表面電漿共振效應(surface plasmon resonance)是一個新穎的突破，這 個效應讓金屬表面、奈米金屬粒子表面，能夠突破繞射的極限，而本論文 是研究:侷域化表面電漿共振的結構，進一步去分析。
本論文的侷域化表面電漿共振的結構，分別為單層的二維材料 MoSe2 ， 用來當作雷射的增益介質，並以激子為作為耦合出表面電漿子的媒介，並 以數層 hBN 用來彌補單層 MoSe2 的缺陷，並再用奈米銀柱，使光與奈米銀 柱的表面電漿耦合激發出光。
使用機械剝離法撕出單層 MoSe2 與數層 h-BN，利用轉移系統，並將單 層 MoSe2 、數層 h-BN，相互疊在一起，接著找出適當的奈米銀柱，也是用 相同的轉移方法，也相互疊在一起，就完成了本實驗的樣品，製作出三層 二維材料的異質結構。
接下來將此二維材料的異質結構，去進行光激發螢光系統量測分析， 探討此異質結構的轉移性，另外並分析 MoSe2 的製程方式，並分析出了表 面電漿共振增強 MoSe2 之自發輻射的特性。

The Surface Plasmon Resonance (SPR) effect is a breakthrough that enables metal surfaces and nano-metal particles to surpass the optical diffraction limit. This thesis focuses on the analysis of the SPR cavity structure. The localized SPR structure discussed in this thesis is a monolayer two-dimensional material, MoSe2, which serves as the gain medium for the laser. Excitons are used to couple out the surface plasmons, and several layers of hBN are added to compensate for the defects of the monolayer MoSe2 because hBN is an excellent insulator. Finally, a nano-silver wire is used to couple light with the surface plasmon of the nano-silver wire to excite light.
The preparation of the monolayer MoSe2 and several layers of hBN was achieved through mechanical exfoliation. The transfer method was used to stack the monolayer MoSe2, several layers of hBN, and the nano-silver wire together to create a three-layer, two-dimensional material heterogeneous structure.
This heterogeneous structure of the two-dimensional material will be studied and analyzed using photoluminescence to examine the spectral properties. The outcome of the SPR cavity structure analysis shows amplified spontaneous emission (ASE) characteristics but does not exhibit lasing characteristics.

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