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DMPU

N,N'-Dimethylpropyleneurea (DMPU), systematically known as 1,3-dimethyl-3,4,5,6-tetrahydro-2(1H)-pyrimidinone, is a cyclic derivative employed as a high-polarity, aprotic in . With the molecular formula C₆H₁₂N₂O and a molecular weight of 128.17 g/, it appears as a clear, colorless at . DMPU exhibits a low of approximately -20 °C, a high of 246–247 °C at standard pressure, and a of 1.06 g/mL at 25 °C, rendering it stable for reactions at elevated temperatures. It is fully miscible with water and most organic solvents, including polar and nonpolar varieties, due to its strong electron-pair donor ability from the . DMPU's space-demanding structure enhances its utility in coordination chemistry by promoting lower coordination numbers in metal complexes compared to less bulky solvents like DMF or DMSO. This property makes it particularly effective for solvating cations in organometallic reactions while avoiding proton donation, positioning it as a safer alternative to more toxic solvents such as (HMPA). In pharmaceutical and synthesis, DMPU facilitates challenging transformations, including the N-alkylation of chiral amines, O-alkylation of aldoses, and the of poly(aryl ethers). It also serves as a component in nucleophilic fluorination reagents like DMPU/ for diastereoselective synthesis of fluorinated heterocycles. Beyond synthesis, DMPU finds applications in and processing, where its high of 121 °C and thermal stability contribute to safer handling in settings. Despite its advantages, users must note its hygroscopic nature and potential for under basic conditions, which can limit long-term storage without proper precautions. Overall, DMPU's combination of solvating power, thermal resilience, and reduced has established it as a versatile tool in modern chemical research and manufacturing.

Nomenclature and Structure

Chemical Identity

DMPU, an abbreviation for N,N'-dimethylpropyleneurea, is a with the 1,3-dimethyl-1,3-diazinan-2-one. It is also systematically named 1,3-dimethyl-3,4,5,6-tetrahydro-2(1H)-pyrimidinone. Common synonyms include N,N'-dimethyltrimethyleneurea, reflecting its derivation from the parent propyleneurea structure, a cyclic based on a six-membered propylene-like chain. This nomenclature distinguishes it from the related dimethylethyleneurea (DMEU), which features a five-membered . The molecular formula of DMPU is C_6H_{12}N_2O, and its molecular weight is 128.17 g/mol. The is 7226-23-5.

Molecular Structure

DMPU possesses a cyclic urea structure characterized by a six-membered heterocyclic ring. This ring includes nitrogen atoms positioned at 1 and 3, a (C=O) at position 2, and a chain (CH₂-CH₂-CH₂) connecting the nitrogens at positions 4, 5, and 6. Each nitrogen atom bears a methyl (N-CH₃), which defines its systematic name as 1,3-dimethyl-3,4,5,6-tetrahydro-2(1H)-pyrimidinone and yields the molecular formula C₆H₁₂N₂O. The of DMPU can be visualized as a saturated six-membered , akin to a partially reduced pyrimidinone, where the connectivity is N¹(CH₃)-C²(=O)-N³(CH₃)-CH₂⁴-CH₂⁵-CH₂⁶, closing back to N¹. This arrangement is commonly represented in SMILES notation as CN1CCCN(C)C1=O, highlighting the tetrahedral geometry around the atoms excluding the planar carbonyl. The carbonyl carbon exhibits sp² hybridization, facilitating with the adjacent nitrogen lone pairs, while the methylene carbons (positions 4, 5, 6) and nitrogen atoms are sp³ hybridized. A key structural feature of DMPU is the absence of active hydrogens on the atoms due to N-methylation, which prevents hydrogen bonding donation and imparts its polar aprotic character. This substitution enhances its utility as a by allowing strong interactions without proton transfer capabilities, distinguishing it from protic ureas.

Physical Properties

Appearance and State

DMPU appears as a clear, colorless to pale yellow liquid under standard conditions. It exists in the liquid phase at (20°C), owing to its low of -22°C. The compound has a of 246°C at 760 mmHg, indicating thermal stability suitable for high-temperature applications. Its is 1.06 g/cm³ at 25°C, which is slightly higher than that of . DMPU is miscible with and most organic solvents, facilitating its use in diverse chemical environments.

Spectroscopic Data

Infrared (IR) of DMPU reveals a strong carbonyl stretching band at 1635 cm⁻¹, characteristic of the cyclic . Aliphatic C-H stretching vibrations from the N-methyl groups occur in the 2800–2900 cm⁻¹ region. ¹H NMR , typically recorded in CDCl₃, displays a at 2.92 for the equivalent methyl protons (6H) attached to atoms. The CH₂ groups appear as multiplets between 2.04 (quintet, 2H) and 3.34 (4H total across the two CH₂ units). In ¹³C NMR, the carbonyl carbon is observed at 156.0 , the N-methyl carbons at 35.0 , and the methylene carbons at 47.8 (C-4,6) and 22.5 (C-5). These shifts confirm the symmetric structure and hydrogen-bonding influences in solution. Electron ionization mass spectrometry shows the molecular ion [M]⁺ at m/z 128 (100% relative intensity), consistent with the formula C₆H₁₂N₂O. Prominent fragments include m/z 127 ([M-H]⁺, 21.9%), m/z 99 (17.6%), m/z 70 (19.1%), m/z 44 (18.7%), m/z 43 (25.0%), and m/z 42 (28.9%), arising from sequential losses of alkyl and nitrogen-containing groups.

Synthesis and Preparation

Laboratory Synthesis

DMPU is commonly synthesized in the laboratory via the reaction of N,N'-dimethylpropane-1,3-diamine with , followed by cyclization under controlled heating conditions. In this method, equimolar amounts of N,N'-dimethylpropane-1,3-diamine and are heated initially at around 120°C for several hours to form an intermediate bisurea compound, then raised to 210°C for an additional period, often in an aprotic polar like DMPU itself under pressure up to 1.5 . This process typically achieves yields of 90-97% with product purity exceeding 99% after . An alternative route employs N,N'-dimethylurea and . The first step involves base-catalyzed addition and cyclization to form N,N'-dimethyldihydrocytosine at to 70°C in a solvent like . This intermediate is then hydrogenated under pressure (e.g., 800 psig H₂, 50–100°C) with a catalyst to yield DMPU in high yields (70-92%). The mechanism for the urea route involves of the diamine nitrogen to the , forming an open-chain urea intermediate, followed by to close the six-membered pyrimidinone ring. These reactions are conducted under an inert atmosphere, such as , at temperatures of 150-200°C to prevent side reactions. Regardless of the route, purification of DMPU is achieved by distillation under reduced pressure to isolate the high-boiling product (bp 246–247°C at atmospheric pressure) with purity >99%.

Commercial Production

DMPU is produced industrially through the continuous reaction of N,N′-dimethylpropane-1,3-diamine with urea in high-pressure reactors, often employing a polar solvent such as N,N-dimethylformamide to facilitate the process. This method involves heating the reactants at temperatures exceeding 180°C, either in a single stage or via a two-stage approach where initial heating occurs at ≤140°C followed by elevated temperatures, achieving high yields up to 96% under optimized conditions. Alternative routes utilize carbon dioxide in place of urea, promoting carboxylation and cyclization in pressurized systems with catalysts like CeO₂, though the urea-based process remains predominant for scalability. Base catalysts, such as , are employed to enhance cyclization efficiency, particularly when using organic carbonates as carbonyl sources in conjunction with the ; typical conditions include temperatures of 90–120°C with addition as a methanolic . These s promote the reaction while minimizing by-products, supporting continuous flow operations in industrial settings. Commercial production is handled by specialized chemical suppliers including Alkyl Amines Chemicals Limited and , with global output concentrated in (approximately 60% of total), (25%), and (15%), reaching tens of thousands of tons annually to meet demand as a specialty . The global market value was estimated at $300 million in 2024, reflecting steady growth driven by pharmaceutical and chemical applications. Cost factors include sourcing raw materials like N,N′-dimethylpropane-1,3-diamine from petrochemical feedstocks and the energy-intensive nature of high-temperature reactions, which require precise control to maintain efficiency. standards enforce strict impurity limits, such as water content below 0.05% and residual amines under 0.1%, achieved through and molecular sieving to ensure ≥99% purity for industrial use.

Chemical Properties and Reactivity

Solvent Characteristics

DMPU functions as a polar aprotic solvent, exhibiting significant polarity with a dielectric constant of 36.1 at 25°C, which facilitates the dissolution of ionic compounds. This value reflects its strong ability to stabilize charged species through electrostatic interactions. Additionally, DMPU possesses a high donor number of 33 kcal/mol, attributed to the availability of oxygen lone pairs in its cyclic urea structure, enabling effective Lewis basicity toward cations. Gutmann's donor number concept quantifies this basicity as the negative enthalpy change in the interaction between the solvent and a reference Lewis acid like SbCl₅, providing a measure of solvation strength without involving hydrogen bonding from the solvent itself. As an aprotic solvent, DMPU lacks O-H or N-H protons, preventing it from forming hydrogen bonds as a donor and allowing it to stabilize anions primarily through non-hydrogen-bonding mechanisms such as dipole interactions and lone pair donation. This property enhances its utility in reactions requiring free anions, like nucleophilic substitutions. Solvatochromic analysis via Kamlet-Taft parameters further characterizes its behavior: α = 0.46 (moderate hydrogen bond donation), β = 0.87 (strong hydrogen bond acceptance), and π* = 0.86 (high dipolarity/polarizability), indicating a solvent environment that has some acidity alongside strong basicity. Compared to analogous solvents, DMPU serves as a less toxic alternative to (HMPA), a known , while offering similar solvency for organometallic and polar species due to comparable donor abilities. It also contrasts with (DMF) by having a higher of 246°C versus DMF's 153°C, which provides greater thermal stability during reactions without substantially altering dissolution capacity. Overall, these characteristics position DMPU as a versatile medium for anion stabilization in synthetic chemistry.

Stability and Reactions

DMPU exhibits good thermal stability under normal laboratory conditions and can withstand temperatures up to its of approximately 246 °C without significant . It decomposes at elevated temperatures above 250 °C, yielding products such as nitrogen oxides, , and . The compound is incompatible with strong oxidizing agents, which can promote . Regarding hydrolytic stability, DMPU resists mild hydrolytic conditions but undergoes ring opening under harsh acidic or basic environments. This behavior is characteristic of its cyclic structure, which maintains integrity in neutral or weakly aqueous media commonly encountered in synthetic applications. DMPU demonstrates reactivity as a coordinating in metal complexes, primarily through its carbonyl oxygen atom, due to its strong electron-donating ability. The steric bulk from its N-methyl groups renders it a space-demanding , often resulting in lower coordination numbers for solvated metal ions compared to less hindered oxygen donors. Additionally, DMPU can undergo N-demethylation when exposed to strong oxidants, though this process occurs at a significantly slower rate than in analogous compounds like HMPA. DMPU is used in applications requiring stability, such as solar cells, with no reported significant degradation under ambient light exposure during typical handling. A notable reaction involving DMPU is its adduct formation with to yield the DMPU· , a nucleophilic fluorinating used in regioselective of fluoroalkenes and gem-difluoromethylene compounds from alkynes. This benefits from DMPU's polarity and coordinating properties, enabling compatibility with metal catalysts while avoiding the hazards of gaseous .

Applications

Use as a Solvent

DMPU serves as a in , where it enhances the reactivity of nucleophiles by coordinating to metal cations, thereby dissociating pairs and promoting reactions such as formations and Grignard additions. In chemistry, DMPU facilitates lithium diisopropylamide-mediated deprotonations by mediating monomer-based metalations, similar to THF but with distinct effects that influence rate and selectivity. For Grignard reagents, DMPU acts as a cosolvent to increase nucleophilicity, enabling efficient conjugate additions to α,β-unsaturated carbonyls under at . In pharmaceutical and synthesis, DMPU facilitates N-alkylation of chiral amines with retention of stereochemistry, O-alkylation of aldoses, and the production of poly(aryl ethers). Specific applications include palladium- and copper-catalyzed cross-couplings, where DMPU improves yields compared to less polar solvents like THF. In Suzuki-Miyaura couplings, DMPU as the reaction medium supports sulfonylative variants with aryl and heteroaryl halides, achieving high efficiency due to its ability to stabilize catalytic intermediates. It has also been employed in aldol condensations, where its coordination disrupts cyclic transition states, favoring anti-selective products in reactions of enolates with aldehydes. DMPU gained popularity in the as a safer alternative to the carcinogenic HMPA, with early demonstrations by Seebach showing equivalent enhancement of nucleophilic reactivity without toxicity concerns. Its high boiling point permits reactions at elevated temperatures that would be impractical in lower-boiling solvents. Additionally, DMPU effectively coordinates Li⁺ ions in organolithium reactions, reducing aggregation and boosting rates in processes like 1,4-additions to enones. In practice, DMPU is typically added as a in 1-5 equivalents relative to the , often mixed with less polar media like THF to optimize and reactivity while minimizing side reactions.

Specialized Chemical Uses

Beyond its role as a , DMPU participates in specialized chemical transformations, particularly through its ability to form stable complexes that enable selective fluorinations. The DMPU/ complex, a nucleophilic fluorinating agent with high acidity, facilitates the gold-catalyzed regioselective hydrofluorination of alkynes, yielding (Z)-fluoroalkenes from mono-fluorination and gem-difluoroalkenes from di-fluorination under mild conditions. This reagent's compatibility with cationic metal catalysts and its liquid state at enhance its utility in precise C-F bond formations. In variant Prins reactions, the DMPU/HF complex acts as a nucleophilic fluoride source for the diastereoselective synthesis of 4-fluorotetrahydropyrans from homoallylic alcohols and aldehydes, providing access to fluorinated heterocycles with high stereocontrol. This application leverages the complex's controlled delivery, avoiding over-fluorination common with gaseous . DMPU also functions as a coordinating additive in catalysis, enhancing reactivity in asymmetric syntheses. For instance, in copper-catalyzed enantioselective allylic alkylations of stereodefined enolates, DMPU promotes efficient coupling to form quaternary carbon centers with high enantioselectivity, acting through coordination to modulate the metal's electronic properties. Additionally, DMPU serves as a in the of esters within superbase ionic liquids, improving and reaction homogeneity to yield materials with tailored thermoresponsive properties. It is also used in the synthesis of poly(aryl ethers) by , where its solvating properties aid in producing soluble, high-molecular-weight polymers. In , DMPU acts as a for cleaning and processing components due to its high dielectric constant and stability. In reduction chemistry, DMPU enhances the reducing power of diiodide (SmI₂) by forming a complex that increases efficiency, enabling selective reductions of aryl ketones and other substrates. These applications emerged in the late 20th and early 21st centuries, with the DMPU/ complex introduced as a safer, more handleable alternative to hazardous reagents like DAST for fluorination reactions, minimizing risks associated with volatile generation.

Safety, Handling, and Environmental Considerations

Toxicity and Health Hazards

DMPU demonstrates low acute oral toxicity, with an LD50 value of 1770 mg/kg in rats, indicating minimal risk from single ingestions at typical exposure levels. It causes limited dermal effects but is not classified as a irritant, and is a severe irritant to eyes (Category 1), based on rabbit Draize tests showing potential for serious eye damage. Inhalation of vapors can cause irritation, while dermal is limited due to its physical properties as a . For safe handling, use protective gloves, safety goggles, and ensure adequate . Store in a tightly closed container in a cool, dry place under inert atmosphere to prevent absorption of moisture and potential under conditions. Chronic exposure to DMPU raises concerns for , classified under EU REACH as Category 2 (suspected of damaging ), similar to other cyclic ureas but without strong evidence of carcinogenicity, distinguishing it from related solvents like HMPA. No definitive data indicate or tumor induction in available studies. Primary symptoms from ingestion include and , with no specific available; treatment is symptomatic and supportive. DMPU is not classified as a hazardous substance under OSHA standards, lacking specific permissible exposure limits, while REACH assessments denote it as a low overall health concern despite reproductive restrictions under Annex XVII.

Environmental Impact and Regulations

DMPU demonstrates low potential for environmental due to its high water solubility and expected in systems. is unlikely, as indicated by assessments, though it is not classified as readily biodegradable under standard testing criteria. The compound exhibits low ecotoxicity to aquatic life, with acute toxicity values including an LC50 of 2,200 mg/L for (96 h exposure), an EC50 greater than 102.8 mg/L for (48 h), and an ErC50 of at least 180 mg/L for (72 h). Chronic toxicity to microorganisms is also low, with an EC50 exceeding 1,000 mg/L. DMPU has no . Bioaccumulation is minimal, with a log Kow of approximately 0.05, well below thresholds for concern. The compound is highly mobile in due to its solubility and low adsorption potential. Industrial applications of DMPU typically employ closed systems to minimize environmental releases, with any effectively managed through conventional processes owing to the solvent's . Contaminated DMPU is classified as and requires disposal in accordance with local regulations, such as or specialized . DMPU is listed on the U.S. Toxic Substances Control Act (TSCA) inventory and is registered under the REACH framework (EC number 230-625-6). It is not designated as a persistent, bioaccumulative, and toxic (PBT) substance or very persistent and very bioaccumulative (vPvB) under criteria. In contexts, DMPU is favored over (DMF) for its lower volatility and reduced overall toxicity profile.

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