vol.289, pp.1324-1326, 2000.

W. K. Hsu, W. Z. Li, Y. Q. Zhu, N. Grober, !. et al., Chem. Phys. Lett, vol.317, pp.77-82, 2000.

J. Sloan, A. Kirkland, J. L. Hutchison, and M. L. Green, Chem. Commun, vol.2, pp.1319-1332, 2002.

J. Sloan, G. Brown, S. R. Balley, K. S. Coleman, E. Flahaut et al., Mater. Res. Soc. Symp. Proc, vol.633, pp.4311-4316, 2001.

J. Sloan, S. J. Grosvenor, S. Frledrlchs, A. I. Kirkland, J. L. Hutchison et al., Angew. Chem. Jnt. Ed, vol.41, pp.1156-1159, 2002.

E. Philp, J. Sloan, A. I. Kirkland, R. R. Meyer, J. L. Friedrichs et al., Nat. Mater, vol.2, pp.788-795, 2003.

N. Kuganathan and J. C. Green, Chem. Commun, pp.2432-2434, 2008.

R. Carter, J. Sloan, A. I. Kirkland, R. R. Meyer, P. J. Llndan et al., Ph ys. Rev. Lett, vol.96, p.5501, 2006.

T. W. Chamberlain, J. Blsk-upek, G. A. Rance, A. Chuvtun, T. J. Alexander et al., ACS Nano, vol.6, pp.3-3953, 2012.

J. Zhang, Z. Zhu, Y. Feng, H. Lshlwata, Y. Miyata et al., Angew. Chem. lot. Ed, vol.52, pp.3717-3721, 2013.

J. Zhang, D. Zhao, D. Xjao, C. Ma, H. Ou et al., Angew. Chem. Jnt. Ed, vol.129, pp.1876-1880, 2017.

M. Hart, E. R. White, J. Chen, C. M. Mcgllvery, C. J. Pickard et al., Angew. Chem. Jnt. Ed, vol.56, pp.8144-8148, 2017.

M. Chorro, G. Kane, L. Alvarez, J. Cambedouzou, E. Palneau et al., Carbon, vol.52, pp.100-108, 2013.

N. Kuganathan and A. Chroneos, Jnorg. Chim. Acta, vol.488, pp.246-254, 2019.

E. L. Sceats, M. L. Green, A. I. Kirkland, and J. C. Green, Chem. Phys. Lett, vol.466, pp.76-78, 2008.

D. G. Calatayud, H. Ge, N. Kuganathan, R. M. Mlrabello, N. H. Jacobs et al., ChemlstryOpen, vol.7, pp.144-158, 2018.

N. A. Kiselev, R. M. Zakalyukln, O. M. Zhlgauna, N. Grober, !. et al., J . Mlcrosc, vol.232, pp.33-342, 2008.

A. S. Kumskov, V. G. Zhlgallna, A. Chuvtun, N. I. Verb-itskiy, and A. G. Ryabenko, Carbon, vol.50, pp.4696-4704, 2012.

A. A. Euseev, N. I. Verbltskly, A. A. Volykhov, A. V. Fedorov, O. Y. Vllkov et al., Carbon, vol.99, pp.619-623, 2016.

M. M. Brzhezlnskaya, R. Ptittner, A. S. Vlnogradov, M. V. Chemysheva, A. A. Ellseev et al., Fullerenes Nanotubes carbon Nanostruct, vol.18, pp.574-578, 2010.

A. V. Generalov, M. M. Brzhezlnskaya, A. S. Vlnogradov, R. Ptittner, M. V. Chemysheva et al., Phys. SoUd State, vol.53, pp.643-653, 2011.

A. A. Euseev, L. V. Yashln-a, N. I. Verbltskly, M. M. Brzhezlnskaya, M. V. Kharlamova et al., carbon, vol.50, pp.4021-4039, 2012.

M. V. Kharlamova, C. Kramberger, A. Domanov, K. Mlttelberger, T. Yanagi et al., J. Mater. Set, vol.53, pp.13018-13029, 2018.

L. Cabana, B. Ballesteros, E. Batista, R. Magen, ). Arena et al., Adv. Mater, vol.26, pp.2016-2021, 2014.

S. Sandoval, D. Keplt, A. Pino, E. Gyorgy, A. G6mez et al., ACS Nano, vol.12, pp.6648-6656, 2018.

S. Sandoval, E. Pach, B. Ballesteros, and G. Tobias, Carbon, vol.123, pp.129-134, 2017.

A. E. Ashokkumar, A. N. Enyashln, and F. L. Deepak, Set. Rep, vol.8, p.10133, 2018.

N. M. Batra, A. E. Ash-oklcumar, J. Smajlc, A. N. Enyashln, F. Deepak et al., J. Phys. Chem. C, vol.122, pp.24967-24991, 2018.

A. Ashok, L. Francis, and A. Enyashln, Capillary filling o f carbon nanotubes b y BICJ, : TEM and MD insight, Nanosystems: Phys. Chem. Math, pp.521-531, 2018.

A. A. Ellseev, N. S. Falaleev, N. Verbltskly, A. A. Volykhov, L. V. Yashlna et al., Nano Lett, vol.17, pp.805-810, 2017.

J. M. Wynn, P. V. Medeiros, A. Vasylenko, J. Sloan, D. Quigley et al., Phys. Rev. Mater, vol.1, p.73001, 2017.

J. Gonzalez, C. Power, E. Belandrla, J. M. Broto, P. Puech et al., Phys. Status SoUdl (b), vol.244, pp.136-141, 2006.

E. Belandrla, M. Miiiot, J. Broto, E. Flahaut, F. Rodriguez et al., carbon, vol.48, pp.2566-2572, 2010.

J. Gonzalez, C. Power, E. Belandria, J. Jorge, F. Gonzalez-jimenez et al., High Pressure Res, vol.28, pp.577-582, 2008.

E. Corro, J. Gonzalez, M. Taravlllo, E. Flahaut, and V. G. Baonza, Nano Lett, vol.8, pp.221-2218, 2008.

M. Sendova, E. Flahaut, and T. Hartsfield, J. Appl Phys, vol.108, p.44309, 2010.

T. Michel, J. Alvarez, R. Sauvajol, R. Almalrac, . Aznar et al., J . Phys. Chem. SoUds, vol.67, pp.1190-1192, 2006.

A. Zubalr, D. Tristan, !. , C. Nie, D. E. Tsentalovlch et al., Phys. Rev. Mater, vol.1, p.64002, 2017.

A. Nie, B. Gallbert, L. Soula, J. Datas, E. Sloan et al., IEEE Trans. Nanotechnol, vol.16, pp.759-766, 2017.

M. Tilmaciu, B. Soula, A. Gaubert, P. Lukanov, J. Datas et al., Chem. Commun, pp.6664-6666, 2009.

S. Datta, L. Marty, J. P. Cleuziou, C. Tllmadu, B. Soula et al., Phys. Rev. Lett, vol.107, p.186804, 2011.

S. Ncube, C. Coleman, A. Strydom, E. Flahaut, A. Sousa et al., Set. Rep, vol.8, p.8057, 2018.

S. Ncube, C. Coleman, A. S. Sousa, C. Nie, P. Lonchambon et al., J. Appl. Phys, vol.123, p.213901, 2018.

L. V. Yashina, A. A. Eliseev, M. V. Kharlamova, A. A. Volykhov, A. V. Egorov et al., J. Phys. Chem. C, vol.115, pp.3578-3586, 2011.

L. Shi, K. Yanagi, K. Cao, U. Kaiser, P. Ayala et al., ACS Nano, vol.12, pp.8477-8484, 2018.

C. H. Chang, H. Jung, Y. Rheem, K. Lee, D. Lim et al., Nanoscale, vol.5, pp.1616-1623, 2013.

S. Heeg, L. Shi, L. V. Poulikakos, T. Pichler, and L. Novotny, Nano Lett, vol.18, pp.5426-5431, 2018.

S. Iijima, Nature, vol.354, pp.56-58, 1991.

M. R. Pederson and J. Q. Broughton, Phys. Rev. Lett, vol.69, pp.2689-2692, 1992.

P. M. Ajayan and S. Iijima, Nature, vol.361, pp.333-334, 1993.

L. H. Malcolm and . Green, His main research fields are the chemical vapour deposition synthesis, functionalisation and filling of carbon nanotubes (double-walled in particular) for various applications. He is working on the human health issues related to carbon nanomaterials, including the synthesis and functionalisation as well as the study of their environmental impact. He is expert for the French National Agency for Food, Emmanuel Flahaut works as a CNRS research director at the CIRIMAT, 2008.

, 2009) and subsequently was awarded with a fellowship of the Fundación Carolina for a MSc. degree in Inorganic and Molecular chemistry from the Universidad de Alcalá de Henares. She obtained her Ph D. in Materials Science from the Autonomous University of Barcelona (UAB, ICMAB, 2016) and is currently working as a Post-doctoral researcher in the group of Dr, Tobias at the Institut de Ciència de Materials de Barcelona (ICMAB-CSIC) in the synthesis and modification of new inorganic nanomaterials for energy and biomedical applications

, He received Bachelor of Chemistry (with Honours) from the Autonomous University of Barcelona (UAB, 2000) and Ph.D. with European mention (UAB, ICMAB, 2004), 2004.

L. H. Malcolm, Green at the University of Oxford. He has coordinated the FP7 European network RADDEL and has been recently granted an ERC Consolidator Grant (NEST)