Raji Chem World Search Engine
Custom Search
Saturday, October 29, 2011
Wednesday, October 26, 2011
Pyridine synthesis from oximes and alkynes via rhodium(iii) catalysis: Cp* and Cpt provide complementary selectivity
Tomislav Rovis, Chem. Commun., 2011, 47, 11846-11848
Tuesday, October 25, 2011
Participation of Carbonyl Oxygen in Carbon–Carboxylate Bond-Forming Reductive Elimination from Palladium - Organometallics (ACS Publications)
Melanie S. Sanford, Organometallics, 2011, DOI: 10.1021/om200677y
Palladium(II) Agostic Complex: Exchange of Aryl–Pd and Alkyl–Pd Bonds
Organometallics, 2011, DOI: 10.1021/om200451v
Oxidative C–H Homodimerization of Phenylacetamides
Michael F. Greaney, 2011, OL, DOI: 10.1021/ol202212f
Palladium(II)-Catalyzed Dehydrogenative Alkenylation of Cyclic Enaminones via the Fujiwara–Moritani Reaction
2011, OL, DOI: 10.1021/ol202677g
TEMPO Oxoammonium Salt-Mediated Dehydrogenative Povarov/Oxidation Tandem Reaction of N-Alkyl Anilines
OL, 2011, DOI: 10.1021/ol202552y
Cu(II) Catalyzed Imine C–H Functionalization Leading to Synthesis of 2,5-Substituted 1,3,4-Oxadiazoles
OL, 2011, DOI: 10.1021/ol202409r
Synthesis of Isochromene and Related Derivatives by Rhodium-Catalyzed Oxidative Coupling of Benzyl and Allyl Alcohols with Alkynes
Palladium-Catalyzed Intramolecular C–H Activation/C–C Bond Formation: A Straightforward Synthesis of Phenanthridines
JOC, 2011, DOI: 10.1021/jo2017108
Palladium-Catalyzed Coupling of Arene C–H Bonds with Methyl- and Arylboron Reagents Assisted by the Removable 2-Pyridylsulfinyl Group
J. Org. Chem, 2011, DOI: 10.1021/jo2018137
Innate and Guided C–H Functionalization Logic
Phil S. Baran, Acc. Chem. Res., 2011,DOI: 10.1021/ar200194b
Rare-Earth-Catalyzed C–H Bond Addition of Pyridines to Olefins
Zhaomin Hou, 2011, JACS, DOI: 10.1021/ja208129t
Nickel-Catalyzed Dehydrogenative [4 + 2] Cycloaddition of 1,3-Dienes with Nitriles
Sensuke Ogoshi, JACS, 2011, DOI: 10.1021/ja208162w
Ligand-Accelerated Cross-Coupling of C(sp2)–H Bonds with Arylboron Reagents
Jin-Quan Yu, JACS, 2011, DOI: 10.1021/ja203978r
Thursday, October 20, 2011
Cobalt-Catalyzed, Room-Temperature Addition of Aromatic Imines to Alkynes via Directed C–H Bond Activation
Naohiko Yoshikai, JACS 2011, DOI: 10.1021/ja2047073
Synthesis of Functionalized 1H-Indenes via Copper-Catalyzed Arylative Cyclization of Arylalkynes with Aromatic Sulfonyl Chlorides
Eiichi Nakamura, JACS 2011, DOI: 10.1021/ja209300c
Synthesis of Catechols from Phenols via Pd-Catalyzed Silanol-Directed C–H Oxygenation
A silanol-directed, Pd-catalyzed C–H oxygenation of phenols into catechols is presented. This method is highly site selective and general, as it allows for oxygenation of not only electron-neutral but also electron-poor phenols. This method operates via a silanol-directed acetoxylation, followed by a subsequent acid-catalyzed cyclization reaction into a cyclic silicon-protected catechol. A routine desilylation of the silacyle with TBAF uncovers the catechol product.
Vladimir Gevorgyan, JACS 2011, DOI: 10.1021/ja208572v
Concentration of Acids and Bases
Properties of various acids and bases
The data in the following table (except MW) is approximate and should only be used as an estimate. Concentrations change upon exposure to air.
Reagent
|
Formula
|
Molecular Weight (g/mol)
|
Specific gravity
|
Normality of conc. reagent
|
Weight %
|
V (mL)*
|
Acetic acid (glacial)
|
CH3CO2H
|
60.05
|
1.05
|
17.45
|
99.8
|
57.3
|
Ammonium hydroxide
|
NH4OH
|
35.05
|
0.90
|
14.53
|
56.6
| |
Ethylene diamine
|
C2H4(NH2)2
|
60.10
|
0.899
|
15.0
|
100
|
66.7
|
Formic acid
|
HCO2H
|
46.03
|
1.20
|
23.6
|
90.5
|
42.5
|
Hydrazine
|
N2H4
|
32.05
|
1.01
|
30.0
|
95
|
33.3
|
Hydriodic acid
|
HI
|
127.91
|
1.70
|
7.6
|
57
|
132
|
Hydrobromic acid
|
HBr
|
80.92
|
1.49
|
8.84
|
48
|
113
|
Hydrochloric acid
|
HCl
|
36.46
|
1.19
|
12.1
|
37.2
|
82.5
|
Hydrofluoric acid
|
HF
|
20.0
|
1.18
|
28.9
|
49.0
|
34.5
|
Nitric acid
|
HNO3
|
63.01
|
1.42
|
15.9
|
70.4
|
63
|
Perchloric acid
|
HClO4
|
100.47
|
1.67
|
11.7
|
70.5
|
85.5
|
Phosphoric acid
|
H3PO4
|
97.10
|
1.70
|
14.8
|
85.5
|
67.5
|
Pyridine
|
C5H5N
|
79.10
|
0.982
|
12.4
|
100
|
80.6
|
Sulfuric acid
|
H2SO4
|
98.08
|
1.84
|
18.0
|
96
|
55.8
|
Triethanolamine
|
C6H15NO3
|
149.19
|
1.124
|
7.53
|
100
|
132.7
|
* V (mL) = volume in milliliters needed to prepare 1 L of 1 molar solution (1 M)
Approximate pH for different concentrations of various substances
Reagent
|
1 N
|
0.1 N
|
0.01 N
|
0.001 N
|
Acetic acid (glacial)
|
2.4
|
2.9
|
3.4
|
3.9
|
Ammonia
|
11.8
|
11.3
|
10.8
|
10.3
|
Benzoic acid
|
3.1
| |||
Citric acid
|
2.1
|
2.6
| ||
Hydrochloric acid
|
0.10
|
1.07
|
2.02
|
3.01
|
Hydrogen cyanide
|
5.1
| |||
Potassium hydroxide
|
14.0
|
13.0
|
12.0
|
11.0
|
Sodium bicarbonate
|
8.4
| |||
Sodium carbonate
|
11.5
|
11.0
| ||
Sodium hydroxide
|
14.05
|
13.07
|
12.12
|
11.13
|
Sulfuric acid
|
0.3
|
1.2
|
2.1
|
Equivalences % / M / N and preparation
The following table lists equivalences between molarities, normalities and percent solutions along with volume of desired substance needed to make 1 L of molar solutions.
HCl
|
0.01 M
|
0.1 M
|
1 M
|
2 M
|
3 M
|
5 M
|
6 M
|
10 M
|
12.1 M
|
Normality
|
0.01 N
|
0.1 N
|
1 N
|
2 N
|
3 N
|
5 N
|
6 N
|
10 N
|
12.1 N
|
% equivalent
|
0.08%
|
0.8%
|
8%
|
17%
|
25%
|
41%
|
50%
|
83%
|
100%
|
V needed to make 1 L
|
0.83 mL
|
8.3 mL
|
83 mL
|
165 mL
|
248 mL
|
413 mL
|
496 mL
|
826 mL
|
1000 mL
|
H2SO4
|
0.01 M
|
0.1 M
|
1 M
|
2 M
|
3 M
|
5 M
|
6 M
|
9 M
|
10 M
|
12 M
|
15 M
|
18 M
|
Normality
|
0.02 N
|
0.2 N
|
2 N
|
4 N
|
6 N
|
10 N
|
12 N
|
18 N
|
20 N
|
24 N
|
30 N
|
36 N
|
% equivalent
|
0.06%
|
0.56%
|
5.6%
|
11%
|
17%
|
28%
|
33%
|
50%
|
56%
|
67%
|
83%
|
100%
|
V needed to make 1 L
|
0.56 mL
|
5.6 mL
|
56 mL
|
111 mL
|
167 mL
|
278 mL
|
333 mL
|
500 mL
|
556 mL
|
667 mL
|
833 mL
|
1000 mL
|
NaOH
|
0.01 M
|
0.1 M
|
1 M
|
2 M
|
5 M
|
10 M
|
15 M
|
20 M
|
25 M
|
27 M
|
Normality
|
0.01 N
|
0.1 N
|
1 N
|
2 N
|
5 N
|
10 N
|
15 N
|
20 N
|
25 N
|
27 N
|
weight needed to make 1 L
|
0.40 g
|
4.0 g
|
40 g
|
80 g
|
200 g
|
400 g
|
600 g
|
800 g
|
1000 g
|
1080 g
|
KOH
|
0.01 M
|
0.1 M
|
1 M
|
2 M
|
5 M
|
10 M
|
15 M
|
20 M
|
21 M
|
Normality
|
0.01 N
|
0.1 N
|
1 N
|
2 N
|
5 N
|
10 N
|
15 N
|
20 N
|
21 N
|
weight needed to make 1 L
|
0.56 g
|
5.61 g
|
56.1 g
|
112 g
|
280 g
|
561 g
|
841 g
|
1120 g
|
1178 g
|
Wednesday, October 19, 2011
Tuesday, October 18, 2011
Tuesday, October 11, 2011
Rhodium-Catalyzed Annulation of N-Benzoylsulfonamide with Isocyanide through C[BOND]H Activation
DOI: 10.1002/chem.201102475
Monday, October 10, 2011
A Diruthenium Catalyst for Selective, Intramolecular Allylic C–H Amination
A Diruthenium Catalyst for Selective, Intramolecular Allylic C–H Amination: Reaction Development and Mechanistic Insight Gained through Experiment and Theory
JACS, 2011, DOI: 10.1021/ja203576p
Saturday, October 1, 2011
Rhodium(III)-Catalyzed Oxidative Coupling of 5-Aryl-1H-pyrazoles with Alkynes and Acrylates
Abstract
[RhCp*Cl2]2-catalyzed oxidative coupling of 5-aryl-1H-pyrazoles with alkynes and acrylates has been achieved using Cu(OAc)2 as an oxidant. Coupling with alkynes afforded six-membered azacycles as a result of C–C and C–N coupling. Coupling with acrylates followed a process of diolefination and a subsequent aza-Michael cyclization.
Intermolecular Oxidative C–N Bond Formation under Metal-Free Conditions: Control of Chemoselectivity between Aryl sp2 and Benzylic sp3 C–H Bond
A new synthetic approach toward intermolecular oxidative C–N bond formation of arenes has been developed under transition-metal-free conditions. Complete control of chemoselectivity between aryl sp2 and benzylic sp3 C–H bond imidation was achieved by the choice of nitrogen sources, representatively being phthalimide and dibenzenesulfonimide, respectively.
Subscribe to:
Posts (Atom)