Co-reporter:Yueguang Chen; Shu Zhao; Xian Wang; Qing Peng; Rui Lin; Yu Wang; Rongan Shen; Xing Cao; Libo Zhang; Gang Zhou; Jun Li; Andong Xia;Yadong Li
Journal of the American Chemical Society 2016 Volume 138(Issue 13) pp:4286-4289
Publication Date(Web):March 21, 2016
DOI:10.1021/jacs.5b12666
In this Communication, we present the integration of synergetic designs into high-quality, well-defined Cu1.94S–ZnxCd1–xS heteronanorods (0 ≤ x ≤ 1) for enhanced photocatalytic hydrogen evolution. These heteronanorods possess two light absorbers, intimate heterointerfaces, tunable band gaps over a wide range, and uniform one-dimensional morphology. As verified by experimental and density functional theory studies, these heteronanorods with continuous composition adjustment fully exploit the benefits of both interfacial charge separation and optimized band alignments. Even without any cocatalysts, Cu1.94S–Zn0.23Cd0.77S heteronanorods exhibit efficient hydrogen production activity (7735 μmol h–1 g–1) under visible-light irradiation (λ > 420 nm), representing a 59-fold enhancement compared with the pristine CdS catalyst. Meanwhile, deposition of a Pt cocatalyst on the Cu1.94S–ZnxCd1–xS surface substantially enhances the hydrogen production performance (13 533 μmol h–1 g–1) with an apparent quantum efficiency of 26.4% at 420 nm, opening up opportunities to promote the overall photocatalytic performance using rationally designed nanostructures.
Co-reporter:Yueguang Chen;Zhanjun Yu;Zheng Chen;Rongan Shen;Yu Wang;Xing Cao
Nano Research 2016 Volume 9( Issue 9) pp:2632-2640
Publication Date(Web):2016 September
DOI:10.1007/s12274-016-1150-6
RuCu nanocages and core–shell Cu@Ru nanocrystals with ultrathin Ru shells were first synthesized by a one-pot modified galvanic replacement reaction. The construction of bimetallic nanocrystals with fully exposed precious atoms and a high surface area effectively realizes the concept of high atom-efficiency. Compared with the monometallic Ru/C catalyst, both the RuCu nanocages and Cu@Ru core–shell catalysts supported on commercial carbon show superior catalytic performance for the regioselective hydrogenation of quinoline toward 1,2,3,4-tetrahydroquinoline. RuCu nanocages exhibit the highest activity, achieving up to 99.6% conversion of quinoline and 100% selectivity toward 1,2,3,4-tetrahydroquinoline.
Co-reporter:Yu Wang;Yueguang Chen;Caiyun Nan;Lingling Li;Dingsheng Wang
Nano Research 2015 Volume 8( Issue 1) pp:140-155
Publication Date(Web):2015 January
DOI:10.1007/s12274-014-0603-z
Co-reporter:Yunxin Liu, Dingsheng Wang, Lingling Li, Qing Peng, and Yadong Li
Inorganic Chemistry 2014 Volume 53(Issue 7) pp:3257-3259
Publication Date(Web):March 27, 2014
DOI:10.1021/ic403091w
Here, we report upconversion nanoparticles with a core/porous-shell structure in which bulk emission and nanoemission are simultaneously observed. The activated porous shell can efficiently tune the bulk emission but has negligible influence on the nanoemission.
Co-reporter:Dingsheng Wang, Xiaoyang Li, Hao Li, Linsen Li, Xun Hong, Qing Peng and Yadong Li
Journal of Materials Chemistry A 2013 vol. 1(Issue 5) pp:1587-1590
Publication Date(Web):16 Nov 2012
DOI:10.1039/C2TA00765G
We exploited a new approach to prepare nanocomposites of semiconductor and noble metal via reaction between sulfur and bimetallic nanocrystals in ODA solvent. Various nanostructures including core–shell, porous, and heterostructure can be prepared, depending on the structure of bimetallic nanocrystals. For example, core–shell (the shell metal reacts with sulfur) bimetallic nanocrystals lead to the formation of core (noble metal)–shell (semiconductor) hybrid nanocrystals (CoxS@Au); intermetallic and alloyed nanocrystals lead to the formation of porous noble metal–semiconductor nanocrystals (CoxS–Pt); core–shell (the core metal reacts with sulfur) bimetallic nanocrystals lead to the formation of hollow noble metal–solid semiconductor heterostructured nanocrystals (Pt–Ag2S). This approach provides a general and excellent way to produce hybrid nanomaterials.
Co-reporter:Jun Lu, Qing Peng, Zhongying Wang, Caiyun Nan, Lihong Li and Yadong Li
Journal of Materials Chemistry A 2013 vol. 1(Issue 17) pp:5232-5237
Publication Date(Web):20 Feb 2013
DOI:10.1039/C3TA01539D
27 nm thick hematite nanodiscs have been prepared by a facile solvothermal method. The growth of Fe2O3 nanodiscs follows the precipitation–dissolution–growth mechanism, and the (001) facets are preferentially exposed since (001) facets are the densest and therefore most stable facets. In particular, outstanding rate and cycling capabilities have been demonstrated for the nanodiscs due to the reduced Li+ diffusion distance and enhanced reactivity of the nanosized structures.
Co-reporter:Peng Li, Dingsheng Wang, Qing Peng, and Yadong Li
Crystal Growth & Design 2013 Volume 13(Issue 5) pp:1949-1954
Publication Date(Web):March 19, 2013
DOI:10.1021/cg301834x
We report a general and efficient strategy to produce monodisperse transition-metal (Mn, Co, and Ni) hydroxide nanoplates with tunable composition through the interface-mediated growth process. It is worth noting that, using common nitrates as the precursors, the as-obtained nanoplates were prepared under hydrothermal conditions. Moreover, the possible formation mechanism of the transition-metal hydroxide nanoplates has also been investigated. Subsequently, the resulting transition-metal hydroxides can be eventually transformed into transition-metal oxide nanoplates and lithium-ion intercalation materials through solid-state reactions, respectively. Furthermore, the electrochemical properties of the resulting nanomaterials have also been discussed in detail. This protocol may be easily extended to fabricate many other metal hydroxide and oxide nanomaterials.
Co-reporter:Yunxin Liu, Shiping Zhan, Jianxin Shi, Qing Peng and Yadong Li
RSC Advances 2013 vol. 3(Issue 41) pp:18894-18899
Publication Date(Web):17 Jul 2013
DOI:10.1039/C3RA42427H
Beyond the superlattices, there are few other intricate superstructures that have been successfully assembled on a 2D substrate from nanocrystal building blocks. Here, we show the direct assembly of oleic acid-capped TiO2 nanocrystals into nanotube networks with good connectivity on 2D substrates. The assembly process was controlled by ethanol vapor. A combination of theoretical calculations and experimental data demonstrates a non-spontaneous assembly process with solvent vapour–ligand interactions, which is in agreement with the experimental results, but different from the widely reported nanocrystal superlattice assembly driven by entropy or enthalpy. From FT-IR spectra, we determined the occurrence of the solvent–ligand interaction; the oleic acid ligands of TiO2 nanocrystals transform into ethyl oleate due to the esterification of oleic acid by ethanol vapor, which may play a main role in driving the assembly process. Changing ethanol to tetrahydrofuran vapor prevented generation of nanotube-network structures, supplying indirect proof for this theory.
Co-reporter:Caiyun Nan;Jun Lu;Lihong Li;Lingling Li;Yadong Li
Nano Research 2013 Volume 6( Issue 7) pp:469-477
Publication Date(Web):2013 July
DOI:10.1007/s12274-013-0324-8
Co-reporter:Dr. Yunxin Liu;Jianxin Shi;Dr. Qing Peng;Dr. Yadong Li
Chemistry - A European Journal 2013 Volume 19( Issue 13) pp:4319-4326
Publication Date(Web):
DOI:10.1002/chem.201203316
Abstract
How to extend ultraviolet photocatalysts to the visible-light region is a key challenge for solar-driven photocatalysis. Herein, we show that ultraviolet ZnO photocatalysts can present high visible-light photocatalytic activity when combined with CuO quantum dots (QDs; <3 nm). Theoretical analysis demonstrates that the quantum size effect plays a key role in the photoactivity of the CuO/ZnO composite. For CuO QDs smaller than 3 nm, the separated charges could transfer from CuO QDs to the conduction bands of ZnO due to quantum splitting of the CuO energy level and phonon compensation for the difference in the conduction band minimum of CuO and ZnO; however, this process would not occur with the disappearance of the quantum size effect. Further structural analysis demonstrates that interfacial charge separation and transfer between ZnO and CuO dominate the photocatalytic processes instead of a single CuO or ZnO surface. Compared with ZnOnoble metal structures (e.g., ZnOAg or ZnOAu), these ZnOCuO QD composites present wider absorption bands, higher visible photocatalytic efficiencies, and lower costs.
Co-reporter:Dr. Peng Li;Dr. Dingsheng Wang;Zhe Wei;Dr. Qing Peng;Dr. Yadong Li
Chemistry - A European Journal 2013 Volume 19( Issue 11) pp:3735-3740
Publication Date(Web):
DOI:10.1002/chem.201203730
Abstract
In this study, we report a simple solution-phase method to prepare ZnO nanostructures with controllable morphologies. By using oleylamine (OAm) and dodecanol (DDL) as solvents, zinc oxide nanocrystals with tunable sizes and diverse shapes (hexagonal pyramids, bulletlike, and pencil-like shapes) have been obtained under mild conditions. At the same time, the introduction of presynthesized gold nanocrystals can also lead to the hybrid nanostructures of gold–zinc oxide hexagonal nanopyramids. In addition, the possible formation mechanism of the as-prepared ZnO nanostructures has been investigated. Notably, the unique optical properties of the ZnO nanostructures with different sizes and shapes have also been discussed. We hope that this strategy will be a general and effective method for fabricating other metal oxide nanocrystals.
Co-reporter:Jun Lu;Caiyun Nan;Lihong Li;Yadong Li
Nano Research 2013 Volume 6( Issue 1) pp:55-64
Publication Date(Web):2013 January
DOI:10.1007/s12274-012-0281-7
Co-reporter:Yunxin Liu, Jianxin Shi, Qing Peng and Yadong Li
Journal of Materials Chemistry A 2012 vol. 22(Issue 14) pp:6539-6541
Publication Date(Web):02 Mar 2012
DOI:10.1039/C2JM16729H
ZnO nanocrystals of ∼4.7 nm were self-assembled into three dimensional nanoporous pyramids by oriented attachment with high selective adsorption and photocatalytic activity.
Co-reporter:Lihong Li, Caiyun Nan, Jun Lu, Qing Peng and Yadong Li
Chemical Communications 2012 vol. 48(Issue 55) pp:6945-6947
Publication Date(Web):21 May 2012
DOI:10.1039/C2CC32306K
A simple one-step route for preparing α-MnO2 nanotubes is reported. The α-MnO2 nanotubes exhibit a high surface area of 226 m2 g−1 and reversible capacity of 512 mA h g−1 at a high current density of 800 mA g−1 after 300 cycles, as well as cycling stability when measured as an anode in lithium batteries.
Co-reporter:Zhongbin Zhuang, Qing Peng and Yadong Li
Chemical Society Reviews 2011 vol. 40(Issue 11) pp:5492-5513
Publication Date(Web):15 Aug 2011
DOI:10.1039/C1CS15095B
The microstructure (composition, size and shape etc.) of semiconductor nanocrystals determine the electronic density of states of semiconductor nanomaterials and ultimately determine their optical and electrical properties. Semiconductor nanocrystal advanced structures, such as hybrid nanostructures and nanocrystal superlattices, not only integrate the function of individual nanocrystals, but also brings the materials collective and synchronic properties. How to control the monodispersity, composition and structure of as-prepared semiconductor nanocrystals during their syntheses, as well as their furthermore assembly, has been a hot research area in this decade. This critical review focuses on the development of synthetic and assembly methods (techniques) of semiconductor nanocrystals processed in the liquid phase. Emphasis is on the synthesis methodology, microstructure related properties of semiconductor nanocrystals, and their applications (243 references).
Co-reporter:Xiaotang Lu, Zhongbin Zhuang, Qing Peng and Yadong Li
Chemical Communications 2011 vol. 47(Issue 11) pp:3141-3143
Publication Date(Web):26 Jan 2011
DOI:10.1039/C0CC05064D
A new wurtzite phase Cu2ZnSnS4 was discovered and the corresponding nanocrystals have been successfully synthesized. They have been characterized in detail and showed the photoelectric response, which demonstrated their potential in the application of photovoltaic devices.
Co-reporter:Yunxin Liu ; Dingsheng Wang ; Qing Peng ; Deren Chu ; Xiangwen Liu ;Yadong Li
Inorganic Chemistry 2011 Volume 50(Issue 12) pp:5841-5847
Publication Date(Web):May 24, 2011
DOI:10.1021/ic2009013
Mesoporous materials have found a great number of important utilities due to their well-defined pore structure and high internal surface area, which are routinely synthesized with the assistance of block copolymers or templates. So far, a key challenge is how to assemble directly ligand-free inorganic nanocrystals into mesoporous structures, so that the high surface activity of ligand-free nanocrystals is not destroyed by further treatment to remove organic species or templates. In this paper, we report the direct assembly of highly uniform ZnO mesoporous ellipsoids from ligand-free ZnO nanocrystals of ∼5 nm. The size of the synthesized uniform ZnO mesoporous ellipsoids can be efficiently tuned from 132 × 75 to 190 × 111 nm (length × width), by varying the size and concentration of primary ZnO nanocrystal building blocks and the composition of the designed assembling solvent. The BET detection indicates that these ZnO mesoporous ellipsoids have high specific surface areas reaching to 136.57 m2/g, while their average BJH pore diameters are located at 8.8 nm. Especially, the high-resolution TEM images and XRD analysis revealed the occurrence of an oriented attachment mechanism in the assembly of uniform ZnO mesoporous ellipsoids, which supplied an important proof for the possibility of constructing stable three-dimensional structures by oriented attachment. The benefits of these ZnO mesoporous ellipsoids were demonstrated by their excellent photocatalytic activity under weak UV irradiation.
Co-reporter:Xiaotang Lu, Zhongbin Zhuang, Qing Peng and Yadong Li
CrystEngComm 2011 vol. 13(Issue 12) pp:4039-4045
Publication Date(Web):08 Feb 2011
DOI:10.1039/C0CE00451K
Wurtzite CuInS2 nanocrystals have been synthesized by direct reaction of copper nitrate, indium nitrate and dodecanethiol. The size and shape of the nanocrystals could be elaborately controlled by varying the Cu/In ratio and additional ligands other than dodecanethiol, such as oleylamine and oleic acid. Especially, the nanorods obtained under a Cu/In raw material ratio of 2:1 with the assistance of both dodecanethiol and oleic acid have good uniformity. They could further assemble into large-scale superlattices on substrates by solvent evaporation method. On the other hand, the optical property studies of the nanocrystals show that the band gap of wurtzite CuInS2 is 1.63 eV, which is optimal for solar cell applications. This report provides valuable insight into the controlled synthesis of ternary I-III-VI2 semiconductors and the assembly process, packing them into oriented films.
Co-reporter:Zhongbin Zhuang;Xiaotang Lu;Dr. Qing Peng; Yadong Li
Chemistry - A European Journal 2011 Volume 17( Issue 37) pp:10445-10452
Publication Date(Web):
DOI:10.1002/chem.201101145
Abstract
In this paper, we demonstrate a simple and general “dispersion–decomposition” approach to the synthesis of metal sulfide nanocrystals with the assistance of alkylthiol. This is a direct heating process without precursor injection. By using inorganic metal salts and alkylthiol as the raw materials, high-quality Ag2S, Cu2S, PbS, Ni3S4, CdS, and ZnS nanocrystals were successfully synthesized. The mechanism study shows that the reaction undergoes two steps. A key intermediate compound, metal thiolate, is generated first. It melts and disperses into the solvent at a relatively low temperature, and then it decomposes into metal sulfide as a single precursor upon heating. This method avoids using toxic phosphine agent and injection during the reaction process. The size and shape of the nanocrystal can be also controlled by the concentration of the reactant and ligands. Furthermore, the optical properties and assembly of the nanocrystals have also been studied. This report provides a facile, direct-heating “dispersion–decomposition” approach to synthesize metal sulfides nanocrystals that has potential for future large-scale synthesis.
Co-reporter:Zhongbin Zhuang ; Xiaotang Lu ; Qing Peng ;Yadong Li
Journal of the American Chemical Society 2010 Volume 132(Issue 6) pp:1819-1821
Publication Date(Web):January 26, 2010
DOI:10.1021/ja909776g
Highly water-soluble ultrathin and fluorescent CdS nanorods are directly synthesized with the assistance of PEI. PEI plays as the passivator to control and induce the growth of the CdS nanorods and also makes the as-obtained nanorods dispersible in water. The as-obtained CdS nanorods are quite thin thus showing the quantum effect in the fluorescence. By adjusting the alkalinity of the solution, CdS nanorods can be controlled to precipitate or redisperse in water, which is believed to stem from the variation of the charges of the capping PEI molecules. These results provide an efficient and convenient way to directly synthesize water-soluble and fluorescent nanocrystals, which has potential application in biological labeling and detection.
Co-reporter:L-r Meng, Ruofei Mo, Heping Zhou, Guofeng Wang, Wei Chen, Dingsheng Wang and Qing Peng
Crystal Growth & Design 2010 Volume 10(Issue 8) pp:3387-3390
Publication Date(Web):July 2, 2010
DOI:10.1021/cg9015417
Uniform cubic phase CuI nanowires and nanorods were synthesized via hydrothermal treatment. The mechanism of the nanostructure evolution is discussed on the basis of SEM and TEM experimental results. It is shown that the initial solution concentration and the reaction time influence the product morphology. Photoluminescence of CuI nanowires show a 2-fold enhancement over that of nanorods.
Co-reporter:Chen Chen, Chao Li, Qiao Su, Qing Peng
Materials Research Bulletin 2010 45(11) pp: 1762-1767
Publication Date(Web):
DOI:10.1016/j.materresbull.2010.06.032
Co-reporter:Chunhui Li, Jin Hu, Qing Peng, Xun Wang
Materials Chemistry and Physics 2008 Volume 110(Issue 1) pp:106-109
Publication Date(Web):15 July 2008
DOI:10.1016/j.matchemphys.2008.01.022
Nanocrystalline NiSb and NiSb2 have been prepared through a solvothermal co-reduction route at low temperatures (120–180 °C). The features of this method include: (1) the reactants are simple inorganic salts (NiCl2·6H2O and SbCl3); (2) two types of nickel antimonides (NiSb and NiSb2) can be obtained respectively by changing the reducing agents and temperatures. The as-prepared samples were characterized by XRD and TEM. A possible formation mechanism has been presented. The thermoelectric properties of as-prepared NiSb, and the magnetic properties of NiSb2 were investigated.
Co-reporter:Zhongbin Zhuang Dr.;Xun Wang Dr.;Yadong Li
Angewandte Chemie International Edition 2007 Volume 46(Issue 43) pp:
Publication Date(Web):20 SEP 2007
DOI:10.1002/anie.200701307
Perfectly faceted tetrahedral 3D superlattice crystals, which are built up of 3.5-nm Ag2S crystals, have been directly prepared through a simple one-step, two-phase reaction. The as-prepared nanocrystals assemble at the interface of water and dodecanethiol phases to form superlattice films, then break into triangular flakes, and finally stack to form tetrahedra; inset of TEM image: fast Fourier transform pattern of the superlattice (SL).
Co-reporter:Zhongbin Zhuang Dr.;Xun Wang Dr.;Yadong Li
Angewandte Chemie 2007 Volume 119(Issue 43) pp:
Publication Date(Web):20 SEP 2007
DOI:10.1002/ange.200701307
Perfekte Flächen sind das Kennzeichen tetraedrischer 3D-Übergitter aus 3.5 nm großen Ag2S-Kristallen, die direkt in einer Zweiphasenreaktion entstehen. Die erhaltenen Nanokristalle könnten dabei an der Grenzfläche zwischen Wasser- und Dodecanthiolphase Filme bilden, die dann in dreieckige Teilchen aufbrechen, aus denen schließlich die Tetraeder aufgebaut werden (siehe TEM-Bilder und Modell; Einschub: Muster der schnellen Fourier-Transformation für das Übergitter (SL)).
Co-reporter:Zhongbin Zhuang Dr.;Jing Zhuang;Xun Wang Dr.;Yadong Li
Chemistry - A European Journal 2006 Volume 12(Issue 1) pp:
Publication Date(Web):31 OCT 2005
DOI:10.1002/chem.200500724
A series of nickel selenides (NiSe2 microcrystals, Ni1−xSe and Ni3Se2 microspheres) has been successfully synthesized through a convenient, low-temperature hydrothermal method. A good nucleation and growth environment has been created by forming a uniform and transparent solution reaction system. The compositions (including the x value of Ni1−xSe), phase structures, as well as the morphologies of nickel selenides, can be controlled by adjusting the Ni/Se ratio of the raw materials, the pH, the reaction temperatures and times, and so forth. The newly produced Se microspheres in the system have been used as both reactant and in situ template to the Ni1−xSe microspheres. It is found that Ni1−xSe microspheres act as the intermediate precursor during the formation of Ni3Se2 microspheres. Under certain conditions, hexagonal NiSe microspheres can be converted into rhombohedral NiSe nanowires in solution. The formation mechanisms of a series of nickel selenides has been investigated in detail by means of X-ray diffraction (XRD) and scanning electron microscopy (SEM) analyses. This work has provided a general, simple, and effective method to control the composition, phase structure, and morphology of metal selenides in aqueous solution, which will be important for inorganic synthesis methodology and further applications of selenides.
Co-reporter:Sheng Xu;Qing Peng
Chinese Journal of Chemistry 2005 Volume 23(Issue 9) pp:
Publication Date(Web):12 OCT 2005
DOI:10.1002/cjoc.200591135
CdS micropheres were prepared by a hydrothermal microemulsion method in cyclohexane/Triton X-100/pentanol/water at 180 °C. The as-prepared samples were characterized by X-ray diffraction analysis, transmission electron microscopy, electron diffraction, energy diffraction X-ray analysis and photoluminescence spectra. It was found that CdS microspheres with diameter of 1.5–2.5µm were aggregated by nanocrystals. The formation mechanism was proposed.
Co-reporter:Jun Lu ; Qing Peng ; Weiyang Wang ; Caiyun Nan ; Lihong Li ;Yadong Li
Journal of the American Chemical Society () pp:
Publication Date(Web):January 9, 2013
DOI:10.1021/ja308717z
By using a novel coating approach based on the reaction between MC2O4·xH2O and Ti(OC4H9)4, a series of nanoscale Li2TiO3-coated LiMO2 nanobelts with varied Ni, Co, and Mn contents was prepared for the first time. The complete, thin Li2TiO3 coating layer strongly adheres to the host material and has a 3D diffusion path for Li+ ions. It is doped with Ni2+ and Co3+ ions in addition to Ti4+ in LiMO2, both of which were found to favor Li+-ion transfer at the interface. As a result, the coated nanobelts show improved rate, cycling, and thermal capabilities when used as the cathode for Li-ion battery.
Co-reporter:Lihong Li, Caiyun Nan, Jun Lu, Qing Peng and Yadong Li
Chemical Communications 2012 - vol. 48(Issue 55) pp:NaN6947-6947
Publication Date(Web):2012/05/21
DOI:10.1039/C2CC32306K
A simple one-step route for preparing α-MnO2 nanotubes is reported. The α-MnO2 nanotubes exhibit a high surface area of 226 m2 g−1 and reversible capacity of 512 mA h g−1 at a high current density of 800 mA g−1 after 300 cycles, as well as cycling stability when measured as an anode in lithium batteries.
Co-reporter:Xiaotang Lu, Zhongbin Zhuang, Qing Peng and Yadong Li
Chemical Communications 2011 - vol. 47(Issue 11) pp:NaN3143-3143
Publication Date(Web):2011/01/26
DOI:10.1039/C0CC05064D
A new wurtzite phase Cu2ZnSnS4 was discovered and the corresponding nanocrystals have been successfully synthesized. They have been characterized in detail and showed the photoelectric response, which demonstrated their potential in the application of photovoltaic devices.
Co-reporter:Zhongbin Zhuang, Qing Peng and Yadong Li
Chemical Society Reviews 2011 - vol. 40(Issue 11) pp:NaN5513-5513
Publication Date(Web):2011/08/15
DOI:10.1039/C1CS15095B
The microstructure (composition, size and shape etc.) of semiconductor nanocrystals determine the electronic density of states of semiconductor nanomaterials and ultimately determine their optical and electrical properties. Semiconductor nanocrystal advanced structures, such as hybrid nanostructures and nanocrystal superlattices, not only integrate the function of individual nanocrystals, but also brings the materials collective and synchronic properties. How to control the monodispersity, composition and structure of as-prepared semiconductor nanocrystals during their syntheses, as well as their furthermore assembly, has been a hot research area in this decade. This critical review focuses on the development of synthetic and assembly methods (techniques) of semiconductor nanocrystals processed in the liquid phase. Emphasis is on the synthesis methodology, microstructure related properties of semiconductor nanocrystals, and their applications (243 references).
Co-reporter:Dingsheng Wang, Xiaoyang Li, Hao Li, Linsen Li, Xun Hong, Qing Peng and Yadong Li
Journal of Materials Chemistry A 2013 - vol. 1(Issue 5) pp:NaN1590-1590
Publication Date(Web):2012/11/16
DOI:10.1039/C2TA00765G
We exploited a new approach to prepare nanocomposites of semiconductor and noble metal via reaction between sulfur and bimetallic nanocrystals in ODA solvent. Various nanostructures including core–shell, porous, and heterostructure can be prepared, depending on the structure of bimetallic nanocrystals. For example, core–shell (the shell metal reacts with sulfur) bimetallic nanocrystals lead to the formation of core (noble metal)–shell (semiconductor) hybrid nanocrystals (CoxS@Au); intermetallic and alloyed nanocrystals lead to the formation of porous noble metal–semiconductor nanocrystals (CoxS–Pt); core–shell (the core metal reacts with sulfur) bimetallic nanocrystals lead to the formation of hollow noble metal–solid semiconductor heterostructured nanocrystals (Pt–Ag2S). This approach provides a general and excellent way to produce hybrid nanomaterials.
Co-reporter:Jun Lu, Qing Peng, Zhongying Wang, Caiyun Nan, Lihong Li and Yadong Li
Journal of Materials Chemistry A 2013 - vol. 1(Issue 17) pp:NaN5237-5237
Publication Date(Web):2013/02/20
DOI:10.1039/C3TA01539D
27 nm thick hematite nanodiscs have been prepared by a facile solvothermal method. The growth of Fe2O3 nanodiscs follows the precipitation–dissolution–growth mechanism, and the (001) facets are preferentially exposed since (001) facets are the densest and therefore most stable facets. In particular, outstanding rate and cycling capabilities have been demonstrated for the nanodiscs due to the reduced Li+ diffusion distance and enhanced reactivity of the nanosized structures.
Co-reporter:Yunxin Liu, Jianxin Shi, Qing Peng and Yadong Li
Journal of Materials Chemistry A 2012 - vol. 22(Issue 14) pp:NaN6541-6541
Publication Date(Web):2012/03/02
DOI:10.1039/C2JM16729H
ZnO nanocrystals of ∼4.7 nm were self-assembled into three dimensional nanoporous pyramids by oriented attachment with high selective adsorption and photocatalytic activity.
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