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Ç°Á½ÌìºÍÅóÓÑÁÄÌì¹ý³ÌÖУ¬ÎÞÒâ¼ä·¢ÏÖ½ñÄê¸÷ÀàÔÓÖ¾ÉϹØÓÚInPµÄÎÄÕÂÈçÓêºó´ºËñ°ãÓ¿ÏÖ¡£µ±Ö®ÎÞÀ¢¿ÉÒÔ³ÆΪÁ¿×Óµã½çµÄÍøºì¡£InP QDsµÄ¸÷ÖÖÓÅÊÆÒѾÔÚÉÏһƪÏà¹Ø·ÖÏíÖÐÁгö£¨InPÁ¿×ÓµãºÏ³ÉÏà¹ØÎÄÏ××ܽáÓë·ÖÎö£©¡£×ܽáΪһ¾ä»°£ºInPÊÇ×îÓпÉÄÜÈ¡´úº¬CdÁ¿×Óµã¶ø×ßÏòÓ¦ÓõIJÄÁÏ¡£ Ê×ÏÈ´Ó½üÆÚCMÉϵÄһƪ×ÛÊö¿ªÊ¼¡£×¨ÃÅÕë¶ÔInP²ÄÁϵÄ×ÛÊöºÜÉÙ¼û£¬×î½ü¸üеÄÕâƪ×ÛÊö½ÏΪȫÃæµÄ½éÉÜÁËInPÁ¿×ÓµãµÄÑо¿½øÕ¹¡£  Chemically synthesized InP nanocrystals (NCs) are drawing a large interest as a potentially less toxic alternative to CdSe-based nanocrystals. With a bulk band gap of 1.35 eV and an exciton Bohr radius of ¡«10 nm the emission wavelength of InP NCs can in principle be tuned throughout the whole visible and near-infrared range by changing their size. Furthermore, a few works reported fluorescence quantum yields exceeding 70% after overcoating the core NCs with appropriate shell materials. Therefore, InP NCs arevery promising for use in lighting and display applications. On the other hand, a number of challenges remain to be addressed in order to progress from isolated research results to robust and reproducible synthesis methods for high quality InP NCs. First of all, the size distribution of the as-synthesized NCs needs to be reduced, which directly translates into more narrow emission line widths. Next, reliable protocols are required for achieving a given emission wavelength at high reaction yield and for further improving the emission efficiency and chemical and photostability. Advances in these directions have been hampered for a long time by the specific properties of InP, such as the rather covalent nature of binding implying harsh synthesis conditions, high sensitivity toward oxidation, and limited choice of phosphorus precursors. However, in recent years a much better understanding of the precursor conversion kinetics and reaction mechanisms has been achieved, giving this field new impulse. In this review we provide a comprehensive overview from initial synthetic approaches to the most recent developments. First, we highlight the fundamental differences in the syntheses of InP-based NCs with respect to established II¨CVI and IV¨CVI semiconductor NCs comparing their nucleation and growth stages. Next, we inspect in detail the influence of the nature of the phosphorus and indium precursors used and of reaction additives, such as zinc carboxylates or alkylamines, on the properties of the NCs. Finally, core/shell systems and doped InP NCs are discussed, and perspectives in this field are given.  ÎÄÖÐÊ×ÏȽéÉÜÁËInP QDsºÏ³É·½·¨µÄ·¢Õ¹Àú³ÌÒÔ¼°·´Ó¦»úÀí¡£½ô½Ó׎éÉܾµäµÄ³ÉºËÓëÉú³¤»úÀí¡£»ù±¾·¢Õ¹¹ý³ÌºÍ»ù±¾»úÀí½éÉÜÍê³Éºó£¬×÷Õß·ÖÀà×ܽáÁËP Ç°Ìå¡¢InÇ°Ìå¡¢ÅäÌåÒÔ¼°Ìí¼Ó¼ÁÔÚInP QDsºÏ³ÉÖеÄ×÷ÓᣳýÁ˵¥´¿µÄInPQDsµÄºÏ³É£¬ÎÄÖкó°ë²¿·ÖÖصã½éÉÜInP/ZnSºË¿Ç½á¹¹Á¿×ÓµãµÄºÏ³ÉºÍInPµÄ²ôÔÓ¡£  Wet chemical synthesis of covalent III-V colloidal quantum dots (CQDs) has been challenging because of uncontrolled surfaces and a poor understanding of surface¨Cligand interactions. We report a simple acid-free approach to synthesize highly crystalline indium phosphide CQDs in the unique tetrahedral shape by using tris(dimethylamino) phosphine and indium trichloride as the phosphorus and indium precursors, dissolved in oleylamine. Our chemical analyses indicate that both the oleylamine and chloride ligands participate in the stabilization of tetrahedral-shaped InP CQDs covered with cation-rich (111) facets. Based on density functional theory calculations, we propose that fractional dangling electrons of the In-rich (111) surface could be completely passivated by three halide and one primary amine ligands per the (2¡Á2) surface unit, satisfying the 8-electron rule. This halide¨Camine co-passivation strategy will benefit the synthesis of stable III-V CQDs with controlled surfaces.  ÕâƪAngewandeÊ״ᨵÀºÏ³É³öËÄÃæÌåInPÁ¿×ӵ㡣ÓйØÁ¿×ÓµãÐÎòµ÷¿ØµÄÎÄÏ׺ܶ࣬µ«ºÜÉÙÉæ¼°InP¡£±¾ÎÄͨ¹ýClºÍ°·ÕâÁ½ÖÖÅäÌåµÄÐͬ×÷Ó㬳ɹ¦ºÏ³É³öËÄÃæÌåInPÁ¿×ӵ㣬³ß´çÔÚ10nm×óÓÒ¡£Í¨¶ÁÈ«ÎÄ£¬·¢ÏÖ¸ÃÎĵÄÁÁµã²¢²»ÔÚÐÎòµÄ¿ØÖÆ¡£Ê×ÏÈÎÄÖÐÖ»ÊǺϳɳöÕâÒ»ÖÖÐÎòµÄInP£¬Æä´ÎûÓп¼²ìÆä³ÉºËÓëÉú³¤¹ý³Ì£¬»úÀí½âÊÍÒ²½ÏΪ¼òµ¥¡£¸öÈ˾õµÃÁÁµãÔÚÓÚÎÞËáÌåϵµÄÒýÈ룬ʵÏÖÁ˽ϺñZnS²ãµÄÉú³¤£¬´Ó¶øÌá¸ßInP/ZnSµÄÎȶ¨ÐÔ¡£ÒÑÓжàƪÎÄÏ×±¨µÀÔÚÓÐËá´æÔڵĺϳÉÌåϵÖУ¬ÎÞÂÛÊǵ¥´¿µÄInP CoreÁ¿×ӵ㣬»¹ÊÇInP/ZnSºË¿ÇÁ¿×ӵ㣬¶¼»áÓв¿·ÖInP±»Ñõ»¯£¬´Ó¶ø×è°InPµÄÉú³¤ºÍ°ü¿Ç¡£±¾ÎÄÑ¡ÔñÒÔInCl3×÷Ϊî÷Ô´£¬ClºÍÓÍ°·×÷ΪÅäÌ壬±ÜÃâÁËôÈËáÑκÍôÈËáµÄʹÓ㬴ӶøûÓÐInPOxµÄÉú³É¡£Í¨¹ý´Ë·½·¨£¬×îÖÕ¿ÉÒÔÔÚInP±íÃæÉú³¤½ü2nmµÄZnS£¬´Ó¶øÌá¸ß²ÄÁϵÄÎȶ¨ÐÔ¡£ ÉÏÃæÕâƪÎÄÏ×ͨ¹ýÒÖÖÆInPÑõ»¯´Ó¶øʵÏÖZnSµÄÓÐЧ³É¿Ç¡£InP/ZnSºË¿ÇÁ¿×ÓµãÄÑÒԺϳɵÄÁíÍâÒ»¸öÔÒòÊÇÁ½Õߵľ§¸ñ²ÎÊýÏà²î´ó¡£½â¾ö¾§¸ñʧÅäµÄ·½·¨ÓÐÁ½ÖÖ£ºÒ»ÊÇÒýÈë¹ý¶É²ã£»¶þÊÇÐγɺϽð¡£ÏÂÃæÕâƪÎÄÏ×ÖУ¬×÷ÕߺϳɳöInZnPxºÏ½ð£¬Í¨¹ý¿ØÖÆZnµÄº¬Á¿£¬¿ÉÒÔʵÏÖ¾§¸ñ²ÎÊýµÄµ÷¿Ø¡£  Colloidal quantum dots (QDs) show great promise as LED phosphors due to their tunable narrow-band emission and ability to produce high-quality white light. Currently, the most suitable QDs for lighting applications are based on cadmium, which presents a toxicity problem for consumer applications. The most promising cadmium-free candidate QDs are based on InP, but their quality lags much behind that of cadmium based QDs. This is not only because the synthesis of InP QDs is more challenging than that of Cd-based QDs, but also because the large lattice parameter of InP makes it difficult to grow an epitaxial, defect-free shell on top of such material. Here, we propose a viable approach to overcome this problem by alloying InP nanocrystals with Zn2+ ions, which enables the synthesis of InxZnyP alloy QDs having lattice constant that can be tuned from 5.93 Å (pure InP QDs) down to 5.39 Å by simply varying the concentration of the Zn precursor. This lattice engineering allows for subsequent strain-free, epitaxial growth of a ZnSezS1¨Cz shell with lattice parameters matching that of the core. We demonstrate, for a wide range of core and shell compositions (i.e., varying x, y, and z), that the photoluminescence quantum yield is maximal (up to 60%) when lattice mismatch is minimal.  ÔÚ°ü¿Çʱ£¬Í¬Ñù¿ÉÒÔͨ¹ýµ÷½ÚSµÄº¬Á¿À´¿ØÖÆZnSeSx¾§¸ñ²ÎÊý¡£×îÖÕ£¬×÷Õß½«Á¿×Ó²úÂÊÓëºË¿Ç¾§¸ñÆ¥Åä¶È¹ØÁª£¨ÈçÏÂͼ£©£¬·¢ÏÖ¾§¸ñÆ¥Åä¶ÈÔ½¸ß£¬ÆäQYÔ½¸ß¡£   Magic-sized nanoclusters have been implicated as mechanistically relevant intermediates in the synthesis of group III-V quantum dots. Herein we report the single-crystal X-ray diffraction structure of a carboxylate-ligated indium phosphide magic-sized nanocluster at 0.83 Å resolution. The structure of this cluster, In37P20(O2CR)51, deviates from that of known crystal phases and possesses a non-stoichiometric, charged core composed of a series of fused 6-membered rings. The cluster is completely passivated by bidentate carboxylate ligands exhibiting predominantly bridging binding modes. The absorption spectrum of the cluster shows an asymmetric line shape that is broader than what would be expected from a homogeneous sample. A combination of computational and experimental evidence suggests that the spectral line width is a result of multiple, discrete electronic transitions that couple to vibrations of the nanocrystal lattice. The product of reaction of this nanocluster with 1 equiv of water has also been structurally characterized, demonstrating site selectivity without a drastic alteration of electronic structure.  ÕâƪJACsµÄÁÁµãÔÚÓÚ¶ÔInP ClusterµÄ±íÕ÷¡£ÎÄÕÂÀ´×ÔÓÚCossairt¿ÎÌâ×é¡£¸Ã¿ÎÌâ×é×öÁË´óÁ¿¹ØÓÚInPºÏ³É·½ÃæµÄ¹¤×÷¡£ÔÚInPÁ¿×ÓµãºÏ³É¹ý³ÌÖУ¬ClusterµÄÐγÉËƺõ²»¿É±ÜÃ⣬ÉõÖÁ¿ÉÒÔ´Ödz½«ClusterÀí½âΪһÖÖÖмä̬¡£±¾ÎÄͨ¹ýµ¥¾§ÑÜÉ䣬×ÐϸÑо¿ÁËInPClusterµÄ½á¹¹£¬·¢ÏÖÆäÓÉÁùÔ²»·×é³É£¬×é³É²¢·ÇÑϸñ»¯Ñ§¼ÆÁ¿±È¡£×ÛºÏʵÑé½á¹ûÓëÀíÂÛ¼ÆË㣬ÎÄÖÐÌá³öClusterµÄ¿í°ë°ë·å¿íÀ´×Ô¾§¸ñÕ𶯡£ ÁíÍâÔÚ¸½¼¸ÆªÎÄÏ×ÔÚ¸½¼þ¡£ |
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±¾ÄÚÈÝÓÉÓû§×ÔÖ÷·¢²¼£¬Èç¹ûÆäÄÚÈÝÉæ¼°µ½ÖªÊ¶²úȨÎÊÌ⣬ÆäÔðÈÎÔÚÓÚÓû§±¾ÈË£¬Èç¶Ô°æȨÓÐÒìÒ飬ÇëÁªÏµÓÊÏ䣺libolin3@tal.com - ¸½¼þ 1 : Chemistry_of_InP_nanocrystal_syntheses.pdf
- ¸½¼þ 2 : Halide¨CAmine_Co-Passivated_Indium_Phosphide_Colloidal_Quantum_Dots_in_Tetrahedral_Shape.pdf
- ¸½¼þ 3 : Single-Crystal_and_Electronic_Structure_of_a_1.3_nm_Indium_Phosphide_Nanocluster.pdf
- ¸½¼þ 4 : Tuning_the_Lattice_Parameter_of_InxZnyP_for_Highly_Luminescent_Lattice-Matched_Core-Shell_Quantum_Dots.pdf
- ¸½¼þ 5 : Band-Edge_Exciton_Fine_Structure_and_Recombination_Dynamics_in_InP-ZnS_Colloidal_Nanocrystals.pdf
- ¸½¼þ 6 : Direct_Observation_of_Early-Stage_Quantum_Dot_Growth_Mechanisms_with_High-Temperature_Ab_Initio_Molecular_Dynamics.pdf
- ¸½¼þ 7 : Luminescent_InP_Quantum_Dots_with_Tunable_Emission_by_PostSynthetic_Modification_with_Lewis_Acids.pdf
2016-04-21 16:42:07, 895.2 K
2016-04-21 16:42:09, 2.91 M
2016-04-21 16:42:10, 1.04 M
2016-04-21 16:42:13, 2.66 M
2016-04-21 16:43:12, 2.48 M
2016-04-21 16:43:14, 1.72 M
2016-04-21 16:43:16, 2.53 M
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