Author: Jessica.F

Hadei, Niloufar published the artcileThe First Negishi Cross-Coupling Reaction of Two Alkyl Centers Utilizing a Pd-N-Heterocyclic Carbene (NHC) Catalyst, SDS of cas: 69361-41-7, the publication is Organic Letters (2005), 7(17), 3805-3807, database is CAplus and MEDLINE.

The development of an NHC-based system capable of cross-coupling sp³-sp³ centers in high yield has been a long-standing challenge. This communication describes the use of a Pd-NHC catalytic system that achieves room-temperature Negishi cross-couplings of unactivated, primary bromides and alkyl organozinc reagents with a variety of functionality. E.g., alkyl-alkyl Negishi cross-coupling of PhCH₂CH₂CH₂Br and BuZnBr in presence of Pd₂(dba)₃ and 1,3-bis(2,6-diisopropylphenyl)imidazolium chloride gave up to 75% heptylbenzene.

Organic Letters published new progress about 69361-41-7. 69361-41-7 belongs to bromides-buliding-blocks, auxiliary class PROTAC Linker,Aliphatic Linker, name is (4-Bromobut-1-yn-1-yl)trimethylsilane, and the molecular formula is C7H13BrSi, SDS of cas: 69361-41-7.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary

Hadei, Niloufar published the artcileRoom-Temperature Negishi Cross-Coupling of Unactivated Alkyl Bromides with Alkyl Organozinc Reagents Utilizing a Pd/N-Heterocyclic Carbene Catalyst, COA of Formula: C7H13BrSi, the publication is Journal of Organic Chemistry (2005), 70(21), 8503-8507, database is CAplus and MEDLINE.

A high-yielding cross-coupling reaction of unactivated alkyl bromides possessing β-hydrogens with alkylzinc halides utilizing a Pd/N-heterocyclic carbene (NHC) catalyst at room temperature is described. A variety of Pd sources, Pd₂(dba)₃, Pd(OAc)₂, or PdBr₂, with the com. available ligand precursor 1,3-bis(2,6-diisopropylphenyl)imidazolium chloride successfully coupled 1-bromo-3-phenylpropane with n-butylzinc bromide in THF/NMP. An investigation of different NHC precursors showed that the bulky 2,6-diisopropylphenyl moiety was necessary to achieve high coupling yields (75-85%). The corresponding Et analog was moderately active (11%). A range of unsym. NHC precursors were prepared and evaluated. The ligand precursor containing one 2,6-diisopropylphenyl and one 2,6-diethylphenyl afforded the coupling product in 47% yield, clearly suggesting a direct relationship between the steric topog. created by the flanking N-substituents and catalyst activity. Under optimal conditions, a number of alkyl bromides and alkylzinc halides possessing common functional groups (amide, nitrile, ester, acetal, and alkyne) were effectively coupled (61-92%). It is noteworthy that β-substituted alkyl bromides and alkylzinc halides successfully underwent cross-coupling. Also, under these conditions alkyl chlorides were unaffected.

Journal of Organic Chemistry published new progress about 69361-41-7. 69361-41-7 belongs to bromides-buliding-blocks, auxiliary class PROTAC Linker,Aliphatic Linker, name is (4-Bromobut-1-yn-1-yl)trimethylsilane, and the molecular formula is C7H13BrSi, COA of Formula: C7H13BrSi.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary

Ndikuryayo, Ferdinand published the artcileHydrophobicity-oriented drug design (HODD) of new human 4-hydroxyphenylpyruvate dioxygenase inhibitors, Quality Control of 76283-09-5, the publication is European Journal of Medicinal Chemistry (2019), 22-31, database is CAplus and MEDLINE.

Involved in the tyrosine degradation pathway, 4-hydroxyphenylpyruvate dioxygenase (HPPD) is an important target for treating type I tyrosinemia. To discover novel HPPD inhibitors, we proposed a hydrophobicity-oriented drug design (HODD) strategy based on the interactions between HPPD and the com. drug NTBC. Most of the new compounds showed improved activity, compound d23 being the most active candidate (IC₅₀ = 0.047 μM) with about 2-fold more potent than NTBC (IC₅₀ = 0.085 μM). Therefore, compound d23 is a potential drug candidate to treat type I tyrosinemia.

European Journal of Medicinal Chemistry published new progress about 76283-09-5. 76283-09-5 belongs to bromides-buliding-blocks, auxiliary class Fluoride,Bromide,Benzyl bromide,Benzene, name is 4-Bromo-1-(bromomethyl)-2-fluorobenzene, and the molecular formula is C7H5Br2F, Quality Control of 76283-09-5.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary

Kim, Hyeokjun published the artcileContribution of dark current density to the photodetecting properties of thieno[3,4-b]pyrazine-based low bandgap polymers, Related Products of bromides-buliding-blocks, the publication is Dyes and Pigments (2022), 109910, database is CAplus.

Recently, near IR (NIR) organic photodetectors (OPDs) have been extensively studied. Bulk heterojunction NIR OPDs composed of a high-bandgap polymer donor (PD) and a low-bandgap non-fullerene acceptor (NFA) showed the best performance, whereas the low-bandgap PD-based OPDs were relatively unsuccessful due to the high level of dark c.d. (J_d) under a neg. bias. In this study, we synthesized three low-bandgap PDs based on a thieno[3,4-b]pyrazine (TP) moiety and developed red-NIR OPDs by blending them with a low-bandgap NFA. We found that the PD having a shallow HOMO energy level generated the largest ground-state electron transfer at neg. bias, which overestimated the responsivity (R) and detectivity (D*) in OPDs. Notably, under weak light irradiation of 0.1 mW/cm² at -2V, the contribution of J_d on J_ph reached 99.6%. Thus, we modified the existing R and D* equations to better understand photodetecting properties at low light intensity, and these modified equations gave more realistic R and D* values in OPDs. On the other hand, a low-bandgap PD showing low J_d in OPDs was highly beneficial to detect a low light signal because the J_d negligibly contributed to J_ph in OPDs. The low J_d values of OPDs at neg. bias resulted in a high on/off signal ratio and constant R and D* values at different light intensities.

Dyes and Pigments published new progress about 52431-30-8. 52431-30-8 belongs to bromides-buliding-blocks, auxiliary class Liquid Crystal &OLED Materials, name is 2,5-Dibromo-3,4-dinitrothiophene, and the molecular formula is C4Br2N2O4S, Related Products of bromides-buliding-blocks.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary

Unny, Divya published the artcileStarburst configured imidazole-arylamine organic sensitizers for DSSC applications, Recommanded Product: 1-Bromooctane, the publication is Journal of Photochemistry and Photobiology, A: Chemistry (2022), 113735, database is CAplus.

In this study, special consideration was given to the design and synthesis of imidazole-arylamine-based organic sensitizers with three arylamine donors (Carbazole, Triphenylamine and Phenothiazine) paired with cyanoacrylic acid acceptor to form D-D-A architecture. Phenothiazine-imidazole dye (PZIM) was found to be the best for DSSC applications in the D-D-A set. Hence, we further extended the conjugation of PZIM dye by three different spacers such as benzene (PZIMBe), thiophene (PZIMTh), and furan (PZIMFu) having different resonance energies, which resulted in the design of D-D-π-A. We have carried out the photo-phys., electrochem., and photovoltaic performance for these six dyes. The PZIM, PZIMTh and PZIMFu dyes were identified as the efficient among the six with an average power conversion efficiency of 7.0%, 7.10% and 7.30%, resp. Thiophene and furan outperformed benzene spacer as the best linkers in the D-D-π-A configuration. Grafting the bulky imidazole moiety onto the arylamine donor is considered to be a promising approach for tuning photovoltaic parameters by increasing the electron richness of the main electron donor core, increasing solubility, and suppressing aggregation.

Journal of Photochemistry and Photobiology, A: Chemistry published new progress about 111-83-1. 111-83-1 belongs to bromides-buliding-blocks, auxiliary class Bromide,Aliphatic hydrocarbon chain, name is 1-Bromooctane, and the molecular formula is C5H5NO3S, Recommanded Product: 1-Bromooctane.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary

Tang, Min-Min published the artcileRole of Rim Functions in Recognition and Selectivity of Small-Molecule Guests in Water-Soluble Cavitand Hosts, Safety of 1-Bromooctane, the publication is Chemistry – An Asian Journal (2022), 17(15), e202200466, database is CAplus and MEDLINE.

Groups on the upper rim of cavitands can play major roles in the recognition of small mols. Water-soluble deep cavitands 1, 2 or 3 bearing the walls upper rim of imidazole, urea, and Me urea, resp., were synthesized and characterized as hosts of small-mol. guests. The vase forms of 1 or 2 are stabilized through H-bonding to solvent water mols. between adjacent walls. Various small alkyl organic mols. – alcs., halides, cycloalkane derivatives and heterocycles – are efficiently bound in 1. For n-alcs. (C5 to C12), the -OH end is fixed at the upper rim and the alkyl parts are in the hydrophobic cavity. The longer alc. guests (C7-C12) show coiling. Cycloalkane guests rotate rapidly on all 3 axes within the host cavity, while heterocycles show orientations placing their heteroatoms near the cavitand rim. Competition studies between alkyl chlorides, bromides and iodides showed preference for binding of iodides in 1. Competition between cavitands for hexyl halide guests halide showed the order 2>1>3.

Chemistry – An Asian Journal published new progress about 111-83-1. 111-83-1 belongs to bromides-buliding-blocks, auxiliary class Bromide,Aliphatic hydrocarbon chain, name is 1-Bromooctane, and the molecular formula is C18H15N3O3, Safety of 1-Bromooctane.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary

v. Braun, Julius published the artcileTransformations of cyclopentadiene, Application of (2-Bromoethyl)cyclopentane, the publication is Berichte der Deutschen Chemischen Gesellschaft [Abteilung] B: Abhandlungen (1937), 1750-60, database is CAplus.

It had been found (C. A. 22, 1146) that 2-cyclopentyl chloride (I) reacts like allyl chloride with aromatic Grignard reagents and the resulting arylcyclopentenes take up HBr to form 2-arylcyclopentyl bromides As was expected, nonaromatic Grignard reagents act in the same way with I and addition of HBr to the products offers no difficulty but, contrary to the aromatic compounds, it results in the formation of 3-alkylcyclopentyl bromides. Their structure was proved by the reaction recently described (C. A. 28, 2329.3): replacement of the Br by CO₂H by means of Mg and CO₂, α-bromination of the acid, and conversion of the Br acid into the acid chloride which with NaN₃ gave a 3-alkylcyclopentanone. HBr thus adds to the alkylcyclopentenes in just the opposite way to its addition to the aryl compounds O and halogens, like Ph, attract electrons but their effect decreases rapidly with distance and, as was expected, β-2-cyclopentenylethyl alc. (II) heated with HBr gave, together with some of the unsaturated bromide (III), the saturated β-(3-bromocyclopentyl) ethyl bromide (IV). It was attempted to prove the structure of IV by replacing both Br atoms with CO₂H but the dicarboxylic acid could not be obtained pure. That, however, it was not the 2-Br compound was indicated by the fact that with 1 mol. malonic ester and 2 atoms Na it gave, along with high-mol. compounds, and a brominated ester of lower mol. weight, only a small amount (30%) of a compound C₁₄H₂₂O₂ (V). Had the ring-substituted Br in IV been in the 2-position, the strainless bicyclo (0.3.3)octane derivative would undoubtedly have been formed very smoothly. V is believed to be the bicyclo (1,2,3) octane It is decarboxylated to the monocarboxylic acid (VI) by means of which it is hoped to develop the field of these bicyclo compounds, representatives of which (with the exception of the Komppa ketone) are as yet known only in a few complex derivatives of the camphor series. Thus far it has not been possible to pass from IV to the parent hydrocarbon of the bicyclo(1.2.2.)heptane series; as was to be expected from the strain existing in the latter system, the action of Na on IV is exclusively extramol. and there results a mixture, boiling within wide limits, of hydrocarbons (C₇H₁₂)_n of varying mol. weight 2-Ethylcyclopentene (VII) (30% yield), b₇₆₈ 99-103°, d₄²⁰ 0.7874, n_D²⁰ 1.43030. It readily adds Br in CS₂ to form a liquid dibromide, b₁₂ 98-100°, faintly yellow but soon decomposing and darkening. 3-Bromo-1-ethylcyclopentane (65% from VII shaken 50 hrs. with 2-3 volumes fuming HBr), b₄₂ 84-6°, d₄²⁰ 1.2597. It reacts readily with Mg and when the product is treated with CO₂ and worked up in the usual way it gives the Na₂CO₃-insoluble 3,3′-diethylbicyclopentyl, b₁₅ 125°, d₄¹⁵ 0.8757, n_D²⁰ 1.47097, and the Na₂CO₃-soluble 3-ethylcyclopentanecarboxylic acid, b₁₅ 132-4°, whose acid chloride, b₁₁ 176-8°, with 1 mol. Br at 125° gives almost quantitatively the α-Br derivative, b₁₁ 110°, and this, in pyridine solution or suspension, heated with NaN₃, then treated with alc. and alkali, acidified with HCl after 15 min. and distilled with steam, yields 3-ethylcyclopentanone, b. 150°, forming a semicarbazone, m. 175°, and with m-O₂NC₆H₄CHO, alc. and a trace of alkali, a lemon-yellow condensation product, C₂₀H₁₈O₅N₂, m. 142°. 2-Isoamylcyclopenten (60%), b₅₉ 86-7°, does not darken on standing, d₄²² 0.7969. 3-Bromo-1-isoamylcyclopentane, b₁₅ 109-10°; 3-carboxylic acid, b₂₀ 160°, d₄^20.5 0.9566. 2-Dodecylcyclopentene (50%), b₁₅ 172°, d₄¹⁶ 0.8262, n_D²⁰ 1.45667. Addition of HBr requires long heating, a considerable part of the hydrocarbon remaining unattacked even after 15 hrs. The 3-bromo-1-dodecylcyclopentane b_0.1 163°, d₄^14.5 0.9811. Mg and CO₂ give, with some 3-carboxylic acid, m. 29°, chiefly dodecylcyclopentane, b₁₅ 175°, d₄¹⁸ 0.8280, n_D²⁰ 1.45737 and 3,3′-didodecylbicyclopentyl, b_0.2 260° (the latter is a semi-solid thick oil, probably consisting of a mixture of stereoisomers). The cyclopentene forms a dibromide, b_0.2 180° without appreciable decomposition but becomes discolored on standing. C₅H₉MgCl and I react very vigorously, yielding somewhat more than 60% 2-cyclopentenylcyclopentane, b₉ 60-4°, d₄²⁰ 0.8838; shaken 60 hrs. with fuming HBr, it gives almost 80% 3-bromobicyclopentyl, b₉ 115°, which with Mg and CO₂ yields bicyclopentyl, b₉ 67°, almost pure tetracyclopentyl, (C₅H₉C₅H_8^–)₂, b₉ 205-7°, and about 30% bicyclopentyl-3-carboxylic acid, b₁₃ 172°, d₄¹⁹ 1.0398; acid chloride, b₁₀ 125°, gives 70% of the α-Br derivative, faintly yellow, b_0.3 128-32°, which with NaN₃ yields 3-cyclopentylcyclopentanone, volatile with steam (oxime, b₁₀ 145-6°, m. 46°; semicarbazone, m. 184°; bis(m-nitro-benzal) derivative, yellow-red, m. 172°). 2-Cyclopentenyl-cyclohexane (60%), b₁₂ 80-5°, d₄¹⁸ 0.8995, n_D²⁰ 1.48698. 3-Bromo-l-cyclohexylcyclopentane (70%), b₁₁ 132-6°, becomes yellowish and splits off a little HBr on standing; Mg and CO₂ give cyclopentylcyclohexane, b₁₁ 86-8°, d₄²³ 0.8886, n_D²⁰ 1.47491, 15% 3,3′-dicyclohexylbicyclopentyl, b_0.1 180°, d₄¹⁸ 0.9592, n_D²⁰ 1.51290, and about 15% 3-cyclohexylcyclopentanecarboxylic acid, b₁₁ 180°, d₄¹⁷ 1.0343, n_D²⁰ 1.49255; the acid chloride, b₁₁ 142-4°, gives an α-Br derivative, b_0.05 140-2°, which with NaN₃ yields 3-cyclo-hexylcyclopentanone, b₁₀ 126°, d₄¹⁹ 0.9730, n_D²⁰ 1.48476 (semicarbazone, m. 186°; bis(m-nitrobenzal) derivative, orange, m. 122°). Et 2-cyclopentenylacetate, from the acid heated 3 hrs. on the water bath with 2 parts by weight of EtOH and 0.1 part concentrated H₂SO₄, b₁₂ 81°. With 10 atoms Na in EtOH it gives 70% II, b₁₅ 82-3°, d₄^23.5 0.9432, n_D²⁵ 1.4695, vigorously decolorizes KMnO₄, readily takes up 2 H atoms with Pd to give β-cyclopentylethyl alc. (also obtained from C₅H₉CH₂CO₂Et with Na and alc.), bit 84-5°,which with HBr at 100° gives almost 100% of the bromide, C₅H₉CH₂CH₂Br, b₁₁ 70-1°. The fraction b_0.4 below 100° (chiefly around 70°) of the product of the reaction of II with HBr and which consists chiefly of III with unchanged II, gives with NHMe₂ in benzene at 100° the unsaturated base, C₅H₇CH₂CH₂NMe₂, b₁₃ 66-8°, d₄²¹ 0.8291 (picrate, m. 136-8°; chloroplatinate, m. 148°; methiodide, m. 223°). IV, b_0.4 100°, darkens only on long standing. V, b₁₂ 155-60°; free dicarboxylic acid, powder, m. 189-90° (foaming) with formation of VI, b₁₃ 150-2°, d₄²⁶ 1.0603.

Berichte der Deutschen Chemischen Gesellschaft [Abteilung] B: Abhandlungen published new progress about 18928-94-4. 18928-94-4 belongs to bromides-buliding-blocks, auxiliary class Bromide,Aliphatic cyclic hydrocarbon, name is (2-Bromoethyl)cyclopentane, and the molecular formula is C16H14O6, Application of (2-Bromoethyl)cyclopentane.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary

Winum, Jean-Yves published the artcileStudy of the Michaelis-Arbuzov reaction during ultrasonic activation, HPLC of Formula: 66197-72-6, the publication is Phosphorus, Sulfur and Silicon and the Related Elements (1997), 83-88, database is CAplus.

The use of ultrasonic activation in Michaelis-Arbuzov reaction promote a byproduct in the case of silyl derivatives and in the synthesis of XCH₂P(O)(OEt)₂ (X = I Br). A mechanism is proposed in which the phosphite undergoes a nucleophilic attack on the quasiphosphonium ion in place of the halide species.

Phosphorus, Sulfur and Silicon and the Related Elements published new progress about 66197-72-6. 66197-72-6 belongs to bromides-buliding-blocks, auxiliary class Aliphatic Chain, name is Diethyl (bromomethyl)phosphonate, and the molecular formula is C18H23N3O4S, HPLC of Formula: 66197-72-6.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary

Szabo, L. P. published the artcileLaboratory scale resolution of short chain chiral carboxylic acid, Safety of 3-Bromo-2-methylpropanoic acid, the publication is Special Publication – Royal Society of Chemistry (1994), 496-504, database is CAplus.

Zeolite A was used as a support and onto the surface via ethylene-diamine spacer L-leucine, L-glutamic acid, L-lysine and L-phenylalanine were chem. bonded to prepare chiral stationary phases. The laboratory scale resolution of (+/-)-3-bromo-2-methyl-propionic acid (DL-BMPA) on these stationary phases was studied. The new packings proved to be efficient for the laboratory scale resolution of DL-BMPA.

Special Publication – Royal Society of Chemistry published new progress about 56970-78-6. 56970-78-6 belongs to bromides-buliding-blocks, auxiliary class Bromide,Carboxylic acid,Aliphatic hydrocarbon chain,Inhibitor, name is 3-Bromo-2-methylpropanoic acid, and the molecular formula is C13H17BF3NO2, Safety of 3-Bromo-2-methylpropanoic acid.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary

Savanur, Hemantkumar M. published the artcileLibraries of C-5 Substituted Imidazoles and Oxazoles by Sequential Van Leusen (VL)-Suzuki, VL-Heck and VL-Sonogashira in Imidazolium-ILs with Piperidine-Appended-IL as Base, Synthetic Route of 243455-57-4, the publication is European Journal of Organic Chemistry (2018), 2018(38), 5285-5288, database is CAplus.

Facile access to diverse C5-substituted imidazoles and oxazoles via sequential Van Leusen-Suzuki, Van Leusen-Heck, and Van Leusen-Sonogashira protocols, employing imidazolium-ILs as solvents along with piperidine-appended imidazolium [PAIM][NTf₂] as task-specific basic IL has been demonstrated, in a high-yielding one-pot method, starting with readily available aldimines (for imidazole) or aldehydes (for oxazole) and tosylmethyl isocyanide (TOSMIC), under mild conditions with potential for recycling and reuse of the IL solvent. The scope of the method is supported 49 examples.

European Journal of Organic Chemistry published new progress about 243455-57-4. 243455-57-4 belongs to bromides-buliding-blocks, auxiliary class Oxazole,Bromide,Benzene, name is 5-(3-Bromophenyl)oxazole, and the molecular formula is C9H6BrNO, Synthetic Route of 243455-57-4.

Referemce:
https://en.wikipedia.org/wiki/Bromide,
bromide – Wiktionary