等离激元共振能量转移与增强光催化研究进展
|
摘要
等离激元共振能量转移指表面等离激元将俘获的能量通过偶极-偶极相互作用转移到邻近的半导体或分子等激子体系中,它是等离激元非辐射弛豫的一个通道,也可作为获取和利用等离激元共振能量的一种方式.此外,等离激元能量还可以通过热电子弛豫(非辐射)和光散射(辐射)等方式耗散.等离激元各个弛豫通道之间存在着很强的关联,相关的能量转移和电荷转移过程可以将等离激元耗散的能量输送到其他体系或转换为其他能量形式.本文主要介绍了等离激元共振能量转移和与其相关的能量和电荷转移过程(包括等离激元近场增强及耦合、远场散射、热电子弛豫等)的物理机制和动力学性质,并详细介绍了这些机制在增强光催化研究领域的最新进展.
Plasmon resonance energy transfer refers to the coherent energy transfer via dipole-dipole coupling from surface plasmons to adjacent exciton nanosystems such as semiconductor quantum dots or dye molecules. The plasmon resonance energy transfer is a non-radiative plasmon decay pathway, which can also act as an available channel to extract the plasmon-harvested energy. In addition, hot electron relaxation(non-radiative channel)and scattering(radiative channel) are also the dissipation pathways of surface plasmon resonances. The plasmon-harvested energy can be effectively transferred to other nanosystems or converted into other energy forms through these correlated dissipation pathways. In this paper, the underlying mechanism and dynamics of the plasmon resonance energy transfer as well as the related energy and charge transfer processes(such as near field enhancement and coupling, far field scattering, plasmon-induced hot electron transfer) are introduced. The recent research progress of the plasmon-enhanced photocatalysis by energy and charge transfer is reviewed.
Plasmon resonance energy transfer refers to the coherent energy transfer via dipole-dipole coupling from surface plasmons to adjacent exciton nanosystems such as semiconductor quantum dots or dye molecules. The plasmon resonance energy transfer is a non-radiative plasmon decay pathway, which can also act as an available channel to extract the plasmon-harvested energy. In addition, hot electron relaxation(non-radiative channel)and scattering(radiative channel) are also the dissipation pathways of surface plasmon resonances. The plasmon-harvested energy can be effectively transferred to other nanosystems or converted into other energy forms through these correlated dissipation pathways. In this paper, the underlying mechanism and dynamics of the plasmon resonance energy transfer as well as the related energy and charge transfer processes(such as near field enhancement and coupling, far field scattering, plasmon-induced hot electron transfer) are introduced. The recent research progress of the plasmon-enhanced photocatalysis by energy and charge transfer is reviewed.
引文
[1]Liu G L,Long Y T,Choi Y,Kang T,Lee L P 2007 Nat.Meth.4 1015
[2]Choi Y,Park Y,Kang T,Lee L P 2009 Nat. Nanotechnol. 4742
[3]Li J T,Cushing S K,Meng F K,Senty T R,Bristow A D,Wu N Q 2015 Nat.Photon.9 601
[4]Engel G S,Calhoun T R,Read E L,Ahn T K,Mancal T,Cheng Y C,Blankenship R E,Fleming G R 2007 Nature 446782
[5]Mirkovic T,Ostroumov E E,Anna J M,van Grondelle R,Govindjee,Scholes G D 2017 Chem.Rev.117 249
[6]Forster T 1948 Ann.Phys.437 55
[7]Selvin P R 2000 Nat. Struct. Biol. 7 730
[8]Clapp A R,Medintz I L,Mattoussi H 2006 ChemPhysChem7 47
[9]Govorov A O,Lee J,Kotov N A 2007 Phys.Rev.B 76125308
[10]Su X R,Zhang W,Zhou L,Peng X N,Pang D W,Liu S D,Zhou Z K,Wang Q Q 2010 Appl. Phys.Lett.96 043106
[11]Su X R,Zhang W,Zhou L,Peng X N,Wang Q Q 2010 Opt.Express 18 6516
[12]Lunz M,Gerard V A,Gun'ko Y K,Lesnyak V,Gaponik N,Susha A S,Rogach A L,Bradley A L 2011 Nano Lett. 113341
[13]Cushing S K,Li J T,Meng F K,Senty T R,Suri S,Zhi M J,Li M,Bristow A D,Wu N Q 2012 J.Am.Chem.Soc.13415033
[14]Choi Y H,Kang T,Lee L P 2009 Nano Lett.9 85
[15]Fujishima A,Honda K 1972 Nature 238 37
[16]Serpone N,Emeline A V 2012 J.Phys.Chem.Lett.3 673
[17]Hashimoto K,Irie H,Fujishima A 2005 Jpn.J.Appl. Phys.44 8269
[18]Schneider J,Matsuoka M,Takeuchi M,Zhang J L,Horiuchi Y,Anpo M,Bahnemann D W 2014 Chem.Rev.114 9919
[19]Nakata K,Fujishima A 2012 J.Photoch.Photobio.C 13 169
[20]Zhang X M,Chen Y L,Liu R S,Tsai D P 2013 Rep.Prog.Phys.76 046401
[21]Kale M J,Avanesian T,Christopher P 2014 ACS Catal. 4116
[22]Liu L Q,Zhang X N,Yang L F,Ren L T,Wang D F,Ye J H 2017 Natl. Sci.Rev.4 761
[23]Warren S C,Thimsen E 2012 Energ.Environ.Sci.5 5133
[24]Linic S,Aslam U,Boerigter C,Morabito M 2015 Nat.Mater.14 567
[25]Erwin W R,Zarick H F,Talbert E M,Bardhan R 2016Energ.Environ.Sci.9 1577
[26]Brongersma M L,Halas N J,Nordlander P 2015 Nat.Nanotechnol.10 25
[27]Hartland G V,Besteiro L V,Johns P,Govorov A O 2017A CS Energy Lett.2 1641
[28]Foerster B,Joplin A,Kaefer K,Celiksoy S,Link S,Sonnichsen C 2017 A CS Nano 11 2886
[29]Zijlstra P,Paulo P M,Yu K,Xu Q,Orrit M 2012 An.gew.Chem.124 8477
[30]Knight M W,Sobhani H,Nordlander P,Halas N J 2011Science 332 702
[31]Clavero C 2014 Nat.Photon.8 95
[32]Jia C C,Li X X,Xin N,Gong Y,Guan J X,Meng L A,Meng S,Guo X F 2016 Adv.Energy Mater.6 1600431
[33]Li W,Valentine J G 2017 Nanophotonics 6 177
[34]Li X H,Zhu J M,Wei B Q 2016 Chem.Soc.Rev.45 3145
[35]Wang M Y,Ye M D,Iocozzia J,Lin C J,Lin Z Q 2016 Adv.Sci. 3 1600024
[36]Ma X C,Dai Y,Yu L,Huang B B 2016 Light Sci.Appl. 5e16017
[37]DuChene J S,Tagliabue G,Welch A J,Cheng W H,Atwater H A 2018 Nano Lett.18 2545
[38]Schather A E,Manjavacas A,Lauchner A,Marangoni V S,DeSantis C J,Nordlander P,Halas N J 2017 J.Phys.Chem.Lett.8 2060
[39]Robatjazi H,Bahauddin S M,Doiron C,Thomann I 2015Nano Lett.15 6155
[40]Ding S J,Yang D J,Li J L,Pan G M,Ma L,Lin Y J,Wang J H,Zhou L,Feng M,Xu H X,Gao S W,Wang Q Q2017 Nanoscale 9 3188
[41]Zhang Y C,He S,Guo W X,Hu Y,Huang J W,Mulcahy J R,Wei W D 2018 Chem.Rev.118 2927
[42]Park J Y,Kim S M,Lee H,Nedrygailov I I 2015 Acc.Chem.Res.48 2475
[43]Zhan C,Chen X J,Yi J,Li J F,Wu D Y,Tian Z Q 2018Nat.Rev.Chem.2 216
[44]Xie W,Schlucker S 2015 Nat.Commun.6 7570
[45]Cortes E,Xie W,Cambiasso J,Jermyn A S,Sundararaman R,Narang P,Schlucker S,Maier S A 2017 Nat.Commun.814880
[46]Mukherjee S,Zhou L,Goodman A M,Large N,AyalaOrozco C,Zhang Y,Nordlander P,Halas N J 2014 J.Am.Chem.Soc.136 64
[47]Mukherjee S,Libisch F,Large N,Neumann O,Brown L V,Cheng J,Lassiter J B,Carter E A,Nordlander P,Halas N J2013 Nano Lett. 13 240
[48]Huschka R,Zuloaga J,Knight M W,Brown L V,Nordlander P,Halas N J 2011 J.Am.Chem.Soc.133 12247
[49]Furube A,Hashimoto S 2017 NPG Asia Mater.9 e454
[50]Wang S Y,Gao Y Y,Miao S,Liu T F,Mu L C,Li R G,Fan F T,Li C 2017 J.Am.Chem.Soc.139 11771
[51]Zhai Y M,DuChene J S,Wang Y C,Qiu J J,JohnstonPeck A C,You B,Guo W X,DiCiaccio B,Qian K,Zhao E W,Ooi F,Hu D H,Su D,Stach E A,Zhu Z H,Wei W D2016 Nat.Mater.15 889
[52]Fang Z Y,Wang Y M,Liu Z,Schlather A,Ajayan P M,Koppens F H L,Nordlander P,Halas N J 2012 A CS Nano 610222
[53]Kang Y M,Najmaei S,Liu Z,Bao Y J,Wang Y M,Zhu X,Halas N J,Nordlander P,Ajayan P M,Lou J,Fang Z Y2014 Adv.Mater.26 6467
[54]Zaleska-Medynska A,Marchelek M,Diak M,Grabowska E2016 Adv.Colloid Interface Sci.229 80
[55]Gilroy K D,Ruditskiy A,Peng H C,Qin D,Xia Y N 2016Chem.Rev.116 10414
[56]Govorov A O,Zhang H,Demir H V,Gun'ko Y K 2014 Nano Today 9 85
[57]Fofang N T,Grady N K,Fan Z Y,Govorov A O,Halas N J2011 Nano Lett. 11 1556
[58]Hao Y W,Wang H Y,Jiang Y,Chen Q D,Ueno K,Wang W Q,Misawa H,Sun H B 2011 Angew.Chem.Int.Ed.507824
[59]Vasa P,Wang W,Pomraenke R,Lammers M,Maiuri M,Manzoni C,Cerullo G,Lienau C 2013 Nat.Photon.7 128
[60]Nan F,Zhang Y F,Li X G,Zhang X T,Li H,Zhang X H,Jiang R B,Wang J F,Zhang W,Zhou L,Wang J H,Wang Q Q,Zhang Z Y 2015 Nano Lett.15 2705
[61]Faucheaux J A,Fu J,Jain P K 2014 J.Phys.Chem.C 1182710
[62]Torma P,Barnes W L 2015 Rep.Prog.Phys.78 013901
[63]Li X G,Zhou L,Hao Z H,Wang Q Q 2018 Adv.Opt.Mater.6 1800275
[64]Yin T T,Jiang L Y,Shen Z X 2018 Chin.Phys.B 27097803
[65]Nan F,Cheng Z Q,Wang Y L,Zhang Q,Zhou L,Yang Z J,Zhong Y T,Liang S,Xiong Q H,Wang Q Q 2014 Sci.Rep.4 4839
[66]Ding S J,Nan F,Yang D J,Liu X L,Wang Y L,Zhou L,Hao Z H,Wang Q Q 2015 Sci.Rep.5 9735
[67]Bellessa J,Bonnand C,Plenet J C,Mugnier J 2004 Phys.Rev.Lett.93 036404
[68]Dintinger J,Klein S,Bustos F,Barnes W L,Ebbesen T W2005 Phys.Rev.B 71 035424
[69]Vasa P,Pomraenke R,Schwieger S,Mazur Y I,Kunets V,Srinivasan P,Johnson E,Kihm J E,Kim D S,Runge E,Salamo G,Lienau C 2008 Phys.Rev.Lett.101 116801
[70]Fofang N T,Park T H,Neumann O,Mirin N A,Nordlander P,Halas N J 2008 Nano Lett. 8 3481
[71]Ni W H,Yang Z,Chen H J,Li L,Wang J F 2008 J.AmChem.Soc.130 6692
[72]Ni W H,Ambjornsson T,Apell S P,Chen H J,Wang J F2010 Nano Lett.10 77
[73]Zhang Y F,Yang D J,Wang J H,Wang Y L,Ding S J,Zhou L,Hao Z H,Wang Q Q 2015 Nanoscale 7 8503
[74]DeLacy B G,Miller O D,Hsu C W,Zander Z,Lacey S,Yagloski R,Fountain A W,Valdes E,Anquillare E,Soljacic M,Johnson S G,Joannopoulos J D 2015 Nano Lett.15 2588
[75]Schlather A E,Large N,Urban A S,Nordlander P,Halas N J 2013 Nano Lett. 13 3281
[76]Wurtz G A,Evans P R,Hendren W,Atkinson R,Dickson W,Pollard R J,Zayats A V,Harrison W,Bower C 2007Nano Lett.7 1297
[77]Zheng Y B,Juluri B K,Jensen L L,Ahmed D,Lu M Q,Jensen L,Huang T J 2010 Adv.Mater.22 3603
[78]Sugawara Y,Kelf T A,Baumberg J J,Abdelsalam M E,Bartlett P N 2006 Phy.s.Rev.Lett. 97 266808
[79]Liu W J,Lee B,Naylor C H,Ee H S,Park J,Johnson A T C,Agarwal R 2016 Nano Lett.16 1262
[80]Lee B,Liu W J,Naylor C H,Park J,Malek S C,Berger J S,Johnson A T C,Agarwal R 2017 Nano Lett.17 4541
[81]Wang S J,Li S L,Chervy T,Shalabney A,Azzini S,Orgiu E,Hutchison J A,Genet C,Samori P,Ebbesen T W 2016Nano Lett.16 4368
[82]Cuadra J,Baranov D G,Wersall M,Verre R,Antosiewicz T J,Shegai T 2018 Nano Lett.18 1777
[83]Zheng D,Zhang S P,Deng Q,Kang M,Nordlander P,Xu H X 2017 Nano Lett.17 3809
[84]Lawrie B J,Kim K W,Norton D P,Haglund R F 2012Nano Lett.12 6152
[85]Wang H,Ke Y L,Xu N S,Zhan R Z,Zheng Z B,Wen J X,Yan J H,Liu P,Chen J,She J C,Zhang Y,Liu F,Chen H J,Deng S Z 2016 Nano Lett. 16 6886
[86]Ding S J,Li X G,Nan F,Zhong Y T,Zhou L,Xiao X D,Wang Q Q,Zhang Z Y 2017 Phys.Rev.Lett.119 177401
[87]Chikkaraddy R,de Nijs B,Benz F,Barrow S J,Scherman O A,Rosta E,Demetriadou A,Fox P,Hess O,Baumberg J J2016 Nature 535 127
[88]Santhosh K,Bitton O,Chuntonov L,Haran G 2016 Nat.Commun.7 11823
[89]Nan F,Ding S J,Ma L,Cheng Z Q,Zhong Y T,Zhang Y F,Qiu Y H,Li X G,Zhou L,Wang Q Q 2016 Nanoscale 815071
[90]Cushing S K,Li J T,Bright J,Yost B T,Zheng P,Bristow A D,Wu N Q 2015 J.Phys.Chem.C119 16239
[91]Li J T,Cushing S K,Zheng P,Meng F K,Chu D,Wu N Q2013 Nat.Commun.4 2651
[92]Wu N Q 2018 Nanoscale 10 2679
[93]Atwater H A,Polman A 2010 Nat.Mater.9 205
[94]Wadell C,Antosiewicz T J,Langhammer C 2012 Nano Lett.12 4784
[95]Swearer D F,Zhao H Q,Zhou L N,Zhang C,Robatjazi H,Martirez J M P,Krauter C M,Yazdi S,McClain M J,Ringe E,Carter E A,Nordlander P,Halas N J 2016 Proc.Natl Acad.Sci.U.S.A.113 8916
[96]Zhang C,Zhao H Q,Zhou L A,Schlather A E,Dong L L,McClain M J,Swearer D F,Nordlander P,Halas N J 2016Nano Lett.16 6677
[97]Li K,Hogan N J,Kale M J,Halas N J,Nordlander P,Christopher P 2017 Nano Lett.17 3710
[98]Robatjazi H,Zhao H Q,Swearer D F,Hogan N J,Zhou L N,Alabastri A,McClain M J,Nordlander P,Halas N J 2017Nat.Commun.8 27
[99]Chen K,Ding S J,Luo Z J,Pan G M,Wang J H,Liu J,Zhou L,Wang Q Q 2018 Nanoscale 10 4130
[100]Mubeen S,Lee J,Singh N,Kramer S,Stucky G D,Moskovits M 2013 Nat.Nanotechnol. 8 247
[101]Cushing S K 2017 Nat. Photon.11 748
[102]Petek H 2012 J.Chem.Phys.137 091704
[103]Narang P,Sundararaman R,Atwater H A 2016Nanophotonics 5 96
[104]Sundararaman R,Narang P,Jermyn A S,Goddard W A,Atwater H A 2014 Nat.Commun.5 5788
[105]Manjavacas A,Liu J G,Kulkarni V,Nordlander P 2014ACS Nano 8 7630
[106]Govorov A O,Zhang H 2015 J.Phys.Chem.C 119 6181
[107]Brown A M,Sundararaman R,Narang P,Goddard W A,Atwater H A 2016 A CS Nano 10 957
[108]Besteiro L V,Kong X T,Wang Z M,Hartland G,Govorov A 0 2017 ACS Photon.4 2759
[109]Dal Forno S,Ranno L,Lischner J 2018 J.Phys.Chem.C122 8517
[110]Liu L Q,Ouyang S X,Ye J H 2013 Angew.Chem..Int.Ed.52 6689
[111]Ma L,Liang S,Liu X L,Yang D J,Zhou L,Wang Q Q 2015Adv.Funct.Mater.25 898
[112]Naya S,Kume T,Akashi R,Fujishima M,Tada H 2018 J.Am.Chem.Soc.140 1251
[113]Wang J H,Chen M,Luo Z J,Ma L,Zhang Y F,Chen K,Zhou L,Wang Q Q 2016 J.Phys.Chem.C 120 14805
[114]Ma L,Yang D J,Luo Z J,Chen K,Xie Y,Zhou L,Wang Q Q 2016 J.Phys.Chem.C120 26996
[115]Li J T,Cushing S K,Zheng P,Senty T,Meng F K,Bristow A D,Manivannan A,Wu N Q 2014 J.Am.Chem.Soc.1368438
[116]Ma L,Chen K,Nan F,Wang J H,Yang D J,Zhou L,Wang Q Q 2016 Adv.Funct.Mater.26 6076
[117]Ma S,Chen K,Qiu Y H,Gong L L,Pan G M,Lin Y J,Hao Z H,Zhou L,Wang Q Q 2019 J.Mater.Chem.A 7 3408
[118]Chen K,Ma L,Wang J H,Cheng Z Q,Yang D J,Li Y Y,Ding S J,Zhou L,Wang Q Q 2017 RSC A dv.7 26097
[119]Li Y Y,Wang J H,Luo Z J,Chen K,Cheng Z Q,Ma L,Ding S J,Zhou L,Wang Q Q 2017 Sci. Rep.7 7178
[120]Liu J,Chen K,Pan G M, Luo Z J,Xie Y,Li Y Y,Lin Y J,Hao Z H,Zhou L,Ding S J,Wang Q Q 2018 Nano scale 1019586
[121]Zheng B Y,Zhao H Q,Manjavacas A,McClain M,Nordlander P,Halas N J 2015 Nat.Commuu.6 7797
[122]Mubeen S,Hernandez-Sosa G,Moses D,Lee J,Moskovits M2011 Nano Lett.11 5548
[123]de Arquer F P G,Mihi A,Kufer D,Konstantatos G 2013A CS Nauo 7 3581
[124]Shiraishi Y,Yasumoto N,Imai J,Sakamoto H,Tanaka S,Ichikawa S,Ohtani B,Hirai T 2017 Nanoscale 9 8349
[125]Wang F,Li C H,Chen H J,Jiang R B,Sun L D,Li Q,Wang J F,Yu J C,Yan C H 2013 J.Am.Chem.Soc.1355588
[126]Zheng Z K,Tachikawa T,Majima T 2014 J.Am.Chem.Soc.136 6870
[127]Zheng Z K,Tachikawa T,Majima T 2015 J.Am.Chem.Soc.137 948
[128]Aslam U,Chavez S,Linic S 2017 Nat.Nanotechnol. 12 1000
[129]Rao V G,Aslam U,Linic S 2019 J.Am.Chem.Soc.141 643
[130]Chavez S,Aslam U,Linic S 2018 ACS Energy Lett.3 1590
[131]Christopher P,Xin H L,Linic S 2011 Nat.Chem.3 467
[132]Christopher P,Xin H L,Marimuthu A,Linic S 2012 Nat.Mater.11 1044
[133]Zhou L A,Swearer D F,Zhang C,Robatjazi H,Zhao H Q,Henderson L,Dong L L,Christopher P,Carter E A,Nordlander P,Halas N J 2018 Science 362 69
[134]Wu K,Chen J,McBride J R,Lian T 2015 Science 349 632
[135]Boerigter C,Campana R,Morabito M,Linic S 2016 Nat.Commun.7 10545
[136]Boerigter C,Aslam U,Linic S 2016 ACS Nano 10 6108
[137]Kale M J,Avanesian T,Xin H L,Yan J,Christopher P2014 Nano Lett.14 5405
[2]Choi Y,Park Y,Kang T,Lee L P 2009 Nat. Nanotechnol. 4742
[3]Li J T,Cushing S K,Meng F K,Senty T R,Bristow A D,Wu N Q 2015 Nat.Photon.9 601
[4]Engel G S,Calhoun T R,Read E L,Ahn T K,Mancal T,Cheng Y C,Blankenship R E,Fleming G R 2007 Nature 446782
[5]Mirkovic T,Ostroumov E E,Anna J M,van Grondelle R,Govindjee,Scholes G D 2017 Chem.Rev.117 249
[6]Forster T 1948 Ann.Phys.437 55
[7]Selvin P R 2000 Nat. Struct. Biol. 7 730
[8]Clapp A R,Medintz I L,Mattoussi H 2006 ChemPhysChem7 47
[9]Govorov A O,Lee J,Kotov N A 2007 Phys.Rev.B 76125308
[10]Su X R,Zhang W,Zhou L,Peng X N,Pang D W,Liu S D,Zhou Z K,Wang Q Q 2010 Appl. Phys.Lett.96 043106
[11]Su X R,Zhang W,Zhou L,Peng X N,Wang Q Q 2010 Opt.Express 18 6516
[12]Lunz M,Gerard V A,Gun'ko Y K,Lesnyak V,Gaponik N,Susha A S,Rogach A L,Bradley A L 2011 Nano Lett. 113341
[13]Cushing S K,Li J T,Meng F K,Senty T R,Suri S,Zhi M J,Li M,Bristow A D,Wu N Q 2012 J.Am.Chem.Soc.13415033
[14]Choi Y H,Kang T,Lee L P 2009 Nano Lett.9 85
[15]Fujishima A,Honda K 1972 Nature 238 37
[16]Serpone N,Emeline A V 2012 J.Phys.Chem.Lett.3 673
[17]Hashimoto K,Irie H,Fujishima A 2005 Jpn.J.Appl. Phys.44 8269
[18]Schneider J,Matsuoka M,Takeuchi M,Zhang J L,Horiuchi Y,Anpo M,Bahnemann D W 2014 Chem.Rev.114 9919
[19]Nakata K,Fujishima A 2012 J.Photoch.Photobio.C 13 169
[20]Zhang X M,Chen Y L,Liu R S,Tsai D P 2013 Rep.Prog.Phys.76 046401
[21]Kale M J,Avanesian T,Christopher P 2014 ACS Catal. 4116
[22]Liu L Q,Zhang X N,Yang L F,Ren L T,Wang D F,Ye J H 2017 Natl. Sci.Rev.4 761
[23]Warren S C,Thimsen E 2012 Energ.Environ.Sci.5 5133
[24]Linic S,Aslam U,Boerigter C,Morabito M 2015 Nat.Mater.14 567
[25]Erwin W R,Zarick H F,Talbert E M,Bardhan R 2016Energ.Environ.Sci.9 1577
[26]Brongersma M L,Halas N J,Nordlander P 2015 Nat.Nanotechnol.10 25
[27]Hartland G V,Besteiro L V,Johns P,Govorov A O 2017A CS Energy Lett.2 1641
[28]Foerster B,Joplin A,Kaefer K,Celiksoy S,Link S,Sonnichsen C 2017 A CS Nano 11 2886
[29]Zijlstra P,Paulo P M,Yu K,Xu Q,Orrit M 2012 An.gew.Chem.124 8477
[30]Knight M W,Sobhani H,Nordlander P,Halas N J 2011Science 332 702
[31]Clavero C 2014 Nat.Photon.8 95
[32]Jia C C,Li X X,Xin N,Gong Y,Guan J X,Meng L A,Meng S,Guo X F 2016 Adv.Energy Mater.6 1600431
[33]Li W,Valentine J G 2017 Nanophotonics 6 177
[34]Li X H,Zhu J M,Wei B Q 2016 Chem.Soc.Rev.45 3145
[35]Wang M Y,Ye M D,Iocozzia J,Lin C J,Lin Z Q 2016 Adv.Sci. 3 1600024
[36]Ma X C,Dai Y,Yu L,Huang B B 2016 Light Sci.Appl. 5e16017
[37]DuChene J S,Tagliabue G,Welch A J,Cheng W H,Atwater H A 2018 Nano Lett.18 2545
[38]Schather A E,Manjavacas A,Lauchner A,Marangoni V S,DeSantis C J,Nordlander P,Halas N J 2017 J.Phys.Chem.Lett.8 2060
[39]Robatjazi H,Bahauddin S M,Doiron C,Thomann I 2015Nano Lett.15 6155
[40]Ding S J,Yang D J,Li J L,Pan G M,Ma L,Lin Y J,Wang J H,Zhou L,Feng M,Xu H X,Gao S W,Wang Q Q2017 Nanoscale 9 3188
[41]Zhang Y C,He S,Guo W X,Hu Y,Huang J W,Mulcahy J R,Wei W D 2018 Chem.Rev.118 2927
[42]Park J Y,Kim S M,Lee H,Nedrygailov I I 2015 Acc.Chem.Res.48 2475
[43]Zhan C,Chen X J,Yi J,Li J F,Wu D Y,Tian Z Q 2018Nat.Rev.Chem.2 216
[44]Xie W,Schlucker S 2015 Nat.Commun.6 7570
[45]Cortes E,Xie W,Cambiasso J,Jermyn A S,Sundararaman R,Narang P,Schlucker S,Maier S A 2017 Nat.Commun.814880
[46]Mukherjee S,Zhou L,Goodman A M,Large N,AyalaOrozco C,Zhang Y,Nordlander P,Halas N J 2014 J.Am.Chem.Soc.136 64
[47]Mukherjee S,Libisch F,Large N,Neumann O,Brown L V,Cheng J,Lassiter J B,Carter E A,Nordlander P,Halas N J2013 Nano Lett. 13 240
[48]Huschka R,Zuloaga J,Knight M W,Brown L V,Nordlander P,Halas N J 2011 J.Am.Chem.Soc.133 12247
[49]Furube A,Hashimoto S 2017 NPG Asia Mater.9 e454
[50]Wang S Y,Gao Y Y,Miao S,Liu T F,Mu L C,Li R G,Fan F T,Li C 2017 J.Am.Chem.Soc.139 11771
[51]Zhai Y M,DuChene J S,Wang Y C,Qiu J J,JohnstonPeck A C,You B,Guo W X,DiCiaccio B,Qian K,Zhao E W,Ooi F,Hu D H,Su D,Stach E A,Zhu Z H,Wei W D2016 Nat.Mater.15 889
[52]Fang Z Y,Wang Y M,Liu Z,Schlather A,Ajayan P M,Koppens F H L,Nordlander P,Halas N J 2012 A CS Nano 610222
[53]Kang Y M,Najmaei S,Liu Z,Bao Y J,Wang Y M,Zhu X,Halas N J,Nordlander P,Ajayan P M,Lou J,Fang Z Y2014 Adv.Mater.26 6467
[54]Zaleska-Medynska A,Marchelek M,Diak M,Grabowska E2016 Adv.Colloid Interface Sci.229 80
[55]Gilroy K D,Ruditskiy A,Peng H C,Qin D,Xia Y N 2016Chem.Rev.116 10414
[56]Govorov A O,Zhang H,Demir H V,Gun'ko Y K 2014 Nano Today 9 85
[57]Fofang N T,Grady N K,Fan Z Y,Govorov A O,Halas N J2011 Nano Lett. 11 1556
[58]Hao Y W,Wang H Y,Jiang Y,Chen Q D,Ueno K,Wang W Q,Misawa H,Sun H B 2011 Angew.Chem.Int.Ed.507824
[59]Vasa P,Wang W,Pomraenke R,Lammers M,Maiuri M,Manzoni C,Cerullo G,Lienau C 2013 Nat.Photon.7 128
[60]Nan F,Zhang Y F,Li X G,Zhang X T,Li H,Zhang X H,Jiang R B,Wang J F,Zhang W,Zhou L,Wang J H,Wang Q Q,Zhang Z Y 2015 Nano Lett.15 2705
[61]Faucheaux J A,Fu J,Jain P K 2014 J.Phys.Chem.C 1182710
[62]Torma P,Barnes W L 2015 Rep.Prog.Phys.78 013901
[63]Li X G,Zhou L,Hao Z H,Wang Q Q 2018 Adv.Opt.Mater.6 1800275
[64]Yin T T,Jiang L Y,Shen Z X 2018 Chin.Phys.B 27097803
[65]Nan F,Cheng Z Q,Wang Y L,Zhang Q,Zhou L,Yang Z J,Zhong Y T,Liang S,Xiong Q H,Wang Q Q 2014 Sci.Rep.4 4839
[66]Ding S J,Nan F,Yang D J,Liu X L,Wang Y L,Zhou L,Hao Z H,Wang Q Q 2015 Sci.Rep.5 9735
[67]Bellessa J,Bonnand C,Plenet J C,Mugnier J 2004 Phys.Rev.Lett.93 036404
[68]Dintinger J,Klein S,Bustos F,Barnes W L,Ebbesen T W2005 Phys.Rev.B 71 035424
[69]Vasa P,Pomraenke R,Schwieger S,Mazur Y I,Kunets V,Srinivasan P,Johnson E,Kihm J E,Kim D S,Runge E,Salamo G,Lienau C 2008 Phys.Rev.Lett.101 116801
[70]Fofang N T,Park T H,Neumann O,Mirin N A,Nordlander P,Halas N J 2008 Nano Lett. 8 3481
[71]Ni W H,Yang Z,Chen H J,Li L,Wang J F 2008 J.AmChem.Soc.130 6692
[72]Ni W H,Ambjornsson T,Apell S P,Chen H J,Wang J F2010 Nano Lett.10 77
[73]Zhang Y F,Yang D J,Wang J H,Wang Y L,Ding S J,Zhou L,Hao Z H,Wang Q Q 2015 Nanoscale 7 8503
[74]DeLacy B G,Miller O D,Hsu C W,Zander Z,Lacey S,Yagloski R,Fountain A W,Valdes E,Anquillare E,Soljacic M,Johnson S G,Joannopoulos J D 2015 Nano Lett.15 2588
[75]Schlather A E,Large N,Urban A S,Nordlander P,Halas N J 2013 Nano Lett. 13 3281
[76]Wurtz G A,Evans P R,Hendren W,Atkinson R,Dickson W,Pollard R J,Zayats A V,Harrison W,Bower C 2007Nano Lett.7 1297
[77]Zheng Y B,Juluri B K,Jensen L L,Ahmed D,Lu M Q,Jensen L,Huang T J 2010 Adv.Mater.22 3603
[78]Sugawara Y,Kelf T A,Baumberg J J,Abdelsalam M E,Bartlett P N 2006 Phy.s.Rev.Lett. 97 266808
[79]Liu W J,Lee B,Naylor C H,Ee H S,Park J,Johnson A T C,Agarwal R 2016 Nano Lett.16 1262
[80]Lee B,Liu W J,Naylor C H,Park J,Malek S C,Berger J S,Johnson A T C,Agarwal R 2017 Nano Lett.17 4541
[81]Wang S J,Li S L,Chervy T,Shalabney A,Azzini S,Orgiu E,Hutchison J A,Genet C,Samori P,Ebbesen T W 2016Nano Lett.16 4368
[82]Cuadra J,Baranov D G,Wersall M,Verre R,Antosiewicz T J,Shegai T 2018 Nano Lett.18 1777
[83]Zheng D,Zhang S P,Deng Q,Kang M,Nordlander P,Xu H X 2017 Nano Lett.17 3809
[84]Lawrie B J,Kim K W,Norton D P,Haglund R F 2012Nano Lett.12 6152
[85]Wang H,Ke Y L,Xu N S,Zhan R Z,Zheng Z B,Wen J X,Yan J H,Liu P,Chen J,She J C,Zhang Y,Liu F,Chen H J,Deng S Z 2016 Nano Lett. 16 6886
[86]Ding S J,Li X G,Nan F,Zhong Y T,Zhou L,Xiao X D,Wang Q Q,Zhang Z Y 2017 Phys.Rev.Lett.119 177401
[87]Chikkaraddy R,de Nijs B,Benz F,Barrow S J,Scherman O A,Rosta E,Demetriadou A,Fox P,Hess O,Baumberg J J2016 Nature 535 127
[88]Santhosh K,Bitton O,Chuntonov L,Haran G 2016 Nat.Commun.7 11823
[89]Nan F,Ding S J,Ma L,Cheng Z Q,Zhong Y T,Zhang Y F,Qiu Y H,Li X G,Zhou L,Wang Q Q 2016 Nanoscale 815071
[90]Cushing S K,Li J T,Bright J,Yost B T,Zheng P,Bristow A D,Wu N Q 2015 J.Phys.Chem.C119 16239
[91]Li J T,Cushing S K,Zheng P,Meng F K,Chu D,Wu N Q2013 Nat.Commun.4 2651
[92]Wu N Q 2018 Nanoscale 10 2679
[93]Atwater H A,Polman A 2010 Nat.Mater.9 205
[94]Wadell C,Antosiewicz T J,Langhammer C 2012 Nano Lett.12 4784
[95]Swearer D F,Zhao H Q,Zhou L N,Zhang C,Robatjazi H,Martirez J M P,Krauter C M,Yazdi S,McClain M J,Ringe E,Carter E A,Nordlander P,Halas N J 2016 Proc.Natl Acad.Sci.U.S.A.113 8916
[96]Zhang C,Zhao H Q,Zhou L A,Schlather A E,Dong L L,McClain M J,Swearer D F,Nordlander P,Halas N J 2016Nano Lett.16 6677
[97]Li K,Hogan N J,Kale M J,Halas N J,Nordlander P,Christopher P 2017 Nano Lett.17 3710
[98]Robatjazi H,Zhao H Q,Swearer D F,Hogan N J,Zhou L N,Alabastri A,McClain M J,Nordlander P,Halas N J 2017Nat.Commun.8 27
[99]Chen K,Ding S J,Luo Z J,Pan G M,Wang J H,Liu J,Zhou L,Wang Q Q 2018 Nanoscale 10 4130
[100]Mubeen S,Lee J,Singh N,Kramer S,Stucky G D,Moskovits M 2013 Nat.Nanotechnol. 8 247
[101]Cushing S K 2017 Nat. Photon.11 748
[102]Petek H 2012 J.Chem.Phys.137 091704
[103]Narang P,Sundararaman R,Atwater H A 2016Nanophotonics 5 96
[104]Sundararaman R,Narang P,Jermyn A S,Goddard W A,Atwater H A 2014 Nat.Commun.5 5788
[105]Manjavacas A,Liu J G,Kulkarni V,Nordlander P 2014ACS Nano 8 7630
[106]Govorov A O,Zhang H 2015 J.Phys.Chem.C 119 6181
[107]Brown A M,Sundararaman R,Narang P,Goddard W A,Atwater H A 2016 A CS Nano 10 957
[108]Besteiro L V,Kong X T,Wang Z M,Hartland G,Govorov A 0 2017 ACS Photon.4 2759
[109]Dal Forno S,Ranno L,Lischner J 2018 J.Phys.Chem.C122 8517
[110]Liu L Q,Ouyang S X,Ye J H 2013 Angew.Chem..Int.Ed.52 6689
[111]Ma L,Liang S,Liu X L,Yang D J,Zhou L,Wang Q Q 2015Adv.Funct.Mater.25 898
[112]Naya S,Kume T,Akashi R,Fujishima M,Tada H 2018 J.Am.Chem.Soc.140 1251
[113]Wang J H,Chen M,Luo Z J,Ma L,Zhang Y F,Chen K,Zhou L,Wang Q Q 2016 J.Phys.Chem.C 120 14805
[114]Ma L,Yang D J,Luo Z J,Chen K,Xie Y,Zhou L,Wang Q Q 2016 J.Phys.Chem.C120 26996
[115]Li J T,Cushing S K,Zheng P,Senty T,Meng F K,Bristow A D,Manivannan A,Wu N Q 2014 J.Am.Chem.Soc.1368438
[116]Ma L,Chen K,Nan F,Wang J H,Yang D J,Zhou L,Wang Q Q 2016 Adv.Funct.Mater.26 6076
[117]Ma S,Chen K,Qiu Y H,Gong L L,Pan G M,Lin Y J,Hao Z H,Zhou L,Wang Q Q 2019 J.Mater.Chem.A 7 3408
[118]Chen K,Ma L,Wang J H,Cheng Z Q,Yang D J,Li Y Y,Ding S J,Zhou L,Wang Q Q 2017 RSC A dv.7 26097
[119]Li Y Y,Wang J H,Luo Z J,Chen K,Cheng Z Q,Ma L,Ding S J,Zhou L,Wang Q Q 2017 Sci. Rep.7 7178
[120]Liu J,Chen K,Pan G M, Luo Z J,Xie Y,Li Y Y,Lin Y J,Hao Z H,Zhou L,Ding S J,Wang Q Q 2018 Nano scale 1019586
[121]Zheng B Y,Zhao H Q,Manjavacas A,McClain M,Nordlander P,Halas N J 2015 Nat.Commuu.6 7797
[122]Mubeen S,Hernandez-Sosa G,Moses D,Lee J,Moskovits M2011 Nano Lett.11 5548
[123]de Arquer F P G,Mihi A,Kufer D,Konstantatos G 2013A CS Nauo 7 3581
[124]Shiraishi Y,Yasumoto N,Imai J,Sakamoto H,Tanaka S,Ichikawa S,Ohtani B,Hirai T 2017 Nanoscale 9 8349
[125]Wang F,Li C H,Chen H J,Jiang R B,Sun L D,Li Q,Wang J F,Yu J C,Yan C H 2013 J.Am.Chem.Soc.1355588
[126]Zheng Z K,Tachikawa T,Majima T 2014 J.Am.Chem.Soc.136 6870
[127]Zheng Z K,Tachikawa T,Majima T 2015 J.Am.Chem.Soc.137 948
[128]Aslam U,Chavez S,Linic S 2017 Nat.Nanotechnol. 12 1000
[129]Rao V G,Aslam U,Linic S 2019 J.Am.Chem.Soc.141 643
[130]Chavez S,Aslam U,Linic S 2018 ACS Energy Lett.3 1590
[131]Christopher P,Xin H L,Linic S 2011 Nat.Chem.3 467
[132]Christopher P,Xin H L,Marimuthu A,Linic S 2012 Nat.Mater.11 1044
[133]Zhou L A,Swearer D F,Zhang C,Robatjazi H,Zhao H Q,Henderson L,Dong L L,Christopher P,Carter E A,Nordlander P,Halas N J 2018 Science 362 69
[134]Wu K,Chen J,McBride J R,Lian T 2015 Science 349 632
[135]Boerigter C,Campana R,Morabito M,Linic S 2016 Nat.Commun.7 10545
[136]Boerigter C,Aslam U,Linic S 2016 ACS Nano 10 6108
[137]Kale M J,Avanesian T,Xin H L,Yan J,Christopher P2014 Nano Lett.14 5405