Au(19 nm)/Al2O3(19 nm), 8 periods
| Rhodamine 800 (715 nm) | 1.8-fold reduction of lifetime | ref.67 (2010)
|
Ag(25 nm, 11 layers)/PMMA(30 nm, 10 layers); Ag(30 nm, 5 layers)/LiF(40 nm, 4 layers); Ag(30 nm)/LiF(40 nm) 8 periods, and Ag(20 nm)/MgF2(30 nm) 8 periods
| IR-140 dye (850 nm) | 1.4 for Ag/LiF; 5.7 for Ag/PMMA | ref.68 (2011)
|
Au(19 nm)/Al2O3(19 nm), 8 periods
| Rhodamine 800 (720 nm) | 9.3 | ref.69 (2012)
|
Ag(9 nm)/TiO2(22 nm), 10 periods
| CdSe/ZnS colloidal QDs (630 nm) | 3 | ref.54 (2012)
|
Au(15 nm)/Al2O3(28 nm), 10 periods
| Coumarin 500 (480 nm) | 2 | ref.70 (2013)
|
Au(19 nm)/Al2O3(19 nm), 8 periods
| NVC (637 nm) | 2.57 | ref.71 (2013)
|
Au nanoparticles (15 nm)/CdTe QDs (5.5 nm), separated by dielectric (PDDA/PPS) spacers with varied thickness (0–10 nm), 2–5 periods | CdTe QDs (590 nm) | 4.4 | ref.74, 75 (2011, 2014)
|
TiN(8.5 nm)/Al0.7Sc0.3N(6.3 nm),10 periods
| NVC (600–800 nm) | 4.7 max Purcell factor | ref.72 (2015)
|
TiN(15 nm)/SiO2(15 nm), 5 periods
| 20 nm thick Si QDs (720 nm) | 1.6 | ref.73 (2015)
|
Ag(25 nm) 7 layers /MgF2(35 nm) 6 layers
| HITC dye-doped polymeric film
(860 nm)
| 7 | ref.78 (2015)
|
Ag(10 nm)/TiO2(30 nm), 10 periods
| Rhodamine 6G (R6G, 540–600 nm) | 80-fold intensity enhancement | ref.85 (2018)
|
Au(26.87–37.31%)/poly(vinyl alcohol) (PVA), 4 periods | R6G dye (540–600 nm) | 1.55 for HMM1, 1.18 for HMM2 | ref.86 (2018)
|
Ag(22 nm)/MoO3(10 nm) 6 periods, HMM;
Ag(12 nm)/MoO3(20 nm) 6 periods, elliptic
| ZnO nanoparticles (395 nm) | Lasing threshold 20% less and 6 times emission intensity | ref.76 (2018)
|
Al(20 nm)/MgF2(20 nm), 4 periods
| 15-nm thick AlGaN MQWs (318 nm) | 160-fold emission rate | ref.77 (2018)
|
Au(30 nm)/ZnS(30 nm) 5 periods, with cylindrical gold patch antenna | SiC (900 nm) | Purcell factor of 400 at 850 nm. (Theory) | ref.87 (2018)
|
Ag(25 nm)/PMMA(30 nm), 5 periods | Zinc tetraphenylporphyrin (ZnTPP), S1 (580–670 nm), S2 (400–460 nm)
| 18-fold increase in fluorescence intensity from S2 state to S1.
| ref.79 (2018)
|
320 nm thick HMM of Ag/ITO with unit cell thickness from 20 to 80 nm | CdSe/ZnS QDs (550 nm) | 40-fold intensity enhancement | ref.83 (2018)
|
Quinoidal oligothiophene derivative
QQT(CN)4 (60 nm thick), 670 to 920 nm
| Styryl9M dye (680–850 nm) | 1.3-1.4 Purcell factor | ref.80 (2019)
|
Ag(24 nm)/TiO2(30 nm) 5, 9, 13, and 17 layers with cylindrical Ag antenna
| CdSeS/ZnS QDs (660 nm) | 200-fold enhancement for 5-layered HMM | ref.88 (2020)
|
Au(15 nm)/SiO2(25 nm) 3, 5, and 8 periods
| Emitter (600–1600 nm) | 60–85 (Theory) | ref.82 (2020)
|
Ag(16 nm)/Al2O3(24 nm), 3 periods
| WS2 monolayer (615 nm)
| 30-fold enhancement of the overall PL intensity | ref.90 (2020)
|
Ag(25 nm)/LiF(35 nm) and Ag(40 nm)/LiF(40 nm), 6 or 8 periods | CsPbI3 Perovskite nanocrystals (520 nm)
| 3-fold Purcell enhancement | ref.94 (2020)
|
Au(10 nm)/ Al2O3(10 nm), 2–7 periods
| BA2Cs3MA3Pb7Br2I20 Perovskite film (700 nm)
| 1.6-3-fold Purcell enhancement depending on number of periods | ref.95(2021)
|
Ag(25 nm)/PMMA(40 nm) and Ag(25 nm)/PMMA(30 nm), 4 periods on paper | MAPbBr3 perovskite nanocrystals (520–550 nm)
| 3.5-fold intensity enhancement | ref.96 (2021)
|
Aperiodic Ag (20 nm, 6 layers)/SiO2(20 nm, 6 layers) in Fibonacci sequence
| Colloidal CdSe/ZnS QDs (640 nm) | 1.6 than Ag layer, 1.35 than periodic material | ref.97 (2014)
|
Aperiodic Ag(20 nm, 8 layers)/SiO2(80 nm, 8 layers) in Tue-Morse (TM) sequence
| Colloidal CdSe/ZnS QDs (640 nm) | 1.45 than glass substrate | ref.98 (2019)
|