Experimental Evaluation of Triphosgene in Organic Synthesis: Understanding Its Selection Logic Through Reaction Tasks
Experimental Evaluation of Triphosgene in Organic Synthesis: Understanding Its Selection Logic Through Reaction Tasks
1. What Triphosgene Is, and Where It Sits Within Phosgenation Reagent Systems
Triphosgene, abbreviated as BTC, is bis(trichloromethyl) carbonate. The name “triphosgene” comes from the fact that, in stoichiometric terms, it can provide three equivalents of phosgene, and it is therefore commonly regarded as a classical phosgene equivalent. A representative paper published in 1987 described it as a crystalline phosgene substitute, and that understanding remains valid today.
Triphosgene is commonly used in research and small-scale organic synthesis, mainly because it is a solid, which makes it relatively convenient to weigh, add portionwise, and incorporate into an experimental workflow. A 2020 review summarized its major applications from 2010 to 2019, covering organic halides, acid chlorides, isocyanates, heterocycles, as well as reactions in flow chemistry and solid-phase systems. Reviews and commonly used reference materials show that, among common phosgene-substitute systems, diphosgene and triphosgene are generally closer to traditional phosgene-type routes involving highly reactive intermediates, whereas CDI (N,N′-carbonyldiimidazole) and DSC (N,N′-disuccinimidyl carbonate) are more often used in milder arrangements based on activated esters, active carbonates, or acyl transfer. Accordingly, the place of triphosgene in experimental work is reflected not only in its operational convenience, but also in the fact that its coverage of reaction tasks is closer to that of phosgene.
Under pseudo-first-order kinetic comparison in CDCl₃ at 25 °C with methanol in excess, Pasquato et al. reported relative reactivities of approximately 170, 19, and 1 for phosgene, diphosgene, and triphosgene, respectively. This indicates that, in that methanolysis model, the defining feature of triphosgene is not maximal reactivity; its common advantages in research and small-scale work arise more from the convenience of weighing, charging, and organizing experiments that comes with its solid form. At the same time, excess triphosgene cannot be removed as readily by volatility as phosgene can, so residue handling and workup are often more troublesome. This point requires especially careful prior evaluation when the target intermediate is sensitive to water or alcohols. Therefore, deciding whether triphosgene is suitable for a given reaction requires simultaneous consideration of the task type, intermediate stability, workup requirements, and safety conditions.
2. Major Reaction Types of Triphosgene Summarized by Experimental Task
From the standpoint of experimental tasks, the common reaction types of triphosgene can be summarized as follows. This classification integrates review articles and representative primary literature, including the preparation of N-carboxyanhydrides (NCAs), the conversion of 1,2- and 1,3-diols into cyclic carbonates, the conversion of amines into isocyanates, and carboxylic acid activation.
Experimental task | Main role played by triphosgene | When to consider it first | Key point for prior evaluation |
Activation of alcohols and phenols | Phosgenation or chloroformylation reagent | When a chloroformate must first be formed, followed by conversion into a carbonate or carbamate | Whether the highly reactive intermediate must be preserved, and whether workup can avoid destruction by water or alcohols |
Cyclization of 1,2- or 1,3-diols | Carbonylative ring-closing reagent | When the goal is to directly construct a cyclic carbonate | Substrate configuration, steric hindrance, and base conditions can markedly affect the outcome |
Carboxylic acid activation | Carboxylic acid preactivation reagent | When the key challenge is to deliver the carboxylic acid into a highly reactive acyl intermediate | Intermediates such as acid chlorides and anhydrides are sensitive to moisture and workup conditions |
Carbonylative conversion of primary amines and related nitrogen-containing substrates | Phosgenation reagent for nitrogen-containing substrates | When isocyanates, carbamoyl chlorides, or further conversion to ureas are needed | Acid generation, overreaction, and handling of salt byproducts |
Preparation of N-carboxyanhydride monomers from α-amino acids | Cyclocarbonylation reagent | When the goal is to obtain an NCA monomer | The intermediates are sensitive, and moisture, acid, and operating conditions in the system all require strict control |
Dehydrative functional-group transformations | Dehydrative phosgene equivalent | When the precursor type matches the target product and activation and dehydration are ideally merged into one pathway | Substrate differences are large, and side-reaction pathways show clear substrate dependence |
3. How to Judge Whether to Use Triphosgene: First Look at the Task Type, Then at Whether the Workup Is Compatible
Whether triphosgene should enter the shortlist of preferred routes usually depends first on whether the step is a typical phosgene-type task, and then on whether the target intermediate and workup conditions allow this route to be used. For tasks involving carbonyl introduction, chloroformylation, or dehydrative transformation, triphosgene and diphosgene are closer to phosgene-type reagents. For tasks centered on carboxylic acid activation and acyl transfer, CDI, that is, N,N′-carbonyldiimidazole, is often more direct. At the actual experimental stage, what truly determines whether triphosgene should rank among the preferred options is whether the intermediate is sensitive, whether the workup is feasible, and whether the reaction can proceed smoothly into the next step after completion.
Key point in the decision | Question that must first be clarified | Influence on whether triphosgene should be selected |
Task type | Whether the current step belongs to a typical phosgene-type transformation | If it is a phosgene-type task, triphosgene can usually enter the shortlist of preferred routes |
Nature of the intermediate | Whether highly reactive intermediates such as chloroformates, carbamoyl chlorides, isocyanates, acid chlorides, or NCAs, that is, N-carboxyanhydrides, will be generated | If the intermediate must be preserved, route selection should shift early toward the feasibility of workup and transfer |
Quench and workup | Whether excess reagent can be treated with conventional water or alcohol quenching after the reaction | If the target intermediate is sensitive to nucleophilic quenching, the operational difficulty of the triphosgene route increases markedly |
Residue control | Whether excess reagent and byproducts can be removed cleanly enough | If residues will affect the next step or product stability, the priority of triphosgene should be lowered |
Integration with the next step | Whether the intermediate will be carried directly into the next step in situ or needs to be isolated and purified | In situ conversion makes it easier to exploit the advantages of triphosgene; if a sensitive intermediate must be isolated, the route becomes more demanding |
4. The Control Points That Require the Earliest Priority Once Triphosgene Is Chosen
Once triphosgene is used, the main points of judgment center on the match between acid generation and base usage, and on whether highly reactive intermediates should be advanced in situ or isolated separately. For sensitive intermediates such as chloroformates, carbamoyl chlorides, isocyanates, acid chlorides, and NCAs, that is, N-carboxyanhydrides, excess reagent cannot simply be treated with water or alcohols, and transfer and workup after reaction completion often become even more critical.
Key control point | Question requiring focused evaluation | Influence on experimental outcome |
Whether acid generation matches base usage | Whether the acid generated in the system will affect the substrate, product, or intermediate; whether adding base truly improves the reaction rather than increasing the burden of byproduct salt handling | Improper base use can increase side reactions and workup complexity, and adding more base is not necessarily better |
Whether the intermediate is advanced in situ or isolated and purified | Whether the current step serves as an activation node for the next step, or whether the intermediate must be isolated separately | In situ progression usually makes it easier to realize the workflow advantages of triphosgene; when sensitive intermediates must be isolated, system cleanliness and workup become more demanding |
Whether the quench and transfer mode is compatible with the target | Whether conventional treatment can be used after reaction completion, and whether the target structure tolerates water, alcohols, or other nucleophilic conditions | In systems involving sensitive intermediates, the mode of reaction termination itself may determine whether the route is viable |
Among these factors, the match between acid generation and base usage particularly requires independent evaluation. A 2007 study on the preparation of isocyanates from amines showed that, under triphosgene conditions of this kind, the additional use of amine bases did not offer a clear advantage in most cases; conditions without an added strong base were instead more favorable for simplifying workup, while only substrates that were more acid-sensitive required assistance from a base. Therefore, in systems of this type for preparing isocyanates from amines, bases in triphosgene chemistry are better treated as condition variables that require separate evaluation, rather than as default components to be added routinely.
5. Key Points in the Safety Evaluation of Triphosgene Routes
Although triphosgene is a solid phosgene equivalent that is convenient for weighing and small-scale operations, it should not therefore be understood as “safe phosgene” or “a safer phosgene.” In experimental decision-making, priority should still be given to controlling inhalation exposure, avoiding contact with moisture or water, and planning the quench and workup after the reaction is complete.
The main points in experimental safety evaluation are concentrated in the following aspects:
Key point in safety evaluation | Question that must first be clarified | Influence on experimental organization |
Control of inhalation and moisture exposure | Whether fume-hood operation is available, and whether exposure and moisture ingress can be controlled during weighing, transfer, and charging | Determines whether the route can be carried out under basic safety conditions |
Mode of reaction termination | Whether the target intermediate tolerates conventional treatment with water or alcohols, and whether the quenching plan will destroy the target structure | Determines whether transfer and workup can be completed safely and cleanly after reaction completion |
Scale-up conditions | Whether off-gas treatment, charge control, and the necessary engineering management are available | Determines whether small-scale feasibility provides a basis for further scale-up |
Publicly available information shows that triphosgene is moisture-sensitive and can release toxic gases upon contact with water. For sensitive intermediates such as chloroformates, carbamoyl chlorides, isocyanates, acid chlorides, and NCAs, that is, N-carboxyanhydrides, excess reagent cannot simply be handled in the usual way with water or alcohols. The transfer mode and workup conditions after reaction completion often determine route viability at an earlier stage than expected.
6. Navigation Table for Experimental Selection of Triphosgene in Organic Synthesis (Choose Table 1-Table 4 by Research or Experimental Goal)
Research or experimental goal | Which table to consult first | Why this table should be consulted first | Which table to consult in combination | Guidance |
To build an overall understanding of the triphosgene system first, and distinguish what the core reagent, control reagents, and preformed activated species are each best suited to address | Table 1 | Table 1 brings together triphosgene itself, CDI, oxalyl chloride, thionyl chloride, DSC, NHS, and preformed chloroformate control reagents, making it suitable for first judging whether the current task belongs to phosgenation, carboxylic acid activation, or an active carbonate/activated ester route | Then see Table 2 | Once the question of “which type of activation mode should be used to drive the reaction” is clarified first, it becomes easier to build a complete experimental judgment before moving on to bases, catalysts, and specific substrate screening |
To compare the differences between triphosgene and routes based on CDI, oxalyl chloride, thionyl chloride, and related reagents, and decide which route should be tried first for carboxylic acid activation or chloroformate formation | Table 1 | Table 1 directly provides the most important route comparators, making it convenient to compare different activation pathways in terms of intermediate type, workup mode, and substrate compatibility | Then see Tables 3 and 4 | If the task falls on carboxylic acids, alcohols, amines, or dehydration substrates, Tables 3 and 4 can then be used to examine specific model substrates and representative products, making route comparison easier to translate into actual experiments |
To establish the basic conditions for triphosgene reactions and compare the effects of bases such as pyridine, triethylamine, DIPEA, N-methylmorpholine, and 2,6-lutidine | Table 2 | Table 2 focuses on acid scavenging bases, hindered bases, catalysts, and workup bases, and is suitable for setting up a basic condition framework for triphosgene reactions | Then see Table 1 | It is more helpful for condition optimization to first use Table 2 to decide how bases and catalysts are organized, and then return to Table 1 to judge which activation reagent or control reagent should be paired with them |
To carry out triphosgene reactions of alcohols, phenols, or diols and determine whether the route should proceed through chloroformate formation, carbonate formation, or cyclic carbonate formation | Table 3 | Table 3 brings together hydroxy substrates such as benzyl alcohol, phenol, ethylene glycol, 1,3-propanediol, and glycerol, making it suitable for first judging from substrate type whether the task involves monohydroxy carbonylation or diol cyclization | Then see Tables 1 and 2 | After reviewing Table 3, returning to Table 1 to choose between triphosgene and preformed chloroformate routes, and then using Table 2 to determine the base and catalyst, makes the experimental pathway clearer |
To study the selectivity of polyhydroxy substrates in triphosgene systems and judge whether over-carbonylation or multistate-site reaction is likely to occur | Table 3 | The glycerol, diol, and phenolic substrates in Table 3 are more suitable for evaluating the effects of hydroxyl number, site differences, and substrate structure on selectivity | Then see Table 2 | In tasks of this kind, the issue is often not only whether reaction occurs, but whether the base, catalyst, and charging mode will amplify competition among multiple reactive sites |
To drive carboxylic acids into more highly reactive intermediates and compare whether the triphosgene route or a classical acid chloride route is more suitable | Table 1 | Table 1 places triphosgene, oxalyl chloride, thionyl chloride, DSC, and NHS together as key activation routes, making it suitable for first judging whether in situ phosgenation, acid chloride formation, or active ester formation should be prioritized | Then see Table 3 | Once the route has been determined, actual screening can then be organized with model substrates such as acetic acid and benzoic acid in Table 3, making it easier to obtain meaningfully comparable data |
To examine the conditions under which primary amines form isocyanates, ureas, or carbamates under the action of triphosgene | Table 3 | Table 3 brings together representative primary amine substrates such as aniline, benzylamine, and cyclohexylamine, making it convenient to compare the reactivity differences of aromatic amines, aliphatic amines, and alicyclic amines in triphosgene systems | Then see Tables 4 and 2 | First use Table 3 to define the substrate type, then use Table 4 for representative isocyanate or urea products, and Table 2 to optimize acid scavenging bases and catalysts, which is more suitable for a complete evaluation of amine-related tasks |
To investigate chemistry centered on the isocyanate node and clarify the relationship between amine substrates and downstream construction of ureas or carbamates | Table 4 | Table 4 provides representative intermediates/products such as benzyl isocyanate and diphenylurea, making it suitable for first clarifying the main convergence directions of amine transformations in triphosgene systems | Then see Table 3 | Once the target product type is clear, returning to Table 3 to choose amine substrates makes it easier to arrange reaction design and endpoint analysis |
To prepare amino-acid NCA monomers and build a basic understanding of the use of triphosgene in cyclocarbonylation of amino acids | Table 3 | Glycine in Table 3 is the direct precursor entry point, making it suitable for understanding the NCA preparation task from the amino acid substrate itself | Then see Tables 4 and 2 | Table 4 can then be used to confirm the target monomer type through the representative 2,5-oxazolidinedione entry, while Table 2 helps focus on acid scavenging and condition control, thereby reducing side reactions and decomposition |
To investigate the use of triphosgene in dehydration to isocyanides or nitriles starting from formamides or oxime precursors | Table 4 | Table 4 gathers dehydration-route precursors and representative products such as N-benzylformamide, benzaldoxime, benzyl isocyanide, and benzonitrile, making it suitable for first deciding whether the task converges on an isocyanide or a nitrile route | Then see Table 2 | Such tasks are sensitive to base, water content, and workup. Once the product direction has been clarified, combining it with Table 2 to arrange conditions is more in line with actual experimental screening |
To understand triphosgene reactions first from the perspective of “precursor-intermediate-end product” | Table 4 | Table 4 is best suited for understanding several key endpoints of triphosgene chemistry from an outcome-oriented perspective: isocyanates, NCAs, ureas, nitriles, and isocyanides | Then see Tables 1 and 3 | After first clarifying the target endpoint, one can then return to Table 1 to choose the activation system and Table 3 to choose substrates, making experimental design more focused |
To build a triphosgene research framework for literature analysis or preliminary condition screening | Table 1 | Table 1 is suitable for first establishing the route framework and sorting out the positions of triphosgene relative to several control reagents | Then see Tables 2, 3, and 4 | Starting with route-level understanding and then adding condition components, substrate types, and representative products makes it possible to form a more systematic overall judgment of the experimental applications of triphosgene |
Table 1 | Core Phosgenation Reagents, Activation Reagents, and Preformed Chloroformate Controls
Category | CAS No. | Aladdin Cat. No. | Name | Grade or Purity | Product Features and Applications |
Core phosgenation reagent | 32315-10-9 | Triphosgene | ≥99% | A classical solid phosgene equivalent that can be used for chloroformylation of alcohols/phenols, cyclization of diols to cyclic carbonates, carboxylic acid activation, preparation of isocyanates from primary amines, and synthesis of NCA monomers from amino acids. It is the core starting point for establishing triphosgene-based experimental routes. | |
Non-phosgene carbonylation control reagent | 530-62-1 | N,N'-Carbonyldiimidazole (CDI) | ≥99% | Commonly used for carboxylic acid activation and acyl transfer. It is suitable for comparing triphosgene-based routes in terms of intermediate type, workup burden, and substrate compatibility in “activate first, then form the bond” strategies. | |
Acid chloride formation control reagent | 79-37-8 | Oxalyl chloride | Reagent grade, advanced pure, ≥99% | Commonly used for the rapid conversion of carboxylic acids into acid chlorides. It is suitable for comparison with triphosgene in terms of carboxylic acid activation rate, handling of volatile byproducts, and effects on sensitive substrates. | |
Acid chloride formation control reagent | 7719-09-7 | T433841 | Thionyl chloride | Advanced pure, reagent grade, ≥99.5%, low iron | A classical reagent for converting carboxylic acids into acid chlorides. It is suitable for comparison with triphosgene in terms of acid chloride formation conditions, handling of gaseous byproducts, and operational differences in exothermic and moisture-sensitive systems. |
Active carbonate construction reagent | 74124-79-1 | N,N'-Disuccinimidyl carbonate (DSC) | ≥98% | Used to construct succinimidyl active carbonates. It can serve as a preformed activation-reagent control for triphosgene/NHS routes and is suitable for comparing in situ phosgenation with preformed activated-species strategies. | |
Activated ester component | 6066-82-6 | N-Hydroxysuccinimide (NHS) | ≥98% | Commonly used to construct NHS active esters or active carbonates. It can serve as a control component between triphosgene in situ activation routes and preformed activated-species routes. | |
Preformed chloroformate control reagent | 1885-14-9 | Phenyl chloroformate | ≥98% | A preformed chloroformate reagent suitable for comparison with routes in which triphosgene generates chloroformates in situ, and useful for screening carbonylation conditions for phenols, alcohols, or amines. | |
Amino-protecting chloroformate control reagent | 501-53-1 | Benzyl chloroformate | ≥96%, contains 0.1% sodium carbonate as stabilizer | A classical reagent for introducing the Cbz (carbobenzyloxy) group. It can serve as a control for amino protection or carbamate construction via chloroformate intermediates generated from triphosgene. |
Table 2 | Acid-Scavenging Bases, Catalysts, and Workup Control Components
Category | CAS No. | Aladdin Cat. No. | Name | Grade or Purity | Product Features and Applications |
Aromatic amine-type acid-scavenging base | 110-86-1 | Pyridine | Anhydrous grade, ≥99.8% | A commonly used acid-scavenging base that can both absorb HCl and help organize chloroformylation of hydroxy substrates and diol cyclization conditions. It is a common starting point in basic condition screening for triphosgene reactions. | |
Conventional tertiary amine acid-scavenging base | 121-44-8 | Triethylamine | Anhydrous grade, ≥99.5%, Water ≤ 50 ppm | A commonly used tertiary amine base suitable for handling the HCl released in triphosgene reactions, and often used in routine condition setup for alcohol, amine, and carboxylic acid activation systems. | |
Hindered tertiary amine acid-scavenging base | 7087-68-5 | N,N-Diisopropylethylamine | Distilled grade, ≥99.5% | A more sterically hindered tertiary amine base, suitable when the goal is to reduce direct nucleophilic participation by the base itself. It is commonly used in condition screening for more sensitive substrates or reactive intermediates. | |
Tertiary amine acid-scavenging base | 109-02-4 | N-Methylmorpholine | Distilled grade, ≥99.5% | A common tertiary amine base that can be used in carbonylation, active ester construction, and some isocyanate-forming conditions. It is suitable for parallel comparison with triethylamine and DIPEA. | |
Hindered aromatic amine acid-scavenging base | 108-48-5 | 2,6-Lutidine | Distilled grade, ≥99% | A sterically hindered aromatic amine base suitable when direct attack of the base on reactive intermediates should be reduced. It can be used to optimize selectivity and suppress side reactions. | |
Nucleophilic acyl-transfer catalyst | 1122-58-3 | 4-Dimethylaminopyridine | ≥99% | A nucleophilic acyl-transfer catalyst that can promote the subsequent conversion of chloroformates and active carbonates with alcohols/amines, and is suitable for accelerating carbonate or carbamate construction. | |
Workup/off-gas absorption base | 1310-73-2 | S111498 | Sodium hydroxide | Guaranteed reagent, ≥96% | Commonly used for off-gas absorption, neutralization of acidic byproducts, and alkaline washing during workup. It is very common in the safety organization and cleanup stages of triphosgene systems. |
Table 3 | Task-Oriented Model Substrates: Hydroxy, Carboxylic Acid, Amine, and Amino Acid Types
Category | CAS No. | Aladdin Cat. No. | Name | Grade or Purity | Product Features and Applications |
Simple carboxylic acid model substrate | 64-19-7 | Acetic acid | Guaranteed reagent, ≥99.5% | A simple aliphatic carboxylic acid model substrate suitable for examining the basic reactivity of triphosgene or control acid-chlorinating reagents in driving carboxylic acids into acid chlorides, anhydrides, or subsequent acyl-transfer intermediates. | |
Aromatic carboxylic acid model substrate | 65-85-0 | Benzoic acid | Suitable for synthesis | A typical aromatic carboxylic acid substrate suitable for comparing triphosgene, oxalyl chloride, and thionyl chloride in carboxylic acid activation, acid chloride formation, and subsequent derivatization. | |
Alcohol model substrate | 100-51-6 | Benzyl alcohol | Pharmaceutical grade, PharmPure™ | A typical primary alcohol substrate suitable for examining chloroformate formation, carbonate construction, and the route leading to subsequent carbamate formation with amines in triphosgene systems. | |
1,2-Diol cyclization model substrate | 107-21-1 | Ethylene glycol | Anhydrous grade, ≥99.8% | A classical 1,2-diol model substrate suitable for establishing the basic conditions for triphosgene-promoted cyclization of diols into five-membered cyclic carbonates. | |
1,3-Diol cyclization model substrate | 504-63-2 | 1,3-Propanediol | Suitable for synthesis | A typical 1,3-diol substrate suitable for examining triphosgene-promoted formation of six-membered cyclic carbonates and the influence of chain length changes on cyclization efficiency and selectivity. | |
Polyol model substrate | 56-81-5 | Glycerol | Anhydrous grade, UltraBio™, molecular biology grade, ≥99.5% (GC) | A polyol model substrate suitable for examining selective carbonylation of polyhydroxy substrates, stepwise protection, and control of overreaction in triphosgene systems. | |
Phenolic phosgenation model substrate | 108-95-2 | Phenol | ≥99.5% (GC) | A typical phenolic substrate suitable for examining chloroformylation of phenolic hydroxyl groups in triphosgene systems, and further corresponding construction of carbonate derivatives. It can also be compared with preformed phenyl chloroformate routes to evaluate in situ phosgenation versus direct use of chloroformate reagents as two different ways of organizing the reaction. | |
Aromatic primary amine model substrate | 62-53-3 | Aniline | Standard for GC, ≥99.9% (GC) | A typical aromatic primary amine substrate suitable for examining reactivity and side-reaction control in triphosgene-promoted conversion of amines into isocyanates, ureas, or carbamates. | |
Aliphatic primary amine model substrate | 100-46-9 | Benzylamine | AR, ≥99% | A common aliphatic primary amine substrate suitable for examining the organization of conditions for forming isocyanates from primary amines and for their subsequent derivatization in triphosgene systems. | |
Alicyclic primary amine model substrate | 108-91-8 | Cyclohexylamine | Moligand™, Standard for GC, ≥99.5% (GC) | An alicyclic primary amine model substrate suitable for comparison with aniline and benzylamine in evaluating the reactivity and selectivity of different amine types in triphosgene systems. | |
Amino acid NCA precursor substrate | 56-40-6 | Glycine | UltraBio™, molecular biology grade, ultrapure grade, ≥99% (NT) | The simplest α-amino acid precursor, corresponding to the classical route for preparing Gly-NCA with triphosgene, and suitable for establishing a basic understanding of NCA monomer synthesis. |
Table 4 | Dehydration-Route Precursors and Representative Intermediates/Products
Category | CAS No. | Aladdin Cat. No. | Name | Grade or Purity | Product Features and Applications |
Isocyanide dehydration precursor | 6343-54-0 | N-Benzylformamide | ≥98% (GC) | A typical N-substituted formamide substrate suitable for examining the pathway by which formamides undergo dehydration to isocyanides in triphosgene systems. It forms a clear precursor-product correspondence with benzyl isocyanide. | |
Aldoxime dehydration precursor | 932-90-1 | Benzaldoxime | ≥95%, mainly the E isomer | A typical aldoxime dehydration precursor suitable for the triphosgene-promoted dehydration route to benzonitrile, and a representative model substrate for oxime-to-nitrile conversion. | |
Representative isocyanate product | 3173-56-6 | Benzyl isocyanate | ≥99% (GC) | A representative isocyanate product corresponding to the typical endpoint in which a primary amine is converted into an isocyanate via phosgenation under the action of triphosgene. | |
Representative NCA product | 2185-00-4 | 2,5-Oxazolidinedione | ≥98% | Can serve as a representative glycine N-carboxyanhydride, corresponding to the classical route in which triphosgene mediates preparation of NCA monomers from α-amino acids. | |
Representative urea product | 102-07-8 | N,N'-Diphenylurea | ≥98% | Can serve as a representative urea product formed by further conversion of aromatic amines through isocyanate intermediates, and is suitable for understanding the downstream convergence of triphosgene-promoted carbonylation of amines. | |
Representative nitrile product | 100-47-0 | Benzonitrile | Anhydrous grade, ≥99% | A representative nitrile product suitable for corresponding result assignment in routes where precursors such as benzaldoxime are converted into nitriles under triphosgene dehydration conditions. | |
Representative isocyanide product | 10340-91-7 | Benzyl isocyanide | ≥96% (GC) | A representative isocyanide product corresponding to the typical endpoint in which N-benzylformamide-type substrates are dehydrated to isocyanides under triphosgene conditions. |
Note: The products listed above are representative Aladdin products. For more product specifications, please refer to the product list at the end of the article or search the Aladdin website using the “product name/CAS/catalog number.”
References
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