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Single molecular systems are typical quantum confinement systems, which have rich electronic states, photon states and spin states due to their discrete energy levels, localized orbitals and diverse chemical structures. The states determined by quantum mechanics in these molecular systems make it possible to serve as great physical entities for future quantum information technology. The detection and manipulation of quantum states on a single molecule scale are beneficial to the bottom-up construction of quantum devices. Owing to the highly limited spatial localization of single molecular systems, it is difficult to accurately address and manipulate them with conventional macroscopic characterization methods. Scanning tunneling microscope (STM) is such a powerful tool that it can achieve high-resolution real-space imaging as well as spectroscopic investigation, with the ability to in-situ manipulating the individual atoms or molecules. It can also work jointly with various near-field or external field characterization techniques, making it a most important technique for precisely detecting and manipulating quantum properties at a single molecule level. In this paper, we review recent research progress of quantum states of surface-supported single molecules and relevant structures based on scanning tunneling microscopy. We start from the methods for the synthesis of molecular structures with desired quantum states, and then we review the recent advances in the local spin states for single molecular systems and the optical properties of single molecules serving as a single-photon source. An emerging family of molecular nanographene systems showing intriguing topological properties and magnetic properties is also reviewed. In the last part, we summarize the research progress made recently and prospect the future development of the quantum states at a single molecular level.
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Keywords:
- scanning tunneling microscope /
- single molecule /
- quantum states /
- spin /
- single-photon source /
- topological states
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图 1 表面单分子结构的量子态的制备、表征与调控的研究示意图
Figure 1. Schematic of the research on the synthesis, characterization and manipulation of the quantum states of surface-supported single molecular structures.
图 2 (a) CoPc的结构模型, 在实验中, 1个瓣的氢原子2和3被解离; (b) STM电流引起的脱氢示意图; (c) 不同温度下CoPc和脱氢CoPc(d-CoPc)的dI/dV谱; (d) STM图像显示了连续尖端诱导的CoPc在Au(111)上的脱氢[48]
Figure 2. (a) Structural formula of the CoPc. Hydrogen atoms 2 and 3 of one lobe were dissociated in the experiments. (b) Diagram of the dehydrogenation induced by the STM current. (c) dI/dV spectra of CoPc and dehydrogenated CoPc (d-CoPc) at different temperatures. (d) STM images showing the sequential tip-induced dehydrogenation of a CoPc on Au(111)[48].
图 3 结合溶液和表面合成chGNRs的方法 (a)—(d) 溶液法合成不同原子宽度3, 1, w-chGNRs的分子前驱体1, 2, 3和3, 2, 8-chGNRs的前驱体4; (e)—(h) 利用4种分子前驱体分别靶向chGNRs的化学结构; (i)—(l) 在Au(111)表面合成chGNRs 的STM图像[59]
Figure 3. Synthetic strategy to produce chGNRs combining solution and on-surface synthesis: (a)–(d) Solution synthesis protocols for producing molecular precursors 1, 2, 3, for the synthesis of 3, 1, w-chGNRs with different widths, and precursor 4 for 3, 2, 8-chGNRs; (e)–(h) targeted chemical structures of chGNRs by using the four molecular precursors in (a)–(d), respectively; (i)–(l) STM overview images of the chGNRs formed on a Au(111) surface[59].
图 4 (a) 诱导分子链发光的STML示意图[84]; (b) 多达12个单体ZnPc分子链的STM形貌图, 不同分子链的典型STML谱, ZnPc链超辐射态的实验光子图像[84]; (c) 不同长度的分子链光子发射的二阶相关函数测量结果[84]; (d) STM诱导的单分子发光示意图, 右边是分子结构的俯视图; 不同偏置电压下单个H2Pc分子的电致发光光谱; 恒定电流下Qx峰的归一化偏置电压和光强依赖关系图, 对数图在插图中[83].
Figure 4. (a) Schematic of STML from ZnPc molecular chains[84]. (b) STM images of ZnPc molecular chains of up to 12 monomers, typical STML spectrum of different molecular chains, experimental photon images for the superradiant states of the ZnPc chains[84]. (c) Second-order correlation functions
$ {g}^{\left(2\right)}\left(\tau \right) $ for different ZnPc chains[84]. (d) Schematic of the STM-induced single-molecule emission. A top view of the molecular structure is given on the right. Electroluminescence spectra from a single H2Pc molecule at different bias voltages. Normalized bias-dependent intensity of the Qx peak at a constant current, with the logarithmic plot shown in the inset[83]
图 5 (a) 针尖增强光致发光实验模型[85]; (b) ZnPC分子的STM图(左)和光子图(右)[85]; (c) 在光子图像(b)中虚白线AB的光子强度侧面图[85]; (d) STM-PL 实验示意图[86]; (e) H2Pc 分子的放大 STM 图, STM 图(左)中的圆圈显示的是光谱测量时针尖的位置, 其颜色与相应光谱的颜色匹配[86].
Figure 5. (a) Schematic of the experimental of Sub-nanometre-resolved single-molecule TEPL[85]; (b) simultaneously recorded STM image (left) and TEPL photon image (right) of a single ZnPc molecule [85]; (c) photon intensity profile for the dashed white line AB in the photon image in b (right)[85]; (d) schematic depiction of STM-PL measurement[86]; (e) a magnified STM image of a H2Pc molecule, and the measurement tip positions for the spectra shown in STM image (left)are indicated with circles whose color matches that of the corresponding spectrum[86].
图 6 Au(111)上 (a) MnPc和 (b) H-MnPc的STM图像; (c) 由H原子吸附和解吸引起的MnPc分子中心记录的dI/dV谱的连续变化; (d) MnPc近藤特征在磁场下的演化[101]
Figure 6. STM images of (a) MnPc and (b) H-MnPc on Au(111); (c) sequential variations of dI/dV spectra recorded at the center of a MnPc molecule induced by the adsorption and desorption of a H atom; (d) magnetic-field evolution of the Kondo feature of MnPc[101].
图 7 (a) 在 Au(111) 上的 TbPc2 分子的叶瓣上和中心处记录的 dI/dV谱. 插图: 组装结构中 TbPc2 分子的 STM 图像. (b) θ = 45°和θ = 30°的TbPc2分子的示意图和STM图像. (c) 在应用尖端脉冲之前和之后在 TbPc2 分子处获得的 dI/dV谱[102].
Figure 7. (a) dI/dV spectra recorded at the lobe and center of a TbPc2 molecule on Au(111). Inset: STM image of TbPc2 molecules in the assembled structure. (b) Schematic illustrations and STM images of TbPc2 molecules with θ = 45° and θ = 30°. (c) dI/dV spectra acquired at a TbPc2 molecule before and after the application of a tip pulse[102].
图 8 (a) H2Pc和Al共沉积后的2个分子的化学结构模型和STM图. STM图左上角和右下角的分子分别是H2Pc和AlPc. (b) 将尖端置于AlPc瓣(黑色)、AlPc的Al中心(蓝色)和H2Pc瓣上方(黄色)得到的谱. (c) ClAlPc 的 STM 形貌图. (d) ClAlPc 瓣的 dI/dV谱. 蓝色: Cl 向上, 绿色: Cl 向下[106].
Figure 8. (a) Chemical structure model and STM map of two molecules after co-deposition of H2Pc and Al. The top-left and bottom-right molecules of the STM image are H2Pc and AlPc, respectively. (b) Spectra taken with the tip placed above a lobe of AlPc (black dots), the Al center of AlPc (blue), and a lobe of H2Pc (yellow). (c) STM topograph of ClAlPc. (d) dI/dV spectra of a lobe of ClAlPc. Blue: Cl-up, green: Cl-down[106].
图 9 (a) 和 (b) 为组态I和II的 FePc分子STM图像, 分别显示组态II的“交叉”相对于组态I的分子中心旋转15° ; (c) 通过正常W端在构型I和II FePc分子上获得的dI/dV谱, 显示分子2种构型的电子状态显著不同; (d)通过超导Nb针尖在构型I和II FePc分子上获得的dI/dV谱; (e) Nb-绝缘体-FePc-Au隧道结结构以及其典型的dI/dV谱, 显示了Kondo特征峰; (f) Nb-FePc-绝缘体-Au隧道结结构, 以及其典型的dI/dV谱, 显示了2个间隙内YSR态[108]
Figure 9. (a) and (b) Typical STM images of configuration I and II FePc molecules, respectively, showing the “cross” of configuration II rotates with respect to the molecular center by 15° compared with configuration I; (c) dI/dV spectra obtained on configuration I and II FePc molecules by a normal W tip, showing strikingly different electron states for the two configurations of the molecule; (d) dI/dV spectra obtained on configuration I and II FePc molecules by a superconducting Nb tip; (e) typical dI/dV spectra in a Nb-insulator-FePc-Au tunneling junction, showing a Kondo dip; (f) typical dI/dV spectra in a Nb-FePc-insulator-Au tunneling junction, showing two in-gap YSR states[108].
图 10 直线型边缘扩展的AGNR异质结构超晶格中的拓扑态 (a)化学结构和nc-AFM图像; (b)计算的能带结构; (c)直线型边缘扩展 AGNR 异质结构超晶格的局域态密度(LDOS)图 [122]
Figure 10. Topological states in in-line edge-extended AGNR heterostructure superlattices: (a) The chemical structure and nc-AFM image; (b) the calculated band structure; (c) the local density of states (LDOS) maps of an in-line edge-extended AGNR heterostructure superlattice[122].
图 11 7—9 AGNR超晶格的拓扑态 (a) 化学结构模型以及不同结构的拓扑指数和高分辨率的STM图像; (b) 计算的石墨烯纳米带能带结构; (c) 7—9 AGNR超晶格的理论计算LDOS图以及对应的实验dI/dV 图[123]
Figure 11. Topological states in a 7–9 AGNR superlattice: (a) The chemical structure and high-resolution STM image; (b) the calculated band structure; (c) the LDOS maps and corresponding experimental dI/dV diagram of a 7–9 AGNR superlattice[123].
图 12 (a) 3种石墨烯纳米结的DFT理论模拟. (b), (c) 分别为类型 1 和类型 2 结上明亮区域的近藤共振. 零偏置峰值主要在类型 1 结的4个 PC 环和类型 2 结的3个 ZZ 环上被检测到. (d) 类型 3 结上零偏压附近的双峰特征. (e) 具有额外 H 原子2个结的STM图. (f) 在电子诱导去除额外的 H 原子后STM图. (g), (h) 在脱氢过程之前(黑色)和之后(蓝色)的 PC1 和 ZZ2 区域的dI/dV谱. (g)中的插图显示了脱氢过程中的电流变化[124]
Figure 12. (a) DFT theoretical simulation of three graphene nanojunctions. (b), (c) Kondo resonances over the bright regions of Type 1 and Type 2 junctions, respectively. The zero-bias peaks are mostly detected over four PC rings of Type 1 junctions and over three ZZ rings of Type 2 junctions. (d) Double-peak features around zero bias over Type 3 junctions. (e) STM image of two junctions with extra H atoms. (f) STM image after the removal of extra H atoms induced by electrons. (g), (h) The PC1 and ZZ2 regions of the dI/dV spectrum before (black) and after (blue) the dehydrogenation process. The inset in (g) shows the current during the dehydrogenation process [124].
图 13 (a), (b) N = 16 开放三角烯链(oTSC)和闭合三角烯环(cTSC) 的高分辨率 STM 图; (c) 在N = 16 oTSC和cTSC的每个单元上获得的dI/dV谱; (d) N = 6 oTSC和cTSC的价键固态自旋态, 占oTSC中S = 1/2边缘态, 而cTSC中没有; (e) 对于N = 2—16的oTSC, 由BLBQ模型ED 计算的自旋激发能量[125]
Figure 13. (a), (b) High-resolution STM images of N = 16 oTSC (a) and cTSC (b); (c) dI/dV spectra acquired on every unit of the N = 16 oTSC (a) and cTSC (b); (d) the valence bond solid spin state for N = 6 oTSC and cTSC, accounting for S = 1/2 edge states in the oTSC and their absence in the cTSC; (e) For oTSC with N = 2–16, the spin excitation energy calculated from the ED of the BLBQ model[125].
图 14 (a) 在插图图像中彩色数字标记位置做的 dI/dV 谱. (b) 磁交换作用是每个单元中自旋密度最大的2个碳原子之间距离的函数. 插图为6种不同f-NG二聚体的自旋密度分布. 所有二聚体都呈现单线态基态. 蓝色和红色等表面表示自旋向上和自旋向下的密度. (c) 实验观察到4种命名为 C1—C4 的 f-NG 二聚体构型. 左侧, nc-AFM 图; 中间, 恒高的STM图, 右侧, 模拟 STM 图. (d) 在 (c) 中标记的位置做的 dI/dV 谱[126].
Figure 14. (a) dI/dV spectra taken at the positions marked by colored numbers in the inset current image. (b) The magnetic exchange interaction J as a function of the distance between two carbon atoms with the strongest spin density in each unit. Inset: spin density distribution of six different f-NG dimers. All dimers exhibit a singlet ground state. Blue and red isosurfaces denote spin up and spin down density. (c) Experimental observed four configurations of f-NG dimers named as C1–C4. Left, nc-AFM frequency shift image; middle, constant-height current image; right, simulated STM image. (d) dI/dV spectra taken at the positions marked in (c)[126].
Termination type Zigzag
(N = Odd)Zigzag′
(N = Odd)Zigzag
(N = Even)Bearded
(N = Even)Unit cell shape 
Bulk symmetry Inversion/mirror Inversion/mirror Mirror Inversion Z2 $\frac{1+{\left(-1\right)}^{\left\lfloor {\tfrac{N}{3} } \right\rfloor+\left\lfloor {\tfrac{N+1}{2} } \right\rfloor} }{2}$ $\frac{1-{\left(-1\right)}^{\left\lfloor {\tfrac{N}{3} } \right\rfloor+\left\lfloor {\tfrac{N+1}{2} } \right\rfloor} }{2}$ $\frac{1-{\left(-1\right)}^{\left\lfloor {\tfrac{N}{3} } \right\rfloor} }{2}$ 
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