Harnessing Multi-Photon Absorption to Produce Three-Dimensional Magnetic Structures at the Nanoscale.
magnetism
nanoscale
nanostructures
three-dimensional
two-photon lithography
Journal
Materials (Basel, Switzerland)
ISSN: 1996-1944
Titre abrégé: Materials (Basel)
Pays: Switzerland
ID NLM: 101555929
Informations de publication
Date de publication:
07 Feb 2020
07 Feb 2020
Historique:
received:
27
12
2019
revised:
01
02
2020
accepted:
05
02
2020
entrez:
13
2
2020
pubmed:
13
2
2020
medline:
13
2
2020
Statut:
epublish
Résumé
Three-dimensional nanostructured magnetic materials have recently been the topic of intense interest since they provide access to a host of new physical phenomena. Examples include new spin textures that exhibit topological protection, magnetochiral effects and novel ultrafast magnetic phenomena such as the spin-Cherenkov effect. Two-photon lithography is a powerful methodology that is capable of realising 3D polymer nanostructures on the scale of 100 nm. Combining this with postprocessing and deposition methodologies allows 3D magnetic nanostructures of arbitrary geometry to be produced. In this article, the physics of two-photon lithography is first detailed, before reviewing the studies to date that have exploited this fabrication route. The article then moves on to consider how non-linear optical techniques and post-processing solutions can be used to realise structures with a feature size below 100 nm, before comparing two-photon lithography with other direct write methodologies and providing a discussion on future developments.
Identifiants
pubmed: 32046068
pii: ma13030761
doi: 10.3390/ma13030761
pmc: PMC7041506
pii:
doi:
Types de publication
Journal Article
Review
Langues
eng
Références
Beilstein J Nanotechnol. 2012;3:597-619
pubmed: 23019557
ACS Nano. 2017 Nov 28;11(11):11066-11073
pubmed: 29072836
Acta Biomater. 2019 Aug;94:204-218
pubmed: 31055121
Nanotechnology. 2016 Sep 2;27(35):355301
pubmed: 27454835
Opt Lett. 2014 Dec 15;39(24):6847-50
pubmed: 25503012
Opt Lett. 1997 Jan 15;22(2):132-4
pubmed: 18183126
Lab Chip. 2010 Apr 21;10(8):1057-60
pubmed: 20358114
Small. 2014 Apr 9;10(7):1284-8
pubmed: 24339330
ACS Nano. 2018 Jun 26;12(6):5932-5939
pubmed: 29812903
Adv Mater. 2013 Nov 6;25(41):5863-8
pubmed: 23864519
Phys Rev Lett. 2019 Nov 22;123(21):217201
pubmed: 31809154
Sci Rep. 2016 May 04;6:25189
pubmed: 27143311
Nat Commun. 2017 Jun 09;8:15756
pubmed: 28598416
Nano Lett. 2020 Jan 8;20(1):184-191
pubmed: 31869235
Appl Phys Lett. 2011 Feb 7;98(6):62106
pubmed: 21383870
Phys Rev Lett. 1988 Nov 21;61(21):2472-2475
pubmed: 10039127
Adv Healthc Mater. 2020 Jan;9(1):e1901217
pubmed: 31746140
Nat Biotechnol. 2003 Nov;21(11):1369-77
pubmed: 14595365
Science. 2000 Aug 11;289(5481):930-2
pubmed: 10937991
Adv Mater. 2012 Feb 7;24(6):811-6
pubmed: 22213276
J Phys Chem B. 2006 Feb 23;110(7):3043-50
pubmed: 16494306
Small. 2019 Apr;15(16):e1805006
pubmed: 30829003
Science. 2008 Apr 11;320(5873):190-4
pubmed: 18403702
Nat Mater. 2010 Dec;9(12):980-3
pubmed: 20890280
Rep Prog Phys. 2015 Sep;78(9):094501
pubmed: 26288956
Nanoscale. 2018 May 31;10(21):9981-9986
pubmed: 29770815
Opt Lett. 2017 Apr 15;42(8):1584-1587
pubmed: 28409804
Nat Commun. 2018 Feb 9;9(1):593
pubmed: 29426947
Phys Rev Lett. 2014 Jun 27;112(25):257203
pubmed: 25014827
J Am Chem Soc. 2002 Sep 25;124(38):11480-5
pubmed: 12236762
Phys Rev Lett. 2015 Mar 20;114(11):115501
pubmed: 25839287
Phys Rev B Condens Matter. 1996 Oct 1;54(13):9353-9358
pubmed: 9984672
Opt Express. 2013 May 6;21(9):10831-40
pubmed: 23669940
Nano Lett. 2005 Jul;5(7):1303-7
pubmed: 16178228
Nanotechnology. 2017 Mar 3;28(9):095709
pubmed: 28139469