ライフサイエンスコーパス: periodic table

1 trends in series of compounds throughout the Periodic Table.

2 rease of proton affinity down a group in the periodic table.

3 reases when moving from right to left in the periodic table.

4 be useful synthons for chemistry across the periodic table.

5 coming from the same row 2 <= n <= 4 in the periodic table.

6 ng of high-valent metal complexes across the periodic table.

7 d to five non-inert end groups of the modern periodic table.

8 y metals and alloys that involve most of the periodic table.

9 n be developed from about 64 elements in the periodic table.

10 iple radioactive materials across the entire Periodic Table.

11 onally ascribed to more noble members of the periodic table.

12 Lab., SAND-89-1685] in ELECTR for the entire periodic table.

13 ls that covers a significant fraction of the periodic table.

14 properties among the least understood in the periodic table.

15 ered embrace most of the metal groups of the Periodic Table.

16 weakening chemistry to more elements in the periodic table.

17 rrelate with their d orbital energies across periodic table.

18 group of metals that lie at the edge of the periodic table.

19 understanding of chemical bonding across the periodic table.

20 the known teflate-based compounds across the periodic table.

21 nization with potential to expand across the periodic table.

22 roadly inform this element's position on the Periodic Table.

23 and comprehensive irradiation of the entire periodic table.

24 zine B-H bond addition to any element of the Periodic Table.

25 ous material compositional spaces across the periodic table.

26 trends in inner-sphere hydration across the periodic table.

27 erse changes over time as stars populate the periodic table.

28 ome of the most complicated chemistry in the periodic table.

29 these transition metals are neighbors in the periodic table.

30 -substrate coupling, down the columns of the periodic table.

31 the other elements in the same column of the periodic table.

32 ctively contain nearly all the metals in the periodic table.

33 new area of chemistry for metals across the periodic table.

34 ral organization of protein complexes into a periodic table.

35 tal situated between mercury and lead in the periodic table.

36 o palladium, and tungsten to platinum in the periodic table.

37 with virtually all available elements of the periodic table.

38 e degree of criticality of the metals of the periodic table.

39 probe the predictive power of trends in the periodic table.

40 ons including almost all the elements of the periodic table.

41 e chemistry and a basic understanding of the periodic table.

42 ope, usually in the lanthanide series of the periodic table.

43 e degree of criticality of the metals of the periodic table.

44 dination complexes with most elements of the periodic table.

45 y in supporting metallic elements across the periodic table.

46 e degree of criticality of the metals of the periodic table.

47 patial resolution and sensitivity across the periodic table.

48 rs, which mimic virtually all members of the periodic table.

49 that we have reached the end of a predictive periodic table(1).

50 ng periodicity and bonding trends across the periodic table(1-3), with a twenty-first-century renaiss

51 f these elements are among the lowest on the periodic table, a fact that has led to an interest in de

52 ocesses have been demonstrated that span the periodic table, a greater understanding of the surface c

53 an unfilled 3d shell and are adjacent in the periodic table: according to this criterion, the product

54 able, diverse inorganic materials across the periodic table and can further be fine-tuned to steer th

55 vices were introduced, including the PubChem Periodic Table and Element pages, Pathway pages, and Kno

56 Boron is carbon's neighbour in the periodic table and has similar valence orbitals.

57 xhibit behaviors reminiscent of atoms in the periodic table and hence can be regarded as superatoms f

58 r organic and inorganic compounds across the periodic table and new simulation methods to evaluate sy

59 epts such as the underlying structure of the periodic table and structure-property relationships in m

60 fferent elements of the p and d block of the periodic table and the self-assembly processes driven by

61 atic bonding to the heaviest elements in the periodic table and to principal quantum number six, and

62 LD) precursors, which span metals across the periodic table and which include ligands from four disti

63 ty, joining different areas across the whole periodic table, and discussing historical milestones and

64 e valences, like some of the elements in the periodic table, and hence have the potential to form sta

65 Trends across the periodic table are derived from three commonly used clos

66 ees , the first 35 predicted elements of the periodic table are discovered.

67 Periodic tables are related one to another through symme

68 powerful classification systems, such as the periodic table, are typically time independent.

69 oxo cations formed by metals from across the periodic table-are particularly inert, which explains th

70 or 54 different elemental systems across the periodic table as well as alloys.

71 metal block (i.e. Ni-, Pd-, and Pt-) of the periodic table at a photon energy of 2.33 eV (532 nm).

72 sidered the two most similar elements on the periodic table, based on their coexistence in nature and

73 ows for simple analysis of nearly the entire periodic table because most elements will readily produc

74 The diagonal relationship in the periodic table between phosphorus and carbon has set an

75 ion of nanochemistry to a larger part of the periodic table, beyond the typical gamut of II-VI, IV-VI

76 noble gases are the most inert group of the periodic table, but their reactivity increases with pres

77 mpounds for several transition metals in the periodic table, but this has mostly been limited to coor

78 While virtually every metal on the Periodic Table can form discrete clusters of some type,

79 presents a transformative step towards cross-periodic table computational design of metal complex che

80 lly possible that some other elements in the periodic table could serve the same functions.

81 A periodic table database of programmed primary structures

82 The review is organized according to the Periodic Table, describing free-base and main-group elem

83 es the most complicated phase diagram in the periodic table, driven by the complexities of overlappin

84 nation chemistry lags behind the rest of the Periodic Table due to its limited availability, lack of

85 , motions ordered by kinetic energy into the periodic table, each table characteristic of the spheric

86 in the bridge and core, covering much of the periodic table, eccentric heteroatom doping, and bridge

87 Despite its proximity to carbon in the periodic table, elemental boron clusters have been scarc

88 ion analytes covering essentially the entire periodic table, employing fluorescent DNA-like chemosens

89 why many low-coordinate complexes across the periodic table exhibit a geometry that is bent, rather a

90 elated sequences are in some respects like a periodic table for biology, allowing us to understand th

91 exciting prospect of a new dimension of the periodic table formed by cluster elements, called supera

92 nd were analyzed for 45 solutes spanning the periodic table from H(+) to U.

93 among monocations, going down Group 1 of the periodic table from Li(+) to Cs(+), PFL-AE activity shar

94 Metal ions from across the periodic table, from main group elements, transition met

95 and pai-hole bonds should be named after the Periodic-Table group to which the electrophile belongs o

96 er of valence electrons, and position on the periodic table (group number) influence the structure pr

97 convex hulls of element-pair systems across periodic table groups, indicating its capability to effe

98 -heterocyclic carbenes as ligands across the Periodic Table had an impact on various aspects of the c

99 anthanoid series, and actinoid series in the periodic table has at least two CompACs.

100 f group III through group VI elements on the periodic table have already demonstrated exciting proper

101 en, numerous metal complexes from across the periodic table have been shown to selectively activate h

102 s, no elements outside groups 4 to 12 of the periodic table have yet been shown to react directly wit

103 Its Biochemical Periodic Tables have grown to include biological informa

104 polymers and contain various elements of the periodic table, in particular metals such as Ca, Al, Na,

105 have been reported with most elements of the periodic table, including Group 14 Si, Ge, Sn, and Pb.

106 rved trends in bond strengths throughout the periodic table, including main group and transition meta

107 synthesized using several elements from the periodic table, including those with metal nodes contain

108 ult, the EA for the heaviest elements of the periodic table is entirely uncharted.

109 l crossings where the shell structure of the periodic table is reordered.

110 ight to the left side of the same row of the periodic table is responsible for these effects.

111 g red shifts in metalloporphyrins across the periodic table is retained for this series.

112 calization for elements down a column of the periodic table is widely recognized, its influence on ch

113 In this International Year of the Periodic Table (IYPT), we ponder whether a Pairiodic Tab

114 O, N, S) with many more elements across the periodic table (Li, B, Mg, Si, Cl, Ca, Ti, V, Cr, Fe, Ni

115 is perspective, we argue against an atlas or periodic table-like discretization as the right metaphor

116 This unique placement in the periodic table makes catenated nitrogen compounds of int

117 of the positions and oxidation states of the Periodic Table neighbors Fe and Mn in 3 has been achieve

118 f the positions and oxidation states for the periodic table neighbors in the heterometallic assemblie

119 ell established, at the other extreme on the periodic table novel properties of iodous materials may

120 gh-pressure conditions, the 'superconducting periodic table' now extends to all classes of the elemen

121 We also highlight how the concept of a periodic table of cell types could be useful for predict

122 this Hypothesis article, we propose that a 'periodic table of cell types' can be used as a framework

123 aking of atomic orbitals used to explain the periodic table of chemical elements; here we introduce a

124 points of entry into the CC+ Database: the 'Periodic Table of Coiled-coil Structures', which present

125 le of chemical elements; here we introduce a periodic table of droplet motions, also based on symmetr

126 ical symbols of the metals in a style of the periodic table of elements, it could be possible for suc

127 Here, we assessed memory for symbols on the periodic table of elements, which could be presented in

128 Here, we examine the concept of a periodic table of niches and feasibility of niche classi

129 ning up the best opportunity to complete the periodic table of the atomic anions.

130 emical behaviors reminiscent of atoms in the periodic table, offering the exciting prospect of a new

131 of the special location of plutonium in the periodic table, on the border between the light and heav

132 search avenues for alloy combinations in the periodic table, opening numerous possibilities in novel-

133 The periodic table provides an intuitive framework for under

134 ompanies a large number of metal ions in the periodic table ranging from lithium to neptunium.

135 ght some of the common trends throughout the periodic table, such as the differences between coordina

136 insteinium (Es), the heaviest element on the periodic table that can currently be generated in quanti

137 tion phenomenon: a fundamental aspect of the periodic table that is quoted in general chemistry textb

138 Es) consist of a very important group in the periodic table that is vital to many modern technologies

139 Across the periodic table the trans-influence operates, whereby tig

140 been used extensively as a ligand across the periodic table, the chemistry of its heavier group 15 co

141 M bond is covalent, but upon moving down the Periodic Table, the CSB character increases.

142 ium are in the same group (Family VI) in the periodic table, the site-specific mutagenesis at the ato

143 nanostructures on most of the metals in the periodic table, their compounds, or alloys by a one-step

144 the isoelectronic elements appearing on the periodic table, thereby quantifying the superatom concep

145 Moving down the periodic table (Ti to Hf) has a marked effect on the exp

146 ites descending along the ninth group of the periodic table to elucidate the emerging properties as d

147 ing, as nitrogen is uniquely situated in the periodic table to form kinetically stable compounds ofte

148 city in the following) and the column of the Periodic Table to which the set of donor atoms belongs (

149 esides these data, it includes a Biochemical Periodic Table (UM-BPT) and a rule-based Pathway Predict

150 stabilization of the heaviest 4+ ion of the periodic table, under mild aqueous conditions, using a s

151 ement was not included in the p-block of the periodic table until more recently.

152 of activity devoted to its neighbours in the periodic table, uranium and plutonium.

153 nanoparticle systems (groups 8 to 11 in the Periodic Table) using density functional theory (DFT) an

154 tion (XRD)-determined complexes spanning the periodic table, we demonstrate quantitative agreement be

155 By irradiating the entire periodic table, we observed similar performance between

156 In the f block of the periodic table, well-known oxidation states in compounds

157 ll understood for actinides (elements in the periodic table with atomic numbers from 89 to 103) based

158 tal ions are among the most important in the periodic table with blood plasma levels of H(+), Na(+) a

159 ons between some of the heaviest ions in the periodic table with little or no bulky-substituent prote

160 s having compositions throughout much of the periodic table, with different structures and thermal st