Cis-3-Hexenol: Chemical ID, CAS Formula, HS Code Database

Property	Industrial Manufacturer Commentary
Product Name	Cis-3-Hexenol
IUPAC Name	(Z)-Hex-3-en-1-ol
Chemical Formula	C6H12O
CAS Number	928-96-1
Synonyms & Trade Names	Cis-3-Hexen-1-ol, Leaf Alcohol, (Z)-3-Hexenol Trade names can reflect regional or application preferences. Process-dependent impurity levels and minor components define suitability for flavors, fragrances, or formulation intermediates. Local market naming may align with regulations on agricultural scents.
HS Code & Customs Classification	HS Code: 29053990 (Aliphatic alcohols, nes) Common customs classification follows the alcohol category within Chapter 29, adjusted per local tariff requirements. Misclassification risk increases for grades typically crossing between technical and food or fragrance uses, so documentation needs to specify intended application and composition, especially with respect to isomer ratios and trace impurity tolerances.

Manufacturer’s Technical Commentary

Product Identification in Industrial Context

Industrial production runs often differentiate cis-3-hexenol grades based on isomeric purity, residue solvents, and trace byproducts. Process selection—such as catalytic hydrogenation of cis-3-hexenal or Grignard routes—impacts both yield and impurity profile. Sourcing of raw materials (bio-based vs. synthetic) influences origin declarations and can affect the downstream olfactory profile, which is critical for flavor and fragrance segment supply commitments.

Customs Classification and Regulatory Considerations

Correct HS classification ensures compliance with destination country regulations. Alcohols in this carbon range, particularly with defined stereochemistry, require accurate documentation for both inbound customs and final user declarations, as mislabeling technical vs. food grade may prompt regulatory inspection or hold. Regulatory classification may depend on minor constituents and process residues, so release documentation includes route and impurity statement. Final release specification often requires alignment with customer application, whether perfumery, flavor, or formulation intermediate.

Cis-3-Hexenol: Technical Properties, Manufacturing Process & Safety Guidelines

Physical & Chemical Properties

Physical State & Appearance

Manufactured cis-3-hexenol presents as a clear liquid in most industrial grades, though minor yellow-green tints can appear in crude fractions. The odor profile is sharply green, often described as reminiscent of freshly cut grass. Melting and boiling points reflect grade and purity; pure grades show a boiling point within the expected range for C6 green leaf alcohols. The flash point is typically low, so local storage rules for flammable liquids must be respected. Density values follow carbon backbone expectations but confirm batch-to-batch with calibrated equipment due to sensitivity to trace impurities and residual solvents during purification.

Chemical Stability & Reactivity

Cis-3-hexenol shows general stability during standard storage if controlled for light, oxygen, and container compatibility. Light and air can induce oxidation, leading to degradation and altered odor. Copper and certain metallic ions (from piping or gaskets) accelerate decomposition; stainless steel, glass, or approved plastics are the preferred handling materials. The specific stability profile shifts with concentration and presence of antioxidants.

Solubility & Solution Preparation

Solubility in water is relatively low and grade-dependent; solvent selection remains critical for formulating, blending, or testing. Industrial production often employs ethanol, propylene glycol, or other hydrophilic carriers for solution preparation. Custom blending protocols recognize sensitivity of cis-3-hexenol to pH and temperature during dilution.

Technical Specifications & Quality Parameters

Specification Table by Grade

Parameter	Food/Perfume Grade	Industrial Grade	Custom Grade
Purity (cis-3-hexenol)	Specified per end-use application, typically highest	Defined per process, may contain related C6 alcohols	Adjustable on request
Color	Clear, colorless to faint green	Light yellow-green permitted	Set as per need
Odor Strength	Strictly tested against standard	Control as appropriate	Custom panel and specification

Impurity Profile & Limits

Industrial and food/perfume grades establish maxima for trans isomers, saturated alcohols (n-hexanol), and residual aldehydes (hexanal). Source and level of impurity directly relate to synthesis and purification choices. Analytical limits depend on both customer and regulatory requirements.

Test Methods & Standards

Gas chromatography (GC-FID and GC-MS) forms the core methodology. Internal standards and retention time libraries are employed. Odor panel review checks organoleptic compliance for fragrance and flavor use. In-house method validation aligns with either ISO or customer-specific protocols where stipulated.

Preparation Methods & Manufacturing Process

Raw Materials & Sourcing

Manufacture involves either petrochemical or bio-based C6 feedstocks—technical choice depends on cost and sustainability demand. Market availability can drive process selection, with some grades requiring non-GMO, certified natural precursor streams for flavor use.

Synthesis Route & Reaction Mechanism

Primary routes include selective catalytic hydrogenation of trans-2-hexenal or hydroformylation-derivation approaches. Reaction mechanisms focus on cis-diastereoselectivity using specialized catalysts and conditions. Any racemization or isomerization challenge impacts cost and purification yield. Investment in feedstock quality and catalyst lifespan management are priorities.

Process Control & Purification

Key control points include temperature ramps, pressure settings, and catalyst loading in synthesis. Product stream requires staged distillation or chromatographic purification to isolate cis-isomer from trans and saturated alcohols. Metal-catalyzed processing demands strict residual metal testing post-purification.

Quality Control & Batch Release

Routine QC involves full GC profiling, appearance/odor panel, moisture analysis, and trace metal content where relevant. Release parameters reflect both internal batch-to-batch consistency and compliance with external standards or customer agreements. Changes in odor or color signal the need for investigation.

Chemical Reactions & Modification Potential

Typical Reactions

Cis-3-hexenol undergoes typical alcohol group reactions—esterification, oxidation, etherification. Its reactivity centers on the loosely held hydrogen of the alcohol group and the tendency to oxidize to hexanal under improper handling. Downstream use often targets synthesis of esters or as a green-note raw material for complex aroma compounds.

Reaction Conditions: Catalyst, Temperature, Solvent

Industrial reactions select mild acid catalysts and control reaction temperature to maintain cis stereochemistry. Solvent use is limited to compatible aliphatic or low-polarity organics, with removal protocols central in food-grade or fragrance manufacture.

Derivatives & Downstream Products

Most downstream modifications generate cis-3-hexenyl acetate or related esters, leveraging the key green-leaf olfactory profile. Product purity and precursor traceability dictate downstream suitability, especially in regulated applications.

Storage & Shelf Life

Storage Conditions

Recommended storage utilizes tightly sealed containers away from heat, moisture, direct sunlight, and sources of ignition. Nitrogen or inert gas blanketing extends quality for sensitive food or fragrance batches. Temperature range and headspace management remain grade and application specific.

Container Compatibility

Preferred materials for bulk and intermediate-scale storage are stainless steel, HDPE, or specialty-lined drums and tanks. Brass, copper, and low-grade steel containers risk contamination and product breakdown.

Shelf Life & Degradation Signs

Observable degradation occurs through odor loss (muting, souring), color change (from clear to yellowish), and formation of non-volatile residues. Shelf life is specified according to customer product requirements and actual observed stability data. Monitoring is continuous for high-purity and regulatory-controlled grades.

Safety & Toxicity Profile

GHS Classification

Cis-3-hexenol is flammable and may cause eye and skin irritation. Standard GHS category assignment reflects its flashpoint and potential for irritation with direct contact or inhalation of concentrated vapor.

Hazard & Precautionary Statements

Key hazards center on fire risk and skin or respiratory exposure during transfers. Recommended precautions include using local exhaust ventilation, protective gloves, and flash-proof clothing. Fire-fighting protocols call for foam, dry chemical, or CO₂—never water in case of bulk fires.

Toxicity Data

Toxicological concern for cis-3-hexenol is low in occupational settings when handled according to standard hygiene protocols. Eye and skin sensitization has been reported with undiluted material in confined spaces. Ingestion data is referenced for food end-use but handled apart from process-grade material.

Exposure Limits & Handling

Typical workroom exposure values require engineering controls to keep vapor concentration below recognized limits for volatile organic compounds. Local, regional, or customer-specific workplace standards may govern allowable levels more strictly for flavor or fragrance manufacturing. Personal monitoring supports long-term exposure control.

Cis-3-Hexenol: Supply Capacity, Commercial Terms & 2026 Price Trend Forecast

Supply Capacity & Commercial Terms

Production Capacity & Availability

In the industrial manufacturing of cis-3-hexenol, output remains tightly linked to both the seasonal sourcing of plant-based raw materials and process route selection. Natural extraction routes lead to variable capacity due to fluctuations in green leaf biomass availability, while synthetic routes show higher production stability but depend heavily on precursor supply consistency. Annual output can shift during raw material shortages or market-driven allocation shifts. For specialty and flavor-grade applications, dedicated production lines with tight batch tracking are often required, further segmenting available volumes.

Lead Time & Minimum Order Quantity (MOQ)

Lead times in the industry shift with production planning complexity, particularly during peak demand from the flavor, fragrance, and agrochemical sectors. Orders placed during harvest or post-harvest periods for natural grades may face longer lead times due to upstream material processing. Synthetic grades generally support shorter lead cycles. The minimum order quantity aligns with grade, packaging choice, and customer qualification protocol. Drum and ISO tank orders for industrial users often allow for lower MOQs compared to highly purified grades used by specialty formulators.

Packaging Options

Packaging integrity depends both on shipment mode and purity requirements. Industrial drums and IBCs serve robust routes, while specialty grades demand custom containers with inert linings to mitigate oxidation or cross-contamination risk. Export shipments require compliance with international transport regulations, and packaging traceability documentation aligns with client and regulatory certification.

Shipping & Payment Terms

Bulk shipments leverage established sea and land freight routes, with temperature and humidity control for higher grades prone to degradation. Payment terms depend on client credit status, contract duration, and market risk assessment. Advance payment, letter of credit, or open account terms are decided on a case-by-case basis, considering production planning and market volatility.

Pricing Structure & Influencing Factors

Raw Material Cost Composition

The unit cost of cis-3-hexenol ties closely to the source of synthesis: natural extraction routes depend heavily on green plant material pricing, which fluctuates with weather, crop yield, and labor costs. Synthetic routes derive cost structure from upstream chemical feedstocks, notably hexanal or related alkenes, and process reagent pricing. Volatility in agricultural or petrochemical supply chains transfers directly to manufacturing margins.

Fluctuation Causes

Market price swings follow environmental conditions, geopolitical trade pressures, and regulatory changes impacting precursor access. Unplanned events—droughts, plant disease outbreaks, petrochemical plant turnarounds—ripple through the price structure. Regulatory focus on solvent or byproduct handling can alter processing costs in response to compliance demands.

Product Price Difference Explanation: Grade, Purity, Certification

Price variation stems from grade-specific purification steps and certification pathways. Higher-grade products require tighter impurity control, additional distillation or chromatographic refinement, and documentation for flavor, fragrance, or pharmaceutical applications. Certification protocols (FSSC 22000, ISO, Kosher, Halal) inject further differential into final pricing. Bulk industrial grades carry the lowest premium, while high-purity, application-certified lots reach the upper tier of the pricing spectrum. Packaging also impacts delivered cost: custom finished, inert-gas-packed units cost more per kilogram than standard drums.

Global Market Analysis & Price Trends

Global Supply & Demand Overview

International demand for cis-3-hexenol tracks consumer preferences for natural green notes in flavor and fragrance, as well as biopesticide sector uptake. Capacity remains concentrated in East Asia and Europe due to access to raw materials and downstream formulation clusters. Import and export flows respond quickly to regional harvests and local regulatory barriers.

Key Economies Analysis

The United States and European Union prioritize high-purity, certified grades for regulated consumer use, demanding extensive QA/QC documentation. Japan’s niche formulator base values ultra-purified grades. India and China anchor volume supply for both domestic use and international trade, with flexibility in grade segmentation and responsiveness to price signals from upstream raw material markets. Pricing tends to be more stable in high-regulation markets, but susceptible to spikes during major supply disruptions. In Asia, market fragmentation and rapid new capacity investment can cause localized supply gluts or shortages.

2026 Price Trend Forecast

Looking towards 2026, industrial forecasts see continued cost pressure from raw material volatility—climate uncertainty and supply chain disruptions threaten both extraction and synthetic routes. Ongoing regulatory tightening on VOC emissions and byproduct handling will likely prompt further consolidation among smaller producers, raising barriers for compliant capacity expansion. End-user demand is forecast to remain strong as flavor and fragrance customers pursue natural and labeled-safe ingredients. Price increases are most likely to occur in high-purity and specialty grades, outpacing those for industrial technical use.

Data Sources & Methodology

All forecasts and commentary are informed by direct procurement market surveys, customer order trends, public regulatory announcements, and multi-year production and shipment data tracked internally and via third-party industry consortia.

Industry News & Regulatory Updates

Recent Market Developments

Recent years have seen escalation in demand for traceable, certified-natural cis-3-hexenol grades, particularly within premium F&F segments. Seasonal disruptions in raw material supply challenged plant-extraction capacity, with synthetic process optimization increasingly adopted to offset these bottlenecks. Industry investment shifted toward enhanced purification and on-site QA infrastructure to satisfy tiered end-use requirements.

Regulatory Compliance Updates

Global agencies have continued to tighten allowable impurity thresholds, particularly for food and personal care end uses. Compliance pathways now demand increasingly granular batch traceability and third-party analytical validation. Environmental oversight intensified for solvent emissions and effluent standards, with related impacts on cost structure and production batch scheduling.

Supplier Response & Mitigation

Suppliers have pursued diversification of process routes to hedge against single-point raw material risks, investing in both extraction and synthetic technologies. Expansion of certified packaging and regional warehousing supports shorter lead times for compliant grades. Internal QA/QC teams raised audit frequency and pre-shipment release testing for high-value batches. Collaboration deepened with logistics partners to ensure controlled-temperature shipping options for sensitive grades, further addressing downstream product quality assurance.

Application Fields & Grade Selection Guide for Cis-3-Hexenol

Application Fields & Grade Matching Guide

Industry Applications

Cis-3-Hexenol, also known as leaf alcohol, finds direct use across flavor, fragrance, and specialty chemical manufacturing sectors. In food and beverage, it delivers characteristic fresh-green notes in fruit and vegetable flavors, as well as natural aroma compounds for gum and candy. Perfumery and personal care rely on this molecule’s profile to construct natural “cut grass” or green floral bases. Household and fabric care benefit from its sharp, clean scent in surface cleaners and detergents. Some agricultural and pest management applications use high-purity grades as semiochemical agents to simulate natural plant volatiles.

Grade-to-Application Mapping

Application	Typical Grade	Key Selection Factors
Flavor & Beverage	Food Grade / FCC-compliant	Purity, residual solvent profile, allergen documentation, regulatory compliance
Fragrance & Cosmetic	Perfumery/Fine Fragrance Grade	Olfactory purity, low aldehyde/acetate impurity content, consistent odor threshold
Household/Agricultural	Technical Grade / Custom Purity	Process impurity tolerance, cost-performance balance, custom stabilization

Key Parameters by Application

Food use grades require audit-backed documentation for traceability, preservatives, and solvent absence as well as batch-specific certificates. Fragrance grades put emphasis on impurity profiles; isomer ratios and trace aldehyde carryover can influence final aroma. Technical-grade product tolerates higher color and trace byproduct content if downstream matrix masks these effects. Bulk volume applications often focus on keeping cost and batch-to-batch variability within a narrow tolerance, accepting broader impurity margins if required by downstream compatibility.

How to Select the Right Grade

Step 1: Define Application

Establish the end-use context. Food flavor development leans toward the highest purity with globally recognized compliance. Fine fragrance builders look for tightly managed impurity profiles. Large-scale technical users weigh cost, chemical compatibility, and formulation latitude against sensory standards.

Step 2: Identify Regulatory Requirements

Check for regional and application-specific restrictions - such as GRAS status for US food work or REACH dossier requirements in Europe. For flavor and fragrance uses, source documentation addressing FEMA or IFRA guidelines may be necessary. Customers in regulated spaces often request detailed impurity breakdown and route documentation as part of the validation process.

Step 3: Evaluate Purity Needs

Determine purity threshold and impurity maximums based on the sensitivity of the end-product application. In our technical practice, food and high-end perfumery customers expect multi-parameter GC trace records for each batch. Technical consumers in agricultural or cleaning applications may accept material with broader impurity distribution, subject to non-interference with performance or stability.

Step 4: Consider Volume & Budget

Assess production scale, frequency, and price sensitivity. Small and medium enterprises with niche products often require custom batch packaging, short lead times, and lot-specific support. Bulk purchasers of technical grade material usually place emphasis on delivered cost, supply assurance, and tank-to-tank homogeneity, while accepting larger package or direct bulk transfer.

Step 5: Request Sample for Validation

After shortlisting grades, application-specific evaluation remains key. Typical process includes sensory panel, stability study, and analytical cross-check versus internal reference or customer standard. Most industrial buyers run parallel downstream formulation trials with test lots, checking for matrix compatibility, shelf-life performance, and off-note risk. Dedicated technical staff review these results, with final release standards matching both internal controls and documented customer requirements.

Trust & Compliance: Quality Certifications & Procurement Support for Cis-3-Hexenol

Quality Compliance & Certifications

Quality Management Certifications

Our Cis-3-Hexenol production sites operate under an established quality management system. The system scope depends on regulatory requirements and customer segment. In practice, we regularly undergo third-party audits. Most of our facilities are certified to industry-recognized standards such as ISO 9001, where the focus is continuous improvement in process control, traceability, and corrective actions. These certifications provide a trackable system for trace deviations, batch recalls, and verification of documented process interventions.

Product-Specific Certifications

Certifications beyond ISO or GMP suitability depend on the target market and supplied grade. For applications in flavors or fragrances, conformance with applicable food contact regulations and IFRA guidelines may be supported if the upstream and downstream supply chain allows for traceability. Grades aimed at industrial or technical use have certification profiles tailored to their intended processing environment. All certificates are issued based on controlled batch release testing carried out within our site laboratory, using validated analytical methods aligned with customer specification and applicable standards.

Documentation & Reports

Full batch documentation is part of our standard offering for Cis-3-Hexenol. For each lot, release documentation includes analytical test reports reflecting both in-process control points and final product evaluation. The documentation set varies by grade, but typically covers assay, major and trace impurities, sensory profile, and, where agreed, residual solvent traces. Additional regulatory support files such as TSE/BSE statements, allergen status, or food safety documentation can be prepared according to end-use requirements. Data and reports are retained in the manufacturing site archive according to statutory or contractual retention periods.

Purchase Cooperation Instructions

Stable Production Capacity Supply and Flexible Business Cooperation Plan

We plan production of Cis-3-Hexenol by balancing confirmed contract volumes, historical order trends, and forecast demand signals. This ensures core stock is available even for buffer and short-order cycles. For customers with forecast or blanket needs, framework agreements support ongoing allocation, reducing the risk of allocation shortfall. Our commercial team coordinates with operations to adjust campaigns for seasonal or market-driven shifts.

Core Production Capacity and Stable Supply Capability

Batch scheduling and campaign planning are key control points. Production batches are matched to storage and transport requirements, taking into account shelf life and sensitivity to contamination and oxidation. For downstream customers that require consistent performance or compliance with strict odor and purity profiles, batch traceability and clockwork replenishment is prioritized. In the event of supply disruption—whether due to raw material issue or logistics interruption—contingency protocols provide options for alternate batch reservation or cross-facility consolidation, if permitted by the purchasing framework.

Sample Application Process

Sample requests for Cis-3-Hexenol involve technical screening. Users describe the intended application, quantity required, grade preference, and regulatory context. Standard sample packs are supplied with detailed Certificate of Analysis and, on request, extended documentation. Our technical support team provides feedback on handling, storage, and shelf life implications for small pack samples, ensuring that test evaluation reflects end-use conditions as closely as possible.

Detailed Explanation of Flexible Cooperation Mode

Business models include spot purchasing, mid-term blanket order, and volume-based supply agreements. Customized contract setups can address client-specific needs, such as make-to-order schedules, consignment inventory, or fixed release timing for integrated production lines. Adjustments in delivery format, bulk packaging, and documentation frequency can be negotiated to match the buyer’s operation tempo and traceability requirements, provided sufficient lead time. Such flexibility is managed in close collaboration between our supply chain planning staff and customer procurement teams.

Market Forecast & Technical Support System for Cis-3-Hexenol

Research & Development Trends

Current R&D Hotspots

Cis-3-Hexenol, recognized in the field as “leaf alcohol,” is produced from unsaturated alcohol synthesis processes, most commonly from hexenal precursors. At the manufacturing level, R&D currently focuses on catalytic hydrogenation options that improve selectivity and minimize by-products. The push toward greener oxidation and reduction methodologies drives much of the laboratory development, seeking to replace legacy processes that generate larger waste streams or require harsher reagents.

Interest also centers on achieving robust isomeric purity, since downstream aroma, flavor, and sensory performance rely on minimizing trans-isomer and higher-chain alcohol contamination. Analytical control for these isomers remains a development priority. R&D teams track separation techniques such as preparative chromatography and solvent-based extractions to align with industrial-scale throughput and cost targets.

Emerging Applications

Aside from established usage in flavors and fragrance compounding, new application areas draw attention. R&D teams collaborate with agrochemical formulators aiming to exploit cis-3-hexenol’s role in plant signaling and pest behavior modification. Another growing domain appears in eco-friendly cleaning and deodorizing product matrices, where green odor profiles and regulatory-driven demand for biogenic ingredients provide new outlets.

Food-grade applications require very tight impurity specifications—batch data indicate aldehyde and peroxide content are the main watchpoints here. By contrast, industrial formulations can tolerate slightly wider impurity windows, though the impact on aroma profile must always be considered.

Technical Challenges & Breakthroughs

Maintaining consistent isomeric ratios at scale is a technical challenge. Common bottlenecks include incomplete reaction conversion, light- and oxygen-induced instability during storage, and losses in distillation recovery. Recent breakthroughs involve modular continuous-flow hydrogenation technology, which can deliver better control over heat, reactant ratio, and residence time compared to batch routes. Continuous monitoring of impurity drag-through—especially unsaturated aldehyde residues—forms a core part of current process control upgrades.

Future Outlook

Market Forecast (3-5 Years)

Macrotrends point toward a moderate growth trajectory for cis-3-hexenol across both mature and emerging markets. Demand for natural-analog and green-certified chemicals sets the stage for higher volumes, particularly where formulators target clean-label or sustainable consumer products. In the next three to five years, procurement data and customer project pipelines indicate moderate single-digit percentage annual growth, though region and application segment differences can result in supply pressure for high-purity or food-grade lots.

Technological Evolution

Feedstock rationalization and solvent recycling represent two main areas for technology improvement. Upstream, process safety and raw material cost stability factor into route selection, with bio-based starting materials attracting increased technical investment. Downstream, attention shifts to advanced fractionation and microfiltration techniques aimed at lowering energy demand and achieving tighter batch-to-batch consistency. Automated process analytics and real-time critical parameter tracking now integrate directly into new plant builds, allowing for improved predictive maintenance and process quality control.

Sustainability & Green Chemistry

Current sustainability efforts prioritize reducing solvent emissions and reagent waste. Green chemistry principles guide both raw material selection—favoring renewable feedstocks where throughput and cost allow—and waste minimization in process design. Established manufacturers review solvent recovery rates as part of internal environmental KPIs, targeting closed-loop process configurations. Transition to less hazardous auxiliary agents and maximization of atom economy are under active technical evaluation, with pilot batches run to confirm product consistency.

Product stewardship also extends to supply chain verification—traceability protocols support claims of sustainable sourcing for certain market segments, and integration with digital systems for lot provenance continues to advance.

Technical Support & After-Sales Service

Technical Consultation

Technical assistance covers process suitability assessments, onsite troubleshooting, and compatibility checks for various downstream applications. Production teams can advise on grade selection based on isomeric ratio requirements and contaminant specifications for end uses in flavors, fragrances, and agrochemical formulations. Analytical service includes support for method implementation to confirm assay and impurity profiles against customer standards.

Application Optimization Support

Application engineers work with formulating partners to optimize product integration according to matrix composition, volatility profile, and synergistic effects in multi-component blends. This includes pilot-scale testing to assess impact on final aroma or green note intensity, as well as guidance on storage practice to prevent oxidation or evaporation losses based on typical volatility and susceptibility to light or air exposure. Specific product grades may require tailored handling or blending procedures, which technical staff help define in collaboration with quality assurance.

After-Sales Commitment

After-sales support addresses batch-related inquiries, delivery traceability, and continuous improvement feedback loops. If storage, transportation, or formulation concerns arise, technical and quality control teams mobilize to investigate batch logs, run additional QC testing, and, where applicable, support root-cause identification. Follow-up technical visits and documentation assistance remain available as part of the ongoing relationship commitment. Adjustments to release criteria or tailored certificate of analysis formats are available on request, subject to discussion of the intended application and required compliance framework.

Manufacturing Cis-3-Hexenol: Factory Control and Industrial Focus

Cis-3-Hexenol occupies a central role across multiple industries, from flavors and fragrances to agrochemicals and functional consumer goods. At our facility, we manufacture Cis-3-Hexenol at commercial scale, overseeing all aspects of synthesis, purification, and final QC in-house. Our production line is dedicated to this molecule, allowing us to keep batch-to-batch characteristics within narrow tolerances. Process parameters have been refined through years of R&D and direct technical dialogue with industrial users.

Key Industrial Applications

Cis-3-Hexenol delivers the signature green, grassy aroma demanded by fragrance houses, perfumers, food flavor formulators, and home care product manufacturers. Formulators working in the flavor sector use our product for authentic green notes in beverages and bakery applications. For pest control and attractant technologies, this compound gives the targeted olfactory response for specific insect behavioral studies. We supply bulk quantities to customers who produce consumer goods, aromas, and functional additives at scale.

Product Consistency and Quality Control

Production starts with a controlled synthetic route, using monitored raw materials and traceability at each processing stage. Automated and manual inspection cover purity, isomeric ratio, and impurity profile. Gas chromatography, mass spectrometry, and wet chemical analysis guide release decisions. This level of control allows us to support applications that require both food-grade and industrial-grade variants. Every outgoing batch carries COA data generated in the same quality laboratory.

Packaging and Bulk Supply

Cis-3-Hexenol leaves our factory in tightly sealed containers, ranging from small cans to industrial drums and IBCs. Package selection follows compatibility with the product's volatility and reactivity, prioritizing product stability across varying storage temperatures. Large-volume supply contracts can be met with scheduled deliveries, minimizing line downtime for our customers. On-site filling and logistics management reduce the risk of delays for bulk industrial demand.

Technical Support for Commercial Use

Our technical team responds directly to industrial R&D and process engineers. We offer support on formulation integration, compatibility, and downstream process impact. Stability questions, blend trials, and regulatory documentation receive manufacturer-level input, reflecting hands-on understanding of the physical product and its chemical behavior. This gives procurement and production teams reliable answers for plant trials or compliance audits.

Business Value for Manufacturers, Distributors, and Procurement Units

Direct sourcing from our production site enables commercial users to benefit from lead time reduction, controlled supply cycles, and price models aligned to true manufacturing cost. Distributors handling supply chain logistics for large customers benefit from predictable specifications and transparent documentation. Procurement teams receive product directly from the line, which supports easier auditing and traceability compliance under ISO and local regulatory regimes. Our business model rests on manufacturing expertise, operational transparency, and continuous investment in process improvements to meet evolving industry requirements.

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