Reversed ethane/ethylene adsorption in a metal–organic framework via introduction of oxygen

Separation of ethane from ethylene is a very important but challenging process in the petrochemical industry.Finding an alternative method would reduce the energy needed to make 170 million tons of ethylene manufactured worldwide each year.Adsorptive separation using C2H6-selective porous materials to directly produce high-purity C2H4 is more energy-efficient.We herein report the"reversed C2H6/C2H4 adsorption"in a metal–organic framework Cr-BTC via the introduction of oxygen on its open metal sites.The oxidized Cr-BTC(O2)can bind C2H6 over C2H4 through the active Cr-superoxo sites,which was elucidated by the gas sorption isotherms and density functional theory calculations.This material thus exhibits a good performance for the separation of 50/50 C2H6/C2H4 mixtures to produce 99.99%pure C2H4 in a single separation operation.

A Novel Large Moment Antiferromagnetic Order in K_(0.8)Fe_(1.6)Se_(2) Superconductor

The discovery of cuprate high TC superconductors has inspired the search for unconventional superconductors in magnetic materials.A successful recipe has been to suppress long−range order in a magnetic parent compound by doping or high pressure to drive the material towards a quantum critical point.We report an exception to this rule in the recently discovered potassium iron selenide.The superconducting composition is identified as the iron vacancy ordered K_(0.83)(2)Fe_(1.64)(1)Se_(2) with T_(C) above 30 K.A novel large moment 3.31μB/Fe antiferromagnetic order that conforms to the tetragonal crystal symmetry has an unprecedentedly high ordering temperature TN≈559 K for a bulk superconductor.Staggeringly polarized electronic density of states is thus suspected,which would stimulate further investigation into superconductivity in a strong spin-exchange field under new circumstances.

Phase separation in Sr doped BiMnO_3

Phase separation in Sr doped BiMnO3(Bi1-xSrxMnO3, x = 0.4–0.6) was studied by means of temperature-dependent high-resolution neutron powder diffraction(NPD), high resolution X-ray powder diffraction(XRD), and physical property measurements. All the experiments indicate that a phase separation occurs at the temperature coinciding with the reported charge ordering temperature(TCO) in the literature. Below the reported TCO, both the phases resulting from the phase separation crystallize in the orthorhombically distorted perovskite structure with space group Imma. At lower temperature,these two phases order in the CE-type antiferromagnetic structure and the A-type antiferromagnetic structure, respectively.However, a scrutiny of the high-resolution NPD and XRD data at different temperatures and the electron diffraction experiment at 300 K did not manifest any evidence of a long-range charge ordering(CO) in our investigated samples, suggesting that the anomalies of physical properties such as magnetization, electric transport, and lattice parameters at the TCOmight be caused by the phase separation rather than by a CO transition.

Evolution of Morphology and Structure During Crystallization and Melting in Syndiotactic Polypropylene

Structure and morphology development during isothermal crystallization and subsequent melting of syndiotactic polypropylene(sPP) was studied by time-resolved simultaneous small-angle X-ray scattering(SAXS) and wide-angle X-ray diffraction(WAXD) methods with synchrotron radiation and differential scanning calorimetry(DSC). The time and temperature dependent parameters such as long period, L , crystal lamellar thickness, l c, amorphous layer thickness, l a, scattering invariant, Q , crystallinity, X c, lateral crystal sizes, L 200 and L 020 , and unit cell parameters a and b were extracted from SAXS and WAXD profiles. Decreasing long period and crystal thickness indicate that thinner secondary crystal lamellae are formed. The decreases in unit cell parameters a and b during isothermal crystallization process suggest that crystal perfection takes place. The changes in the morphological parameters (the invariant, Q , crystallinity, X c, long period, L , and the crystal thickness, l c) during subsequent melting were found to follow a two-stage melting process, corresponding to the dual endotherm behavior in the DSC scan. We conclude that the dual melting peaks are due to the melting of secondary and primary lamellae(first peak) and the subsequent recrystallization-melting process(second peak). Additional minor endothermic peak located at the lowest temperature was also detected and might be related to melting of secondary, thinner and defective lamellae. WAXD showed that during melting, thermal expansion was greater along the b axis than that along the a axis.

A Triplet Resonance in Superconducting Fe_(1.03)Se_(0.4_Te_(0.6)

From heavy fermion compounds and cuprates to iron pnictides and chalcogenides, a spin resonance at hΩ0 ∝ k_BT_c is a staple of nearly magnetic superconductors. Possible explanations include a two-particle bound state or loss of magnon damping in the superconducting state. While both scenarios suggest a central role for magnetic fluctuations,distinguishing them is important to identify the right theoretical framework to understand these types of unconventional superconductors. Using an inelastic neutron scattering technique,we show that the spin resonance in the optimally doped Fe_(1.03) Se_(0.4) Te_(0.6) superconductor splits into three peaks in a high magnetic field,a signature of a two-particle S = 1 triplet bound state.

Influence of annealing treatment on structural and magnetic properties of double perovskite Sr_2FeMoO_6

The structure, magnetic and electric properties of Sr2FeMoO6 (the as-made sample) and samples after heat treatment were investigated. The nuclear and magnetic structures of the samples were studied using neutron powder diffraction at room temperature. The results show that the tunneling magnetoresistance of polycrystalline Sr2FeMoO6 depends on its annealing temperature. Annealing at 800 ℃ makes the minimal magnetoresistance(MR) elevated, which may be due to the change of the grain size or the modified intergranular connections. Because of the impurity phase of Fe which probably affects the magnetotransport properties is much larger in sample C, so the MR is decreased by postannealing at 1100 ℃. Therefore, further enhancement of the tunneling magnetoresistance (TMR) can be realized by regulating the grain size at appropriate annealing temperature.

Superconductivity Tuned by the Iron Vacancy Order in K_(x)Fe_(2−y)Se_(2)

Combining in-depth neutron diffraction and systematic bulk studies,we discover that the√5×√5 Fe vacancy order,with its associated block antiferromagnetic order,is the ground state with varying occupancy ratios of the iron 16i and vacancy 4d sites across the phase-diagram of K_(x)Fe_(2)-ySe_(2).The orthorhombic order,with one of the four Fe sites vacant,appears only at intermediate temperatures as a competing phase.The material experiences an insulator to metal crossover when the√5×√5 order is highly developed.Superconductivity occurs in such a metallic phase.

Novel Cancer Treatment Using Targeted Delivery of Short-Lived Radiologically Activated Nanoparticles

The goal of our preliminary study is to show that a minimal of overall body toxicity while maximizing the cancer tumor treatment may be achieved in a novel approach where minute amounts of coated nanoparticles may be radiologically activated prior to treatment and“coerce”tumor cells into readily absorb these nanoparticles.This targeted intracytoplasmic delivery of short-lived radiologically activated nanoparticles could provide less“whole-body”radiation dose while delivering a short lived potent tumor localized dose,along with their low toxicity may prove to be another tool in the treatment of diverse cancers.

Frustrated Magnetic Interactions and Quenched Spin Fluctuations in CrAs

The discovery of pressure-induced superconductivity in helimagnets(CrAs,MnP)has attracted considerable interest in understanding the relationship between complex magnetism and unconventional superconductivity.However,the nature of the magnetism and magnetic interactions that drive the unusual double-helical magnetic order in these materials remains unclear.Here,we report neutron scattering measurements of magnetic excitations in CrAs single crystals at ambient pressure.Our experiments reveal well defined spin wave excitations up to about 150 meV with a pseudogap below 7 meV,which can be effectively described by the Heisenberg model with nearest neighbor exchange interactions.Most surprisingly,the spin excitations are largely quenched above the Néel temperature,in contrast to cuprates and iron pnictides where the spectral weight is mostly preserved in the paramagnetic state.Our results suggest that the helimagnetic order is driven by strongly frustrated exchange interactions,and that CrAs is at the verge of itinerant and correlation-induced localized states,which is therefore highly pressure-tunable and favorable for superconductivity.

Hydrogen-bonded organic framework for red light-mediated photocatalysis

The development of heterogeneous molecule-based catalysts for red light-mediated photocatalysis is still challenging due to the improper light absorption for most materials and the photoactivity deactivation for solid assembly.Herein,red light photocatalysis with a hydrogen-bonded organic framework(HOF)is established.This HOF,named HOF-66,is formed from the self-assembly of guanine-decorated naphthalenediimide(NDI)molecule through hydrogen-bonded guanine-quadruplex nodes,showing square grid supramolecular layers confirmed by powder X-ray diffraction analysis.In contrast to unsubstituted NDI HOF,introduction of ethylamino groups to NDI core in HOF-66 tunes strong electronic maximum absorption peak to 619 nm,allowing red light photocatalysis of singlet oxygen evolution proved by 1,3-diphenylisobenzofuran degradation and electron spin resonance determination.Particularly,under the same conditions,the sulfide oxidation rate in the presence of HOF-66 was 28 times higher compared to its unsubstituted analogue.This work integrates the molecular design and aggregation effect towards the application of HOFs,opening a new gate for red light photocatalysts.

A microporous aluminum-based metal-organic framework for high methane,hydrogen,and carbon dioxide storage

We report a microporous aluminum-based metal-organic framework(MOF),BUT-22 for high methane(CH_(4)),hydrogen(H_(2)),and carbon dioxide(CO2)storage.At 296 K and 80 bar,BUT-22 exhibits a high gravimetric CH4 storage capacity of 530 cm^(3)(STP)/g(0.379 g/g).BUT-22 also has a high gravimetric H_(2)storage capacity of 12 wt.%at 100 bar and 77 K.In addition,the CO_(2)adsorption studies revealed that BUT-22 exhibits a high absolute gravimetric CO2 uptake of 1.7 g/g at 296 K and 40 bar.

The Influence of Ethyl Branch on Formation of Shish-Kebab Crystals in Bimodal Polyethylene under Shear at Low Temperature

Formation of shish-kebab crystals using a bimodal polyethylene system containing high molecular weight(HMW)component with different ethyl branch contents was investigated.In situ small-angle X-ray scattering(SAXS)and wide-angle X-ray diffraction(WAXD)techniques were used to monitor the formation and evolution of shish-kebab structure sheared at low temperature in simple shear mode and low rate.Only the bimodal PE with no branch formed shish-kebab crystals at the shear temperature of 129℃,and the shish length increased with the crystallization time,while bimodal PE with branch has no observable shish under the same conditions.The degree of crystallization for bimodal PE with no branch increased with time up to above 7%,while those with ethyl branch increased continually up to above 23%.Furthermore,bimodal PE's Hermans orientation factor with no branch increased to 0.60,while those with ethyl branch only increased to a value below 0.15.This study indicated that the shish-kebab crystal formed at the low temperature of 129℃is due to the stretch of entangled chains under shear for the bimodal PE with no branch.Only partly oriented lamellar crystals were formed for the bimodal PE with ethyl branch.All the results at the shear temperatures higher,closed to,and lower than the melting point,the modulation of shish crystals formation owing to different mechanisms of the coil-stretch transition and the stretched network by changing shear temperature was achieved in the bimodal PE samples.

NEUTRON DIFFUSE SCATTERING IN LEAD-BASED RELAXOR FERROELECTRICS AND ITS RELATIONSHIP TO THE ULTRA-HIGH PIEZOELECTRICITY

A brief review is presented that summarizes recent neutron diffuse scattering measurements on single crystal PbMg_(1/3)Nb_(2/3)O_(3)(PMN)and PbZn_(1/3)Nb_(2/3)O_(3)(PZN)doped with PbTiO_(3)(PT).Emphasis is placed on results that suggest that the short-range,polar correlations observed in these systems are connected to the anomalous relaxor dielectric properties,and in particular to the large values of the piezoelectric coe±cient d33 near the morphotropic phase boundary.

A new method to enhance the magnetocaloric effect in (Sc,Ti)Fe_(2) via magnetic phase separation

Magnetic refrigeration based on the magnetocaloric effect(MCE)is a novel refrigeration technology that will replace traditional vapor-compression refrigeration in the future.Improvement in the performance of MCE materials is crucial for the development of magnetic refrigeration technology.This study presents a new method that enhances the MCE performance of(Sc,Ti)Fe_(2) via magnetic phase separation.The maximum magnetic entropy change induced by the coexistence of an in-plane ferromagnetic phase(FMab)and a canting antiferromagnetic phase(CAFM)in Sc_(0.3)Ti_(0.7)Fe_(2) is twice that found in other(Sc,Ti)Fe_(2 )compounds.Variable-temperature neutron diffraction experiments directly reveal that the large magnetic entropy change in Sc_(0.3)Ti_(0.7)Fe_(2) is dominated by the transformation from a highly ordered FMab state to a CAFM state with a lower magnetic order.The magnetic phase separation is a direct transition from a higher-ordered state with a larger lattice to a lower-ordered state with a smaller lattice that induces a large magnetic order change and lattice contraction.The combination of the metamagnetic transition and negative thermal expansion leads to enhanced MCE.This study suggests the possibility that magnetic phase separation can be an effective approach to achieving and controlling a large MCE in magnetic materials.

Mn_(1.2)Fe_(0.8)P_(0.76)Ge_(0.24)磁制冷材料相变过程与磁性能关系的研究

利用机械合金化(MA)结合放电等离子烧结(SPS)技术,制备了Mn_(1.2)Fe_(0.8)P_(0.76)Ge_(0.24)磁制冷材料,并采用SEM观察烧结样品的显微组织,利用中子衍射、超导量子干涉磁强计(SQUID)、差示扫描量热仪(DSC)和X射线衍射(XRD)等手段对相变过程和磁热性能进行了研究.结果表明:烧结样品显微组织均匀致密,Mn_(1.2)Fe_(0.8)P_(0.76)Ge_(0.24)化合物具有六方Fe_2P型晶体结构.外加磁场和温度的变化都可以引起材料的磁热相变,即顺磁相与铁磁相之间的可逆一级相变.材料的磁熵变与相转变的程度有密切关系,随着外加磁场的增大或温度的降低,合金由顺磁相向铁磁相转变,从而使材料磁熵变增大.分析发现,材料的磁熵变大小与相转变过程中发生转变的相变百分比是直接对应的,温度诱导相变与磁场诱导相变所得结果一致.

Glass transition: from interaction potential changes to the corresponding structural and relaxation responses along the path of reaching the final equilibrium

Glass transition involves a many-body interaction and relaxation process. The split of relaxation spectrum and the extremely slow dynamics bring into considerations of non-linearity and non-equilibrium. Some of our recent findings in two measurable colloidal systems are reviewed, one with a simple attractive interparticle potential and the other with a competitive(repulsive vs. attractive)inter-particle interaction. With an approach from interaction potential changes to the corresponding structural and relaxation responses, along the path of reaching the final equilibrium, we illustrate some interesting physics in glass formation process. Also,some reviews on the popular glass transition theories are made to remind readers to avoid artifacts and misinterpretations.

自旋旋转在La(Fe,Al)_(13)超磁致伸缩中的关键作用

磁致伸缩可作为电磁能和机械能之间的高效转换途径,是基础研究以及技术应用等方面重要的材料性能.然而,在其微观成因的理解方面仍然存在挑战,这对磁致伸缩材料的发展非常重要.本文利用原位磁场和温度场下的粉末中子衍射技术首次揭示了自旋旋转对La(Fe,Al)_(13)超磁致伸缩的关键作用. La(Fe,Al)_(13)超磁致伸缩性能是由磁场驱动的倾斜结构磁矩旋转引起的,其中铁磁成分的急剧增加促使晶格内部二十面体伸长,进而产生巨大的磁致伸缩.此外,本文揭示了La(Fe,Al)_(13)精确的倾斜磁结构特征.本研究提供了一种通过磁场诱导自旋旋转途径探索新型磁致伸缩功能材料的策略.

平均原子晶格体积在预测负热膨胀材料中的作用:以REFe(CN)_(6)为例

面对高精尖仪器或设备的热膨胀控制的需求,探索新的负热膨胀材料显得尤为重要.本文采用"平均原子晶格体积"概念预测各向异性新的负热膨胀材料体系,据此发现了REFe(CN)_(6)(RE=La,Sm,Ho,Lu)负热膨胀材料家族.我们采用原位中子粉末衍射(NPD)、X射线吸收精细结构谱(EXAFS)和第一性原理计算揭示了其负热膨胀来源于低频声子振动模式中的CN原子的横向热振动,进一步发现"平均原子晶格体积"越大,其对应的低频声子模式频率越低,格林艾森常数越负,CN原子的横向热振动越强.本工作为定性预测负热膨胀材料提供了新的方法,对热膨胀控制与设计具有重要意义.

Field-tuned magnetic structure and phase diagram of the honeycomb magnet YbCl_(3)

We report thermodynamic and neutron diffraction measurements on the magnetic ordering properties of the honeycomb lattice magnet YbCl_(3). We find YbCl_(3) exhibits a Ne′el type long-range magnetic order at the wavevector(0, 0, 0) below TN= 600 mK.This magnetic order is associated with a small sharp peak in heat capacity and most magnetic entropy release occurs above the magnetic ordering temperature. The magnetic moment lies in-plane, parallel to the monoclinic a-axis, whose magnitude mYb= 0.86(3) μBis considerably smaller than the expected fully ordered moment of 2.24 μBfor the doublet crystal-field ground state. The magnetic ordering moment gradually increases with increasing magnetic field perpendicular to the ab-plane, reaching a maximum value of 1.6(2) μBat 4 T, before it is completely suppressed above ~ 9 T. These results indicate the presence of strong quantum fluctuations in YbCl_(3).