Free-standing Crystals Research Articles

Thermal and Lattice Misfit Stress Relaxation in Growing AlN Crystal with Simultaneous Evaporation of SiC Substrate

AlN single crystals were prevented from cracking by simultaneous growth and evaporation of SiC substrates. The freestanding crystals (<1 mm thick) were proved continuous by synchrotron phase contrast imaging and used as a model system to investigate the type of dislocation structure near AlN/SiC interface by x-ray diffraction techniques. We have found that, unlike the situation in GaN films, where predominantly edge-type threading dislocations cross the layer along its normal, the dislocations configure to form mosaic structure. We suggest a theoretical model that describes the misfit stress relaxation in growing AlN crystal.

Polarization states and dielectric responses of elastically clamped ferroelectric nanocrystals

Polarization states and physical properties of ferroelectrics depend on the mechanical boundary conditions due to electrostrictive coupling between electric polarization and lattice strains. Here, we describe theoretically both equilibrium thermodynamic states and electric permittivities of ferroelectric nanocrystals subjected to the elastic three-dimensional (3D) clamping by a surrounding dielectric material. The problem is solved by the minimization of a special thermodynamic potential that describes the case of an ellipsoidal ferroelectric inclusion embedded into a linear elastic matrix. Numerical calculations are performed for BaTiO3, PbTiO3, and Pb(Zr0.5Ti0.5)O3 nanoparticles surrounded by silica glass. It is shown that, in the case of BaTiO3 and PbTiO3, elastic 3D clamping may change the order of a ferroelectric phase transition from first to second. Furthermore, the mechanical inclusion–matrix interaction shifts the temperatures of structural transitions between different ferroelectric states and even eliminates some ferroelectric phases existing in stress-free BaTiO3 and Pb(Zr0.5Ti0.5)O3 crystals. Another important effect of elastic clamping is the lowering of the symmetry of ferroelectric states in ellipsoidal inclusions, where orthorhombic and monoclinic phases may form instead of the tetragonal and rhombohedral bulk counterparts. Finally, our thermodynamic calculations show that the dielectric responses of studied perovskite ferroelectrics are sensitive to matrix-induced clamping as well. For instance, dielectric peaks occurring at structural transitions between different ferroelectric phases in BaTiO3 appear to be much higher in spherical inclusions than in the freestanding crystal. Predicted clamping-induced enhancement of certain dielectric responses at room temperature indicates that composite materials comprising nanocrystals of perovskite ferroelectrics are promising for device applications requiring the use of high-permittivity dielectrics.

Binary Protein Crystals for the Assembly of Inorganic Nanoparticle Superlattices.

Biomolecules can act as functional templates for the organization of inorganic particles. Here we use two protein containers, engineered with opposite surface charge, as building blocks for the construction of a new type of biohybrid material. Binary structures with crystalline order were obtained, adopting a tetragonal lattice. Moreover, the cavity of the engineered protein containers can be filled with inorganic nanoparticles. The controlled assembly of these protein-nanoparticle composites yields highly ordered binary nanoparticle superlattices as free-standing crystals, with up to a few hundred micrometers in size. Because the structure and lattice parameters of the protein-nanoparticle crystals are independent of their nanoparticle cargo, the binary protein material may serve as a generally applicable matrix for the assembly of a variety of nanoparticles types.

Free-Standing and Circular-Polarizing Chirophotonic Crystal Reflectors: Photopolymerization of Helical Nanostructures.

The preparation of materials exhibiting structural colors has been intensively studied in biomimetic science and technology. Utilizing a newly synthesized cholesteric liquid-crystal (CLC) monomer (abbreviated as BP1CRM), we have prepared CLC films. Photoinitiated copolymerization of this monomer with a common achiral liquid-crystalline monomer produced free-standing films with homogeneous and nanoscale pitch distributions. Employing the thermal sensitivity of the CLC monomer, chirophotonic crystal reflectors were prepared exhibiting a range of colors. The free-standing and circular-polarizing chirophotonic crystal films maintain excellent thermal, mechanical, and chemical stabilities, and the composition can readily be applied as polarized optical films and smart paints.

Homoepitaxial growth of HVPE-GaN doped with Si

Results of growth of high structural quality gallium nitride single crystals doped with silicon are described in this paper. Dichlorosilane was used as precursor of silicon in the hydride vapor phase epitaxy method. Crystallization runs with different flows of dichlorosilane were performed and compared. One-inch free-standing HVPE-GaN crystals of high structural quality and high purity, previously grown on ammonothermal GaN substrates, were used as seeds. Structural, electrical, and optical properties of HVPE-GaN doped with silicon are presented and discussed in detail. A laser diode built on the homoepitaxially grown GaN is demonstrated.

Two scale simulation of surface stress in solids and its effects

Surface stress in solids can have profound effects in semi-infinite and nanoscale materials. The current work pertains to the simulation of surface stress, using the concept proposed by Shuttleworth [Proceedings of Physical Society 63 (1949) 444–457]. A two-scale approach is used for the simulation of surface stress. Density functional theory is used to compute the lattice parameter of a free-standing layer (or two layers in the case of (110) surface) of atoms, which is further used as an input into a finite element model. Aluminium is used as a model material for the computation of surface tension of (100), (111) and (110) planes and the results of the simulations are validated by comparison with results from literature. The utility of the model developed is highlighted by demonstrating the effect of surface tension on the: (i) stress variation in a thin slab & (ii) lattice parameter of nanoscale free-standing crystals.

Facile route to freestanding CH3NH3PbI3 crystals using inverse solubility.

CH3NH3PbI3 was found to exhibit inverse solubility at high temperatures in γ-butyrolactone. Making use of this unusual, so far unreported phenomenon, we present a facile method for the growth of freestanding crystals of CH3NH3PbI3 from solution without addition of any capping agents or seed particles. Large, strongly faceted crystals could be grown within minutes. This finding may aid in understanding the crystallization process of CH3NH3PbI3 from solution that may lead to improved morphological control of film deposition for a range of device architectures. Our process offers a facile and rapid route to freestanding crystals for use in a broad range of characterization techniques.

Direct and Scalable Deposition of Atomically Thin Low-Noise MoS2 Membranes on Apertures.

Molybdenum disulfide (MoS2) flakes can grow beyond the edge of an underlying substrate into a planar freestanding crystal. When the substrate edge is in the form of an aperture, reagent-limited nucleation followed by edge growth facilitate direct and selective growth of freestanding MoS2 membranes. We have found conditions under which MoS2 grows preferentially across micrometer-scale prefabricated solid-state apertures in silicon nitride membranes, resulting in sealed membranes that are one to a few atomic layers thick. We have investigated the structure and purity of our membranes by a combination of atomic-resolution transmission electron microscopy, elemental analysis, Raman spectroscopy, photoluminescence spectroscopy, and low-noise ion-current recordings through nanopores fabricated in such membranes. Finally, we demonstrate the utility of fabricated ultrathin nanopores in such membranes for single-stranded DNA translocation detection.

Observation of piezoelectricity in free-standing monolayer MoS₂.

Piezoelectricity allows precise and robust conversion between electricity and mechanical force, and arises from the broken inversion symmetry in the atomic structure. Reducing the dimensionality of bulk materials has been suggested to enhance piezoelectricity. However, when the thickness of a material approaches a single molecular layer, the large surface energy can cause piezoelectric structures to be thermodynamically unstable. Transition-metal dichalcogenides can retain their atomic structures down to the single-layer limit without lattice reconstruction, even under ambient conditions. Recent calculations have predicted the existence of piezoelectricity in these two-dimensional crystals due to their broken inversion symmetry. Here, we report experimental evidence of piezoelectricity in a free-standing single layer of molybdenum disulphide (MoS₂) and a measured piezoelectric coefficient of e₁₁ = 2.9 × 10(-10) C m(-1). The measurement of the intrinsic piezoelectricity in such free-standing crystals is free from substrate effects such as doping and parasitic charges. We observed a finite and zero piezoelectric response in MoS₂ in odd and even number of layers, respectively, in sharp contrast to bulk piezoelectric materials. This oscillation is due to the breaking and recovery of the inversion symmetry of the two-dimensional crystal. Through the angular dependence of electromechanical coupling, we determined the two-dimensional crystal orientation. The piezoelectricity discovered in this single molecular membrane promises new applications in low-power logic switches for computing and ultrasensitive biological sensors scaled down to a single atomic unit cell.

Formation Mechanism of Freestanding CH3NH3PbI3 Functional Crystals: In Situ Transformation vs Dissolution–Crystallization

To date, the formation mechanism of organolead halide CH3NH3PbI3 perovskites based on the efficient sequential reaction route has remained virtually unexplored. Such a synthetic method usually yields high-performance solar cells with an efficiency over 15%, and the identification of the crystal growth mechanism is crucial for understanding the chemical reaction process and further improving the light converting efficiency. Herein, we develop a versatile and facile approach based on sequential reaction to produce freestanding CH3NH3PbI3 crystals as a model for crystal growth mechanism studies. It was found that the in situ transformation and dissolution–crystallization mechanisms play competing roles in determining the characteristics of products that are largely depend on the chemical reaction kinetics. Such a method can also be readily used for synthesis of freestanding CH3NH3PbI3 crystals with controllable morphological characteristics, such as cuboids, rods, wires, and plates. The synthetic strategy as...

Preparation of free-standing GaN substrates from GaN layers crystallized by hydride vapor phase epitaxy on ammonothermal GaN seeds

Crystallization of GaN by hydride vapor phase epitaxy (HVPE) on ammonothermally grown GaN seed crystals is overviewed. Morphology of the crystal growing surface at the beginning of the crystallization process and at the end of it is presented. Based on these results a rough growth model is proposed. Smooth GaN layers up to 1 mm thick and of a high purity, excellent crystalline quality, without any cracks, and with a low dislocation density are grown. Preparation of the free-standing HVPE-GaN crystals by slicing as well as structural, electrical and optical qualities of the resulting wafers are reported and discussed.

Analysis of self-lift-off process during HVPE growth of GaN on MOCVD-GaN/sapphire substrates with photolitographically patterned Ti mask

An influence of a nitridation process on a self lift-off phenomenon during the HVPE crystallization of GaN on a MOCVD-GaN/sapphire template with photolitographically patterned Ti mask was investigated. Duration of the nitridation process and flows of reagents in this process were modified. A correlation between degradation degree of a GaN template surface and the conditions of the nitridation process was observed. It was also observed that the degree of degradation had a direct influence on a moment of the self lift-off phenomenon (separation of a HVPE-GaN crystal from the template). It was shown that the best free-standing HVPE-GaN crystals, in sense of their structural quality, were obtained when the separation process occurred during cooling down step.

Preparation of Bulk AlN Seeds by Spontaneous Nucleation of Freestanding Crystals

Freestanding AlN single crystals are grown in a RF-heated furnace by physical vapor transport (PVT). Three different growth regimes with growth temperatures between 2080–2200°C result in different crystal habits and very high structural quality. The Rocking curves show FWHM < 21 arcsec in the 0002 and 101̄0 Reflection on the as-grown facets. Isometric AlN crystals with sizes up to 10 × 10 × 12mm3 show a zonar structure consisting of a yellowish core area which is grown on the N-polar (0001̄) facet and a nearly colorless edge region grown on prismatic {101̄0} facets. In the two growth zones nearly the same C concentrations but different amounts of O and Si are measured by secondary ion mass spectrometry (SIMS). The yellowish core area show a very low defect density (EPD ⩽ 100 cm−2) and a higher deep UV transparency compared to the edge region.

Resonant tunnelling and negative differential conductance in graphene transistors

The chemical stability of graphene and other free-standing two-dimensional crystals means that they can be stacked in different combinations to produce a new class of functional materials, designed for specific device applications. Here we report resonant tunnelling of Dirac fermions through a boron nitride barrier, a few atomic layers thick, sandwiched between two graphene electrodes. The resonance occurs when the electronic spectra of the two electrodes are aligned. The resulting negative differential conductance in the device characteristics persists up to room temperature and is gate voltage-tuneable due to graphene’s unique Dirac-like spectrum. Although conventional resonant tunnelling devices comprising a quantum well sandwiched between two tunnel barriers are tens of nanometres thick, the tunnelling carriers in our devices cross only a few atomic layers, offering the prospect of ultra-fast transit times. This feature, combined with the multi-valued form of the device characteristics, has potential for applications in high-frequency and logic devices.

Recent advances in free-standing two-dimensional crystals with atomic thickness: design, assembly and transfer strategies

Free-standing two-dimensional (2D) crystals with atomic thickness have attracted extensive attention because of their novel electronic, optical, mechanical and biocompatible properties, and so on. In recent years, the study of atomically thick 2D crystals has mainly focused on the layered materials with weak van der Waals forces between the layers. For the lack of executable synthetic strategies, preparation of atomically thick 2D crystals with a nonlayered structure or quasi-layered structure with relatively strong bonds between the layers is still a great challenge. This review mainly focuses on recent advances in synthetic strategies for atomically thick 2D crystals with a nonlayered structure as well as the quasi-layered structure with relatively strong bonds between the layers. Furthermore, methods for the modulation of the electronic structures of 2D crystals along with assembly and transfer techniques of the 2D crystals are discussed. The key points of each strategy in preparation, electronic structure modulation, assembly and transfer processes are also presented.

Electrostatic assembly of binary nanoparticle superlattices using protein cages

Binary nanoparticle superlattices are periodic nanostructures with lattice constants much shorter than the wavelength of light and could be used to prepare multifunctional metamaterials. Such superlattices are typically made from synthetic nanoparticles, and although biohybrid structures have been developed, incorporating biological building blocks into binary nanoparticle superlattices remains challenging. Protein-based nanocages provide a complex yet monodisperse and geometrically well-defined hollow cage that can be used to encapsulate different materials. Such protein cages have been used to program the self-assembly of encapsulated materials to form free-standing crystals and superlattices at interfaces or in solution. Here, we show that electrostatically patchy protein cages--cowpea chlorotic mottle virus and ferritin cages--can be used to direct the self-assembly of three-dimensional binary superlattices. The negatively charged cages can encapsulate RNA or superparamagnetic iron oxide nanoparticles, and the superlattices are formed through tunable electrostatic interactions with positively charged gold nanoparticles. Gold nanoparticles and viruses form an AB(8)(fcc) crystal structure that is not isostructural with any known atomic or molecular crystal structure and has previously been observed only with large colloidal polymer particles. Gold nanoparticles and empty or nanoparticle-loaded ferritin cages form an interpenetrating simple cubic AB structure (isostructural with CsCl). We also show that these magnetic assemblies provide contrast enhancement in magnetic resonance imaging.

Graphene-based materials for biosensing and bioimaging

Abstract

Frederic Holtzberg

Materials scientist Frederic Holtzberg passed away in Greenport, New York, on 24 April 2012 after an extended illness. He was a distinguished member of the IBM Research Division, where he worked from 1952 through 1993. Although trained in chemistry, he had diverse interests that encompassed other disciplines, particularly physics. Holtzberg made outstanding contributions to our understanding of rare-earth materials, especially magnetic semiconductors and materials with strong electron correlations. He was the co-recipient, with Francis DiSalvo Jr, of the American Physical Society’s 1991 International Prize for New Materials for his discovery of new materials characterized by strong electron correlations.Born in New York City on 12 April 1922, Holtzberg served in the US Army, including some time in India. He received his BS in chemistry at Brooklyn College in 1947, and under the guidance of crystallographer Isidor Fankuchen, in 1952 he completed his PhD on the structure of formic acid at the Polytechnic Institute of Brooklyn. That year he joined the IBM Thomas J. Watson Research Center at Columbia University. From 1959 to 1960 he took a leave of absence to become a technical assistant and consultant with the White House office of science and technology. He then rejoined the Watson Research Center, which had moved to Westchester County, New York.Holtzberg’s career as a materials scientist spanned many of the important developments in rare-earth research. With interdisciplinary insight and talent, he performed new syntheses and fabricated novel materials that led to the exploration of new physical phenomena. His creation and study of new rare-earth materials were critical in developing several still-active fields of research, including magnetic semiconductors, intermediate valence, and high-temperature superconductors. He was aided in his efforts by his wide family of collaborators, which included solid-state physicists and chemists from the US, the UK, Germany, and France. Not only did Holtzberg create samples that made the experiments possible, but he also initiated ideas and directions for such experiments.Following the 1961 discovery by Bernd Matthias and colleagues that europium oxide was a ferromagnetic insulator, Holtzberg and Siegfried Methfessel embarked on original studies on the Eu chalcogenides and their alloys. Holtzberg and Methfessel had the idea to produce magnetic semiconductors made from that class of materials. That led to their well-known 1964–66 work establishing the magnetic phase diagrams of solid, insulating Eu chalcogenide solutions with trivalent rare-earth metals. The importance of those studies cannot be overemphasized, since at that time all interest in Eu compounds focused on pure materials. Holtzberg showed that the entire series of solid solutions could be produced in single-crystal form, that adding the trivalent rare earths made the materials good conductors, and that the electrons modified the magnetic exchange. That insight influenced rare-earth research thereafter and swiftly led to major efforts at ETH Zürich, MIT, and IBM.His expertise in rare-earth materials led Holtzberg naturally to the subject of intermediate valence. In 1970 Aiyasami Jayaraman at Bell Labs had discovered in samarium sulfide a pressure-induced insulator–metal transition, in which the color changed from black to gold and the lattice constant collapsed by 5% without a change in crystal structure. Holtzberg discovered in 1973 that he could induce the transition by “chemical pressure” in solid solutions of samarium sulfide with lanthanum and yttrium sulfide. Independently, Jayaraman reported on a similar study using gadolinium sulfide the same year.In 1975 Holtzberg visited the low-temperature research center of CNRS in Grenoble, France, and started an effective rare-earth research program. Until that time, the center’s work had involved principally transition-metal alloys. Holtzberg’s presence changed the emphasis of the center’s materials research. His effectiveness as a collaborator and leader may best be highlighted by the fact that of his last 150 publications, only one third involved colleagues solely from IBM.Among the many other materials Holtzberg prepared and studied were spin glasses, manganese-doped II-VI semiconductors, and some of the first single crystals of reentrant superconductors. Of particular importance, Holtzberg, with his postdoctoral colleague Debra Kaiser, developed the first technique for growing free-standing crystals of high-temperature yttrium-based superconductors. Such crystals were essential for transport, magnetization, IR absorption, and tunneling-spectroscopy experiments to probe the underlying mechanism for superconductivity.Holtzberg will be remembered by his many colleagues for his wisdom and great sense of humor. In his years at IBM, he taught and mentored two generations of younger scientists, including the three of us. He attacked each materials problem with dedication, humility, and extraordinary skill. It is a testament to his innate modesty that he was not a coauthor of many of the first detailed studies on rare-earth alloy systems, since his samples had not been specifically made for the reported experiments. Holtzberg was one of the pioneers of multidisciplinary materials research, and his achievements remain a model for excellent science in a truly interactive mode between chemists, ceramicists, and physicists.Frederic HoltzbergPPT|High resolution© 2012 American Institute of Physics.

Scalable nanomanufacturing of millimetre-length 2D NaxCoO2 nanosheets

A novel, scalable nanomanufacturing technique is reported for batch fabrication of nanoscale-thick Na0.7CoO2 nanosheets. The nanomanufacturing technique is a high-yield, bottom-up process that is capable of producing tens of thousands of nanosheets stacked into a macro-scale pellet. The nanosheets are uniform in length and shape with very high crystal anisotropy. The nanosheet thicknesses can be 10–100 nm while their lengths can measure up to 1.8 mm long. The typical dimension ratios are highly anisotropic, at 10−5:1 : 1 (thickness:length:width). X-ray synchrotron studies indicate that the 2D crystals are stacked in a turbostratic arrangement with rotational misalignment with respect to the stacking axis. The stacked nanosheets are readily delaminated into very large (350 μm × 150 μm × 100 nm) free-standing 2D crystals. The novel nanomanufacturing technique is based on sol–gel and electric-field induced kinetic-demixing followed by a brief high temperature treatment, thus providing an efficient means of large scale crystal growth requiring only a simple furnace and power supply. Evidence shows that the demixing process increases the concentration of Na ions and that demixing is necessary to produce the millimetre-length nanosheets. Electric field induced kinetic-demixing is successfully performed at low temperatures (<300 °C), which is more than three times lower than past kinetic-demixing temperatures.

Light harvesting architectures for electron beam evaporated solid phase crystallized Si thin film solar cells: Statistical and periodic approaches

The fabrication of light trapping architectures for electron beam (e-beam) evaporated polycrystalline Si thin film solar cells is investigated based on tailored self-organized light scattering silica nanospheres and 2 dimensional periodic nanoimprinted structures on glass. A microscopic analysis reveals a unique correlation between the microstructure of high-rate e-beam evaporated Si and the substrate topography. These features provide the basis for the design of nanostructured Si that complies with its distinctive growth characteristics. A layer of self-organized nanospheres embedded in a sol–gel matrix and an anti-reflection coating is found to be an e-beam compatible light trapping approach for poly-Si solar cells, contributing to an increase of 50% in current collection. We developed a preparation process for arrays of equidistant free-standing Si crystals with remarkable optical absorption characteristics based on a nanoimprinted glass substrate by selectively etching e-beam evaporated Si. This periodic approach opens design possibilities for effective three-dimensional architectures for advanced photon management.