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1                                              Al(3+) chelation increased absorbance 2-42x and lambdama
2 rded [Cp*2Fe][(C5H6Me4NOE(C6F5)3] (E = B 10, Al 11).
3  effects of chelation of metal ions (Mg(2+), Al(3+), Cr(3+), Fe(3+), and Ga(3+)) in factorial excesse
4 different semiconductors, Mg2Si, Si0.8Ge0.2, Al(x)Ga(1-x)As and clathrate Si46-VIII were studied, whi
5 ore the last addition of stellar-derived (26)Al has not been identified yet but may be preserved in p
6  before its pollution by stellar-derived (26)Al.
7 e-crystal X-ray diffraction and show by (27) Al NMR spectroscopy, electrospray-ionization mass spectr
8 gh high-resolution measurements of (13)C-(27)Al distances.
9 on of well-resolved DNP surface-enhanced (27)Al cross-polarization spectra.
10 s are examined with this technique using (27)Al and (7)Li NMR.
11 works with other Lewis acids (such as B(3+), Al(3+) and Sn(4+)) and can be applied to other 2D materi
12 ysis of the precursor complex [(HEB)Re(CO)3][Al(OR(f))4] (15) in the presence of the added alkane.
13         The addition of synthetized Glut-3SH-Al and Glut-3SH-SO3 in the synthetic medium induced a si
14 afforded [Cp*2Fe][PhC(O)OE(C6F5)3] (E = B 5, Al 6).
15  [Cp*2Fe]2[(mu-O2C6H4)(E(C6F5)3)2] (E = B 8, Al 9).
16  grain boundaries in aluminium alloy AA5083 (Al-Mg-Mn) during isothermal exposures is proposed herein
17                                 In addition, Al(3+) stress up-regulated expression of AUX1 and PIN2 g
18      The extraction fluid leached additional Al and Si from the method-prescribed borosilicate glass
19 ield strength of the corresponding peak-aged Al alloy at ambient temperature and 14 times higher at 4
20 or Earth's most abundant mineral, (Mg,Fe,Al)(Al,Fe,Si)O3 bridgmanite (also known as silicate perovski
21 layer-deposited Al2O3 thin films in Al/Al2O3/Al trilayers can recover after the breakdown.
22 complexes of the type [(HEB)Re(CO)2(alkane)][Al(OR(f))4] (HEB = eta(6)-hexaethylbenzene; alkane = cyc
23 re of amorphous (am) and fcc-aluminum (alpha-Al) phases.
24 Al and 85Al alloys, and [am] --> [am + alpha-Al + cubic AlxMy (M = Y, Ni, Co, Fe, Pd)] --> [am + alph
25 e heating-induced reversion from [am + alpha-Al + multicomponent AlxMy] to [am + alpha-Al] for the 84
26 xMy (M = Y, Ni, Co, Fe, Pd)] --> [am + alpha-Al] --> [alpha-Al + Al3Y + Al9(Co, Ni)2 + unknown phase]
27 llization sequences are [am] --> [am + alpha-Al] --> [alpha-Al + compounds] for the 86Al and 85Al all
28 ha-Al + multicomponent AlxMy] to [am + alpha-Al] for the 84Al alloy is abnormal, not previously obser
29 is encouraging for obtaining the [am + alpha-Al] mixture over a wide range of high temperature effect
30  Co, Fe, Pd)] --> [am + alpha-Al] --> [alpha-Al + Al3Y + Al9(Co, Ni)2 + unknown phase] for the 84Al a
31 nces are [am] --> [am + alpha-Al] --> [alpha-Al + compounds] for the 86Al and 85Al alloys, and [am] -
32  85Al alloy where the primary phase is alpha-Al.
33 he heterogeneous nucleation of primary alpha-Al crystals and reduces the undercooling needed for soli
34 terogeneous particles, the size of the alpha-Al crystals was found to be less dependent on the proces
35 w pH solubilizes root-toxic ionic aluminium (Al(3+)) species from clay minerals, driving the evolutio
36  (Co), nickel (Ni), zinc (Zn), and aluminum (Al) concentrations in atmospheric deposition, likely via
37 sorption spectrometric analysis of aluminum (Al) and chromium (Cr) in vegetables.
38 te the physiological importance of aluminum (Al) phytotoxicity for plants, it remained unknown if, an
39 ntity possesses trans-planar geometry and an Al-Al bond length of 2.3943(16) A, which is the shortest
40 ardening Al-Zn-Mg(-Cu) matrix composites, an Al 7075 alloy composite reinforced with B4C particles wa
41 n, we present a new approach in designing an Al-based alloy through solid state precipitation route t
42 on of a stable neutral compound featuring an Al horizontal lineAl double bond stabilized by N-heteroc
43 sults clearly demonstrate the presence of an Al horizontal lineAl double bond in this molecule.
44 udy and those from similar experiments on an Al-2Cu alloy were consistent when the alloy compositions
45                   Here the authors report an Al@Cu2O heterostructure based on earth abundant material
46  A highly selective fluoride optode using an Al(III) -porphyrin ionophore is examined as an initial e
47 organometallic reagents (Mg(CH2 SiMe3 )2 and Al(TMP)iBu2 ), key intermediates in this process have be
48 ew strategy to achieve reversible Mg(2+) and Al(3+) insertion in anatase TiO2, achieved through aliov
49 rtion of multivalent ions such as Mg(2+) and Al(3+) into electrode materials remains an elusive goal.
50      The produced crystalline AlCl3.6H2O and Al(NO3)3.9H2O in the first stage of the preparation meth
51  salts, including Al2(SO4)318H2O, AlCl3, and Al(NO3)39H2O under identical conditions.
52 etween the two lines, under both control and Al stress treatments.
53 s Cu-ZSM-5 is characterized by severe Cu and Al aggregation into a copper aluminate phase (CuAl2O4 sp
54 ,000 mile simulation, Cu-SSZ-13 shows Cu and Al clustering, whereas Cu-ZSM-5 is characterized by seve
55 ified: (1) Pb, As, Co, Cd and Cr; (2) Cu and Al; (3) Fe and (4) Zn.
56              Considering samples; K, Cu, and Al had the highest mean concentrations with 6714.5mugg(-
57 our different metal species (Zr, Cr, Fe, and Al) were successfully functionalized with oligonucleotid
58 ional Ru-Al interaction next to the Ru-H and Al-S bonds.
59 atory mechanisms in legumes against H(+) and Al(3+) stresses, but also casts light on their role in m
60  expression and plant resistance to H(+) and Al(3+) toxicity.
61 lubility equilibrium controls on Fe(III) and Al and a commonly reported acceleration of the abiotic F
62  M=Fe(III) , Ga(III) , Cr(III) , In(III) and Al(III) .
63 ous counts attributed to salt particles, and Al-rich particles.
64 ch the ZnO layer isolates the perovskite and Al layers, thus preventing degradation.
65 ncentration profiles as a function of pH and Al content.
66 ere characterized by elevated V, Fe, Si, and Al concentrations, indicating the presence of inorganic
67 . vacancies in bridging tetrahedra sites and Al for Si substitution.
68 nes previously shown to underlie Arabidopsis Al tolerance via root malate exudation, known as SENSITI
69 ith high twin-fault energy barriers, such as Al, Ni, and Pt, but instead is often observed.
70 ng protocol for more reactive melts, such as Al-rich BMG-forming systems.
71 in aluminium, especially cast alloys such as Al-Si alloys, is a matter of importance in order to achi
72    A temperature gradient is induced in a Au/Al dual-layer target by proton heating, and subsequent h
73  for Al thermal conductivity and LEOS for Au/Al release equation-of-state show good agreement with da
74 olecular mechanism in which either the basic Al(I) center or the transient Al horizontal lineNTol spe
75 reduction-oxidation reaction history between Al-Cu-Fe alloys and silicate melt.
76 f droplet morphology during reaction between Al and SiO2.
77 ith the ALD procedure, assemblies bridged by Al(III), Sn(IV), Ti(IV), or Zr(IV) metal oxide units hav
78 e surface was determined to be terminated by Al-O species, and was significantly different from the i
79  of fluoroarenes and heteroarenes to sp(2) C-Al bonds (19 examples, 1 mol % Pd loading).
80 s creates two new C-C bonds as well as one C-Al bond, which can be oxidized in situ with O2 or hydrol
81 itrate, into the soil rhizosphere, chelating Al(3+) ions and thereby imparting Al-resistance based on
82 e elements and heavy metals (Cd, Cr, Cu, Co, Al, Zn, As, Pb and Fe) in 22 varieties of cooked rice us
83 nanowires in conjunction with sputter-coated Al-doped ZnO (AZO) thin films were used as a composite t
84 erformance of powder metallurgy-consolidated Al composites reinforced with either IF- or 2H-WS2 parti
85 ith complex mineral preservatives containing Al, Ca, Cu, Na, K, and Zn.
86 that confirm the formation of a conventional Al=Al double bond.
87  (AlIII) and CH2 bound to a four-coordinated Al (AlIVb) are the precursors of the most active sites f
88 , favored at low values of both Si:Al and Cu:Al ratios, inhibit the material performance by being ina
89 rains in ZnO films is achieved by depositing Al at 100 degrees C with a surface roughness 9.2 nm, wh
90 us an advance in developing highly desirable Al-based BMGs, and also provides guidance for designing
91 , the dissolution method produces a discrete Al cluster on a scale suitable for studies and applicati
92 esults highlight the importance of dissolved Al for amplifying the toxicity of transition metals to h
93                  Concentrations of dissolved Al, As, B, Mo, Na, S, and V all significantly decreased
94      Interdiffusion of parent elements (i.e. Al and Cu) was noticed in the amorphous phase, which was
95 butions of Cu as well as framework elements (Al, O, Si) in both fresh and aged Cu-SSZ-13 and Cu-ZSM-5
96                  Ion imaging showed elevated Al levels in the bacterial membrane, and high intracellu
97 to the unusual 3DOM structure, which ensures Al and Mn2O3 to integrate compactly in nanoscale and gre
98 nanosensor enabled HL-FeNPs to remove excess Al(3+) by using external magnet.
99 y imparting Al-resistance based on excluding Al(+3) from the growing root tip.
100 transporters involved in citric acid export, Al(3+) tolerance and Fe translocation.
101 ologies, specifically for B-(18)F, Si-(18)F, Al-(18)F, and iodine (III)-mediated radiofluorination vi
102 ta for Earth's most abundant mineral, (Mg,Fe,Al)(Al,Fe,Si)O3 bridgmanite (also known as silicate pero
103 vent as early as 4.564 Ga in which the first Al-Cu-Fe alloys formed; and, second, a more recent impac
104 tion of triclusters and a 4-, 5-, and 6-fold Al-O coordination, as observed in previous studies.
105 ear working range of 0.07-100microgL(-1) for Al(III), and 0.05microgL(-1) in linear working range of
106 s could be used as fluorescent biomarker for Al(3+) in live whole organisms.
107 soindole-1,9'-xanthen]-3(2H)-one (DEMAX) for Al(III) chelation is described herein.
108 MG-forming composition reported thus far for Al-rich alloy systems.
109 Further, substitution of only 1% Fe(III) for Al(III) in the structure of boehmite inhibited delaminat
110 ecord critical size (diameter) of 2.5 mm for Al-based BMGs.
111 gulated/dependent transcriptomic network for Al stress responses.
112  using Purgatorio model or Sesame S27314 for Al thermal conductivity and LEOS for Au/Al release equat
113  which is significantly larger than that for Al and is retained in the dynamic regime.
114      The Al-TiO2 nanoparticles prepared from Al(NO3)39H2O exhibit the best photocatalytic activity am
115                The propolis was sourced from Al-Baha in the southern part of the Kingdom of Saudi Ara
116     Their emission was compared to that from Al/AlOx/Au tunnel junctions, which has been previously a
117 f boehmite (gamma-AlOOH) and gibbsite (gamma-Al(OH)3) were compared and contrasted in real time via l
118 he light absorption ratio for nanometer GeSn/Al foil heterostructures can be enhanced up to 85%.
119 ectron (3c2e) donor-acceptor sigma(Ru-H) --> Al interaction.
120 g complexes 5 and 7 are stabilized by Pt-H-->Al and Pt-NH-C(Ph) = O-->Al bridging interactions, resul
121 tabilized by Pt-H-->Al and Pt-NH-C(Ph) = O-->Al bridging interactions, resulting in 5- and 7-membered
122 dianion in [{((Dep) Nacnac)Mg}2 (mu-H)]2 [H3 Al-AlH3 ] ((Dep) Nacnac=[(DepNCMe)2 CH](-) , Dep=2,6-die
123 nto precipitation phenomena in age-hardening Al-Zn-Mg(-Cu) matrix composites, an Al 7075 alloy compos
124 That deaggregation is coupled to heterolytic Al-H bond activation at the Ru-S bond, formally splittin
125 centrations were found in multifloral honey (Al, As, Be, Ca, Cr, Mn, Mo, Ni, Se, Th and U), common he
126 n through adsorption to aluminium hydroxide (Al) is a promising option, and establishing its effectiv
127                       Multimeric oxo-hydroxo Al clusters function as models for common mineral struct
128  ago by the astronomer and mathematician Ibn Al-Haytham and was forcefully restated 150 years ago whe
129 ing Lewis acidity, including Ni(II), Zn(II), Al(III), Ti(IV) and Mo(VI), are anchored as metal-oxide,
130  chelating Al(3+) ions and thereby imparting Al-resistance based on excluding Al(+3) from the growing
131 cations, such as <110> {111} dislocations in Al-based and Ti-based intermetallic compounds.
132 f atomic-layer-deposited Al2O3 thin films in Al/Al2O3/Al trilayers can recover after the breakdown.
133 ting protein kinases (CIPKs) are involved in Al resistance.
134 ng in microcrystalline grains (>/=10 mum) in Al 7075.
135 nchrotron-based hard X-ray nanotomography in Al-Cu alloys to measure kinetics of different nanoscale
136 h as tripling the critical temperature TC in Al-Al2O3 epsilon near zero (ENZ) core-shell metamaterial
137     Similar to fcc-to-hcp transformations in Al and the noble gases, the transformation is sluggish,
138 ure of 10(-10) Torr, but rather an increased Al-O occupancy occurred, which was accompanied by a larg
139                  Here the strongly increased Al and Fe concentration in the effluent suggested that s
140                   Results show the installed Al-C(aryl) bonds are more prone to decomposition by benz
141 ing Na-cycle systems can be retrofitted into Al-cycle operation without major difficulty.
142 peak after the year 2100, predicted free ion Al, Fe, Cu, and Pb concentrations increase by factors of
143  K, Mg, and Na, as well as the foreign ions (Al, Cu, Fe, Mn, Zn) to the solution on the in situ atomi
144    INTERPRETATION: The lowest dose (1/10 IPV-Al) of the vaccine performed well both after two and thr
145  receive 1/5 IPV-Al, 204 to receive 1/10 IPV-Al, and 206 to receive IPV.
146  2), and 98.5% (n=202, type 3); and 1/10 IPV-Al: 98.5% (n=201, type 1), 94.6% (n=193, type 2), and 99
147 /5 IPV-Al], ten-times reduced dose [1/10 IPV-Al], or IPV) intramuscularly in the thigh at 6, 10, and
148 programme of immunisation schedule): 1/3 IPV-Al 98.5% (n=202, type 1), 97.6% (n=200; type 2), and 99.
149 05 were randomly assigned to receive 1/3 IPV-Al, 205 to receive 1/5 IPV-Al, 204 to receive 1/10 IPV-A
150 mulations (three-times reduced dose [1/3 IPV-Al], five-times reduced dose [1/5 IPV-Al], ten-times red
151 o receive 1/3 IPV-Al, 205 to receive 1/5 IPV-Al, 204 to receive 1/10 IPV-Al, and 206 to receive IPV.
152  type 2), and 99.5% (n=204, type 3); 1/5 IPV-Al: 99.5% (n=204, type 1), 96.1% (n=197, type 2), and 98
153 /3 IPV-Al], five-times reduced dose [1/5 IPV-Al], ten-times reduced dose [1/10 IPV-Al], or IPV) intra
154 e seroconversion rate difference between IPV-Al and IPV was greater than -10%.
155 ion is a crucial milestone in developing IPV-Al.
156  2, and 3 was already high for the three IPV-Al vaccines after two vaccinations, but was higher after
157 was to show the non-inferiority of three IPV-Al vaccines to standard IPV.
158          Hence, the DIBAL-H molecule and its Al-H bond are activated by the Ru-S bond, but these hydr
159 /= Kd(K(+)) > Kd(Ca(2+)) >/= Kd(Mg(2+)) > Kd(Al(3+)).
160 pected proton exchange between extra-lattice Al-OH species and an alkane reagent.
161 ed site and these two types of extra-lattice Al-OH species, and it also reveals unexpected proton exc
162                    cbl1 plants exudated less Al-chelating malate, accumulated more Al, and displayed
163 ve, after rearrangement, the carbene-ligated Al(III) amide, NacNac'Al(NHTol)(SIMe) (6).
164      The reduction of pH leads to much lower Al, V, and As mobility in the actively treated residue a
165 es in the following order: Mo(VI) < Ti(IV) &lt; Al(III) < Zn(II) < Ni(II).
166 ous metal-organic materials, MFM-300(M) (M = Al, Sc, Fe, In).
167 gands, M[N((o-C6H4)NCH2P(i)Pr2)3], where M = Al, Ga, and In.
168  the type M[(mu-OH)2 Co(NH3 )4 ]3 (NO3 )6 (M=Al, Ga) can be synthesized using Werner's century-old cl
169 linity or impurities such as organic matter, Al or Si, persisted under suboxic-oxic conditions in the
170 e and Fe-Si metal, and oxidation of metallic Al to Al2O3, occurring where silicate melt was in contac
171 ion of twenty-seven elements (Li, Be, B, Mg, Al, P, K, Ca, Cr, Mn, Co, Ni, Cu, Zn, As, Se, Sr, Mo, Cd
172            Some light elements as He, C, Mg, Al are depleted, while Si and P are enhanced.
173  selected reactions containing elemental Mg, Al, Mn and Sn particles.
174                        In particular, for Mg-Al alloys, this direction changes from [Formula: see tex
175  ions, we examined ternary mixtures of MnO2, Al ions, and NOM.
176     The first reversible capacity of EG-MNPs-Al as anode material for lithium ion battery was 480 mAh
177 d less Al-chelating malate, accumulated more Al, and displayed a severe root growth reduction in resp
178 ine, and have elevated concentrations of Na, Al, and other trace metals.
179 t, the carbene-ligated Al(III) amide, NacNac'Al(NHTol)(SIMe) (6).
180  grain boundary migration in nanocrystalline Al films with the excess of O atoms at the boundaries.
181 igate the effects of aluminum nanoparticles (Al NPs) prepared by sonication of aluminum foil on the U
182 conventional s-wave superconductor (e.g. Nb, Al) and either strongly spin-polarized ferromagnetic ins
183        Homodinuclear multiple-bonded neutral Al compounds, aluminum analogues of alkenes, have been a
184 create a class of steels, strengthened by Ni(Al,Fe) precipitates, with a strength of up to 2.2 gigapa
185                        The ferritic Fe-Cr-Ni-Al-Ti alloys strengthened by hierarchical-Ni2TiAl/NiAl o
186 ls as follows: Mo/CZTSSe/CdS/i-ZnO/Al:ZnO/Ni/Al.
187 icating the distribution of Si(-O-Si)4-n (-O-Al)n species is spatially biased as opposed to being ran
188 duction of Mg and Ta and approximately 5% of Al, Cu, and Sn.
189 n only be modeled with a few combinations of Al positioning at tetrahedral sites in the crystal unit
190 he formation of anionic chelate complexes of Al(III) and Cr(VI) with o-hydroxy azo dye, at pH 6.5, an
191 nts on a decagonal phase with composition of Al-15at%Ni-15at%Co.
192 on and subsequent intergranular corrosion of Al-5.3 wt.% Mg alloy has been shown to be an important f
193 rtant factor in stress corrosion cracking of Al-Mg alloys.
194 ty loading at the site, and the depletion of Al mineral buffering capacity after approximately 5 year
195 ics is required for the proper deployment of Al resistance responses in the root.
196  highly selective and sensitive detection of Al(3+) in 100% water at physiological pH.
197 successfully applied to the determination of Al and Cr in vegetables using standard addition method.
198 ial chelator in the practical development of Al(3+) selective nanobiosensor is unprecedented.
199                            For the effect of Al ions, we examined ternary mixtures of MnO2, Al ions,
200                       The energy gap (Eg) of Al-TiO2 nanoparticles decreases due to Al ion doping int
201 and are successfully produced in the form of Al-2Nb-xB (x = 0.5, 1 and 2) master alloys.
202 h temperature effective for the formation of Al-based high-strength nanostructured bulk alloys by war
203                         The incorporation of Al and increased curing temperature promotes the crystal
204                    However, the influence of Al-induced structural changes on the mechanical properti
205      Our study shows that the inoculation of Al-10Si braze alloy with these compounds effectively pro
206                               Three kinds of Al-TiO2 samples and pure TiO2 samples were synthesized v
207 imethylsiloxane, and a bottom layer, made of Al.
208 er, is inserted between a top layer, made of Al/polydimethylsiloxane, and a bottom layer, made of Al.
209 companied by a larger outwards relaxation of Al from the bulk positions.
210 ussed here investigate the shock response of Al microstructures comprising of grain sizes ranging fro
211 vatives on color expression and stability of Al(3+) and Fe(3+) chelates in pH 6-7 were evaluated by s
212  attempt was made to enhance the strength of Al-6wt%Si-2wt%Fe model recycled cast alloy with differen
213 of clean (111), (100), and (110) surfaces of Al, Cu, Ru, Rh, Pd, Ag, Pt, and Au.
214 a successful example of the transmutation of Al atoms into Si atoms by electron donation.
215                                 Two types of Al matrix zones were identified in the composite: (1) th
216 urements show that the elastic behaviour of (Al,Fe)-bearing bridgmanite is markedly different from th
217     Hence, with the required combination of [Al] and [B], a highly selective hydrosilylative reductio
218     Finally, transparent conductors based on Al-doped Ag possess both a high and flat transmittance o
219 emical stability up to at least 4 V vs Mg on Al electrodes.
220 we report single-crystal elasticity data on (Al,Fe)-bearing bridgmanite (Mg0.9Fe0.1Si0.9Al0.1)O3 meas
221                                         Only Al derived from the clay exceeded the minimum inhibitory
222 ion of a Lewis acid (e.g., E(C6F5)3 E = B or Al) with a small molecule substrate and decamethylferroc
223 h preferentially occurred as nanogoethite or Al/Si-substituted goethite.
224 nsist of densely packed LixM (M = Si, Sn, or Al) nanoparticles encapsulated by large graphene sheets.
225 ne axis was found to be different from other Al-based DQCs.
226                         The evolution of pH, Al, and Fe were closely linked; field observations were
227 oduced the general patterns of salinity, pH, Al, and Fe during an uncontrolled river breach in 2011,
228 Cp*2Fe][PhSB(C6F5)3] 1 and [Cp*2Fe][(mu-PhS)(Al(C6F5)3)2] 2 and [Cp*2Fe][(mu-PhTe)(Al(C6F5)3)2] 3, re
229 u-PhS)(Al(C6F5)3)2] 2 and [Cp*2Fe][(mu-PhTe)(Al(C6F5)3)2] 3, respectively.
230 cate glass cross-cutting lower melting-point Al-Cu-Fe alloys, as well as unambiguous evidence of a re
231 microstructural evolution of polycrystalline Al microstructures at the mesoscales.
232 photocatalytic properties of the as-prepared Al-TiO2 nanoparticles were studied.
233 o Al (2Al sites) is consistent with a random Al siting in the SSZ-13 lattice subject to Lowenstein's
234 y and the tensile properties of the recycled Al-Si alloys due to the presence of the Fe containing in
235 s, that mu-methylene structures (Al-CH2-ReO3-Al) containing a Re horizontal lineO bound to a tricoord
236 n strength due to addition of Cu, in Fe-rich Al-Si alloys is promising from the alloy recyclability p
237 sing an inclined c-axis ZnO grown on a rough Al electrode.
238 tallographically, revealing an additional Ru-Al interaction next to the Ru-H and Al-S bonds.
239 cant differences in the amounts of Na, K, S, Al, Mn, Ni, As and Cd were observed between conventional
240 als, including C (and organic carbon), N, S, Al, Fe, Mn, Cu, Zn, As, Cd, Cr, Ni, and Pb.
241       However, in a recent issue of Science, Al Jord et al. (2017) show that key regulators of the mi
242 with models for sensitisation in 5xxx series Al-alloys.
243 three-dimensional structure of corner-shared Al(BO3 )3 O polyhedra.
244 extraction of zeolite framework cations (Si, Al) on a faujasite-type zeolite, the archetype of molecu
245                     CIT-9 has the highest Si/Al ratio reported for GME, and along with its good poros
246 nthesis protocols applied here and across Si:Al ratios, the volumetric density of six-membered-rings
247 ites in 6r, favored at low values of both Si:Al and Cu:Al ratios, inhibit the material performance by
248 can be explained by the formation of soluble Al-F complexes and some dissolution of the Al(OH)3 preci
249  calculations, that mu-methylene structures (Al-CH2-ReO3-Al) containing a Re horizontal lineO bound t
250            The rechargeable aluminum/sulfur (Al/S) battery is of great interest owing to its high ene
251    Crack-free semi-polar [Formula: see text] Al x Ga1-x N epilayers with AlN contents up to x = 0.56
252                  These results indicate that Al(3+)-induced reduction of root growth could be associa
253                            Here we show that Al toxicity plays a central role in the antibacterial ac
254 ced bioimaging methods and genetic show that Al(3+) misfolds cell membrane proteins, while Fe(2+) evo
255 cal analysis of AMZ and bacteria showed that Al, P, and transition metals (Fe, Cu, Mn, and Zn) were e
256  of membrane permeabilization, suggests that Al reacts with membrane phospholipids, enhancing intrace
257                                          The Al-TiO2 nanoparticles prepared from Al(NO3)39H2O exhibit
258                                          The Al=Al double bond is elusive in chemistry.
259 cial role of the substrate structure and the Al(OtBu)3 additive on the kinetics and thermodynamics of
260                     The dislocations and the Al/B4C interfaces provide more heterogeneous nucleation
261 e through-plane thermal conductivity and the Al/TMD interface conductance depend on the modulation fr
262 ula: see text] to [Formula: see text] as the Al-concentration increased, and for Mg-Zn alloys, this d
263 nd along the recovered interface between the Al and permalloy.
264  P was observed at the interface between the Al matrix and eutectic Si, strongly indicating that P, i
265 ur kinds of samples, followed in turn by the Al-TiO2 nanoparticles prepared with AlCl3, Al2(SO4)318H2
266  oxygen pressure to 10(-6) Torr enriched the Al site occupancy fraction at the outermost surface from
267 cal ordering, and by selectively etching the Al and Sc atoms, we show evidence for 2D Mo1.33C sheets
268 to transform the beta-Al9Fe2Si2 phase in the Al-Si-Fe system.
269 n), may have nucleated on the surface of the Al matrix and thereby enhanced the heterogeneous nucleat
270                         The roughness of the Al surface is controlled by changing the substrate tempe
271 e Al-F complexes and some dissolution of the Al(OH)3 precipitate.
272 xperimental evidence on the influence of the Al-induced atomistic configurational change on the mecha
273 the present thermodynamic description of the Al-Si-Fe-Cu system needs finer tuning to accurately pred
274 gy, phase purity and the defect sites of the Al-TiO2 nanoparticles.
275         The photocatalytic activities of the Al-TiO2 samples were investigated by the degradation of
276 d Fe-Si beads, aluminous spinel rinds on the Al-Cu-Fe alloys, and Al2O3 enrichment in the silicate me
277 ion at the Ru-S bond, formally splitting the Al-H linkage into hydride and an alumenium ion.
278 The new evidence firmly establishes that the Al-Cu-Fe alloys (including quasicrystals) formed in oute
279 bsequent heat flow from the hotter Au to the Al rear surface is detected by two simultaneous time-res
280               The approach is similar to the Al-Eigen approach of Di Lena et al. (2010) , but with im
281  in the ion beam, including the one with the Al=Al double bond.
282 on junctions formed by InAs nanowires and Ti/Al superconducting leads.
283 g) of Al-TiO2 nanoparticles decreases due to Al ion doping into TiO2.
284                                  Exposure to Al resulted in up-regulation of a large set of genes onl
285 ments show that this species is proximate to Al atoms, similar to the Bronsted acid site proton.
286  severe root growth reduction in response to Al.
287 MATE66 rendered hairy roots more tolerant to Al(3+) toxicity.
288 ansparent conducting oxide nature of the top Al:ZnO film can be tuned to facilitate the fine control
289 ther the basic Al(I) center or the transient Al horizontal lineNTol species deprotonates the methyl g
290 e horizontal lineO bound to a tricoordinated Al (AlIII) and CH2 bound to a four-coordinated Al (AlIVb
291 y of six-membered-rings (6MR) containing two Al (2Al sites) is consistent with a random Al siting in
292 rbolic metamaterials consisting of ultrathin Al-doped Ag films are attained having a homogeneous and
293 ad less root growth than the wild type under Al(3+) stress, and seedlings were chlorotic under Fe-def
294  mass and composition was investigated using Al-referenced enrichment factors (EFs) and source factor
295 based on VACNT grown on aluminum foil (VACNT-Al foil) with poly (9,9-di-(2-ethylhexyl)-fluorenyl-2,7-
296 rect interaction of the bacterial cells with Al NPs and elucidate the nanoshielding mechanism via UV
297 ring where silicate melt was in contact with Al-Cu-Fe alloys.
298  solar cells as follows: Mo/CZTSSe/CdS/i-ZnO/Al:ZnO/Ni/Al.
299 glass/indium tin oxide/NiO(x)/perovskite/ZnO/Al), in which the ZnO layer isolates the perovskite and
300 ll-inorganic solar cells (ITO|NiOx |BiOI|ZnO|Al) with negligible hysteresis and up to 80% external qu

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