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    The Science of Tea Extracts: Creating Realistic Iced Tea Profiles

    Author: R&D Team, CUIGUAI Flavoring

    Published by: Guangdong Unique Flavor Co., Ltd.

    Last Updated:  Jul 01, 2026

    WhatsApp & Telegram: +86 189 2926 7983

    A premium editorial photo of a golden-amber iced tea glass with lemon and fresh tea leaves — illustrating the beverage flavor science explored in this technical article by CUIGUAI Flavoring.

    Iced Tea Glass

    Introduction: Why Iced Tea Is the Most Chemically Complex Beverage to Replicate

    The global ready-to-drink (RTD) iced tea market was valued at USD 25.0 billion in 2025 and is projected to reach USD 39.5 billion by 2035, growing at a steady CAGR of 4.7% (Fact.MR, 2025). Despite this commercial scale, the task of replicating a truly authentic iced tea flavor in an industrial RTD formulation remains one of the most technically demanding challenges in beverage flavor science.

    Why? Because tea is not one flavor — it is a dynamic, multi-layered sensory system built from hundreds of interacting chemical compounds: polyphenols, amino acids, volatile aromatics, alkaloids, and pigments. Each of these compound classes behaves differently during extraction, processing, pH adjustment, sweetening, and shelf storage. The final consumer experience — that characteristic balance of brisk astringency, floral aroma, clean sweetness, and cooling finish — is the product of an extraordinarily complex chemical choreography.

    For beverage flavor manufacturers, the central question is: how do you capture, stabilize, and faithfully reproduce that choreography at industrial scale? This technical guide, authored by the R&D team at CUIGUAI Flavoring (Guangdong Unique Flavor Co., Ltd.), answers that question through a rigorous, science-based analysis of tea extract chemistry, aroma compound behavior, extraction kinetics, and industrial formulation strategy.

    Whether you are developing a new RTD iced tea SKU, an iced tea powder mix, or a iced-tea-flavored confection, the principles in this article will provide the technical foundation you need to formulate with precision and authenticity.

    1. The Chemical Architecture of Tea: What Makes Tea Taste Like Tea

    Understanding how to create a realistic iced tea flavor profile requires a deep understanding of the source material itself. The Camellia sinensis plant produces a leaf that contains five major classes of flavor-active compounds, each contributing differently to the sensory experience.

    1.1 Polyphenols: The Engine of Astringency and Body

    Polyphenols are the dominant flavor compounds in tea, comprising 25–35% of dry leaf weight. The most important subclass for iced tea flavor is the catechins — a group of flavan-3-ol molecules that include:

    • Epigallocatechin gallate (EGCG): the most abundant catechin; primary driver of astringency and bitterness
    • Epigallocatechin (EGC): contributes greenness and mild astringency
    • Epicatechin gallate (ECG): contributes bitterness and some astringency
    • Epicatechin (EC): the mildest catechin; contributes a soft, slightly bitter note

    Research published in the Journal of Agricultural and Food Chemistry (ACS Publications) found that catechin contents increase by 30–40% when teas are extracted for an extended period of 10 minutes compared to standard infusions — a critical parameter for industrial flavor extraction. Galloylated catechins (EGCG, ECG) are significantly more astringent than their non-galloylated counterparts (EGC, EC), and this ratio fundamentally determines the perceived “briskness” of the final iced tea product.

    1.2 Theanine and Amino Acids: The Umami-Like Backbone

    L-theanine (N-ethyl-L-glutamine) is the dominant free amino acid in tea, comprising 1–3% of dry leaf weight. It has a profound impact on flavor perception: theanine suppresses the bitterness and astringency of catechins, contributing a characteristic umami-like smoothness and sweetness that rounds out the harsh edges of polyphenols. The ratio of theanine to catechins is a critical quality parameter — premium teas typically have higher theanine-to-catechin ratios, producing a smoother, more complex cup.

    In iced tea formulation, theanine is rarely added as a direct ingredient due to cost and regulatory considerations. Instead, flavor formulators must engineer the perception of theanine’s smoothing effect through sweetener selection, pH management, and specific flavor modulating compounds.

    1.3 Caffeine: The Bitterness Modulator

    Tea contains 2–4% caffeine by dry weight, making it a significant flavor-active compound beyond its physiological effects. In flavor chemistry, caffeine contributes clean bitterness that is distinct from the astringent bitterness of catechins. Critically, caffeine forms complexes with catechins during brewing, which actually reduces the perceived astringency of galloylated catechins — a molecular interaction that is partially disrupted when tea is cooled, which is why iced tea can taste more bitter and astringent than its hot-brewed equivalent at the same catechin concentration.

    According to a comprehensive review published in PubMed Central (PMC ID: PMC12031152), the interaction between caffeine and catechins at reduced temperatures is a key variable that beverage formulators must account for when designing cold-serve tea products.

    1.4 Volatile Aroma Compounds: The Fragrance of Tea

    The aroma of tea is generated by a complex mixture of over 700 volatile organic compounds (VOCs), of which approximately 70–80 are considered flavor-active at threshold concentrations. Key aroma compound categories include:

     

    Of these, linalool, geraniol, and beta-ionone are considered the most critical for a “classic” black iced tea aroma, while methyl salicylate (wintergreen-like) is the signature marker compound for traditional sweet iced tea profiles popular in North America. For green iced tea, the profile shifts toward leafy/grassy esters and fresh terpene alcohols, while white tea iced profiles rely heavily on honey-like aldehydes and delicate ionones

    A scientific flat-design illustration of EGCG and catechin molecular structures, with the galloyl ester group highlighted. This image supports the technical article on tea extract chemistry for iced tea flavor formulation.

    Tea Polyphenol Chemistry

    2. Extraction Science: How Brewing Method Defines Flavor Identity

    Every iced tea flavor profile begins with extraction. The method of extraction — temperature, time, water chemistry, and leaf-to-water ratio — is arguably the single most important variable determining the chemical composition of the resulting tea base. For industrial flavor manufacturers who must consistently replicate specific profiles, understanding extraction kinetics is non-negotiable.

    2.1 Hot Extraction: High Yield, High Astringency

    Traditional hot brewing (80°C–100°C) relies on elevated temperature to accelerate the diffusion of flavor compounds from the leaf cellular matrix into the aqueous phase. The kinetics are fast: most catechins, caffeine, and amino acids are extracted within 3–5 minutes. However, high-temperature extraction also drives the extraction of tannins and high-molecular-weight polyphenols that are not present in cold-brew profiles, contributing to greater astringency and bitterness.

    Research from the National Center for Biotechnology Information (NCBI, PMC ID: PMC4573099) demonstrated that brewing at 85°C for 3 minutes represents an optimal balance point for black tea, maximizing EGCG concentration at 50.69 mg/100 mL while maintaining the highest sensory scores. Above this temperature and time threshold, bitterness rapidly increases and desired floral aromas degrade.

    For industrial flavor production, hot extraction is typically performed in counter-current extraction tanks at carefully controlled temperatures. The resulting concentrate is then subjected to clarification (centrifugation + ultrafiltration) to remove insoluble material before concentration and encapsulation.

    2.2 Cold Brew Extraction: Low Astringency, High Aroma Retention

    Cold brew extraction (2°C–25°C, 4–24 hours) produces a fundamentally different chemical profile. Due to the lower thermal energy driving diffusion, galloylated catechins (EGCG, ECG) are extracted at significantly lower rates compared to their non-galloylated counterparts, resulting in a lower astringency, higher perceived sweetness, and brighter floral character

    A 2025 study on cold brew extraction found that cold water extracts only about 53% of the EGCG that hot water does at equivalent leaf-to-water ratios. Conversely, aromatic volatile retention is substantially higher in cold brew, as the low-temperature environment prevents the thermal degradation of heat-labile aldehydes, esters, and terpene alcohols that characterize the “fresh” tea aroma.

    This makes cold brew extraction increasingly attractive for premium RTD iced tea products seeking a “cleaner” and more “natural” flavor identity. However, it creates formulation challenges: cold brew extracts are microbiologically more vulnerable than hot-extracted equivalents, requiring more careful downstream processing to achieve commercial shelf stability. For manufacturers seeking expert guidance on cold beverage flavor systems, our technical resource on engineering authentic RTD beverage flavors explores these principles in detail across parallel beverage categories.

    2.3 The Water Chemistry Factor

    Water minerality is a critically underappreciated variable in tea flavor extraction. A 2026 study in Food Research International (Elsevier) demonstrated that purified water (PW) and deionized water (DW) produced higher catechin and caffeine extraction levels — intensifying astringency and bitterness — while double-deionized water (DDW) enhanced sweetness perception and reduced astringency. Calcium and magnesium ions in water interact directly with tea polyphenols, forming insoluble complexes that reduce polyphenol bioavailability and modify flavor balance.

    For RTD manufacturers using municipal water supply, water treatment and mineral standardization are essential pre-steps in maintaining batch-to-batch flavor consistency. Formulating to a standardized water hardness of 50–150 ppm (as CaCO₃) is a common industry practice for iced tea production.

    A split-view technical illustration comparing hot and cold tea extraction methods, showing how temperature affects catechin yield, aroma compound retention, and the final iced tea flavor profile.

    Hot vs Cold Brew Tea

    3. Engineering Authentic Iced Tea Flavor Profiles: A Technical Framework

    With a clear understanding of the source chemistry and extraction variables, we can now address the central technical challenge: how do flavor manufacturers engineer authentic, stable, and scalable iced tea flavor systems for industrial beverage production?

    3.1 The Four-Dimension Flavor Model for Iced Tea

    At CUIGUAI Flavoring, we conceptualize iced tea flavor profiles along four dimensions, each requiring independent technical management:

    3.2 Astringency Calibration: The Art of Polyphenol Fractionation

    The most technically demanding aspect of iced tea flavor replication is calibrating astringency to the target profile without making the beverage harsh or unpalatable. The key tool is polyphenol fractionation — the selective concentration or depletion of specific catechin species using membrane filtration or chromatographic separation.

    For a classic American sweet iced tea profile (smooth, moderately astringent, very sweet): the target galloylated catechin fraction should be maintained at 15–25% of total polyphenols, with heavy sweetener loading (10–12% sucrose equivalent) to balance the astringency perception.

    For a premium British-style black iced tea profile (brisk, full-bodied, moderately bitter): galloylated catechins should represent 40–55% of total polyphenols, with a thinner sweetener load to let the astringency “bite” show through.

    For a Japanese green iced tea (ryokucha) profile: catechin fractionation should favor EGC and EC (non-galloylated), with a higher theanine content to produce the characteristic umami-sweetness that differentiates sencha-style profiles from black tea.

    3.3 Aroma Reconstruction: Volatiles Engineering for Stability

    The “fresh brew” aroma of iced tea is dominated by heat-labile volatile compounds that are rapidly lost during: (1) high-temperature extraction, (2) UHT/pasteurization processing, and (3) cold storage over time. Reconstructing this aroma in an industrial RTD product requires a staged volatiles engineering approach

    • Step 1 — GC-MS fingerprinting of the target tea variety: identify the top 15–20 aroma-active compounds by Odor Activity Value (OAV).
    • Step 2 — Aroma reconstitution: synthesize or source individual aroma compounds and blend them in proportions matching the GC-MS fingerprint.
    • Step 3 — Thermal stability testing: identify which compounds are degraded during pasteurization and require protective encapsulation.
    • Step 4 — Encapsulation selection: choose appropriate wall materials (cyclodextrins, modified starch, gum arabic) for microencapsulation of labile volatiles.
    • Step 5 — Post-process addition: wherever production allows, add encapsulated aroma fractions post-pasteurization to maximize freshness in the finished product.

    The most critical compounds requiring encapsulation are linalool, geraniol, and aldehydes such as benzaldehyde and phenylacetaldehyde. These contribute the “fresh-brewed” floral top note that distinguishes premium iced tea from lower-quality RTD equivalents. Beta-cyclodextrin complexation is particularly effective for terpene alcohols, achieving 5–8x improvement in thermal stability during pasteurization.

    3.4 Sweetener Interaction and Flavor Modulation

    The choice of sweetener system has a profound effect on the iced tea flavor profile — not merely as a masking agent for astringency, but as an active flavor modulator. Key considerations:

    • Sucrose: provides the most natural mouthfeel and enhances floral aroma perception through polarity effects; preferred for premium positioning.
    • High-fructose corn syrup (HFCS): slightly suppresses the perception of bitter catechins; widely used in cost-optimized formulations.
    • Sucralose: interacts with certain polyphenols to produce metallic off-notes at high concentrations; must be carefully dosed and complemented with mouthfeel enhancers.
    • Stevia (Rebaudioside A): the lingering sweet aftertaste of Reb-A can conflict with the “clean finish” expected in high-quality iced tea; blending with erythritol reduces this effect.
    • Acesulfame-K: frequently used in combination with sucralose at 1:1–3:1 ratio to improve temporal sweetness profile and reduce metallic notes.

    For health-positioned products, monk fruit extract (luo han guo) is gaining ground as a premium sweetener for iced tea, as its flavor profile is considered more compatible with tea polyphenols than stevia at equivalent sweetness levels. The natural citrus-adjacent notes in some monk fruit extracts can also complement lemon iced tea profiles effectively.

    4. Tea Variety Profiling: Black, Green, White, and Oolong

    Different tea varieties present fundamentally different flavor engineering challenges. Understanding the chemical identity of each variety is essential for creating authentically differentiated products in a competitive RTD market.

    4.1 Black Tea: The Foundation of Classic Iced Tea

    Full oxidation during processing converts catechins into theaflavins and thearubigins — the characteristic reddish-brown pigments and astringency compounds of black tea. Theaflavins are the most important quality markers: they contribute brisk astringency and bright, coppery color, while thearubigins contribute body and a darker color. The theaflavin content typically ranges from 0.5–2.5% of dry weight, with higher theaflavin content correlating with higher quality and stronger “bite.”

    For classic iced tea formulation, theaflavin-rich black tea extracts are the preferred raw material. Sri Lankan (Ceylon) and Kenyan black teas are particularly prized for their high theaflavin content and the resulting brisk, bright iced tea profile. Assam teas contribute malty, robust notes that work well in concentrated milk-tea applications.

    4.2 Green Tea: The Antioxidant-Forward Profile

    Unoxidized green tea retains the full catechin complement, with EGCG typically representing 50–80% of total catechins. The aroma of green tea is dominated by leafy, vegetal, and grassy compounds including cis-3-hexen-1-ol (fresh-cut grass), indole (floral/jasmine), and various pyrazines (roasted, in pan-fired varieties). Iced green tea formulation must balance the intensely vegetal raw notes of the extract with sweeteners and flavor modifiers that prevent a “seaweed-like” off-note from dominating.

    The trend toward matcha-flavored RTD beverages has created a specialized sub-category requiring even more precise flavor management. Authentic matcha flavor is characterized by its unique umami-forward, creamy, and slightly marine profile — derived from high theanine content and specific L-serine and glycine amino acid interactions.

    Our Beverage Flavors product range includes specialized green tea and matcha flavor concentrates designed for RTD beverage manufacturers seeking consistent, authentic plant-based taste profiles across high-volume production runs.

    4.3 White Tea: The Delicate Premium Profile

    White tea, made from young buds and minimal processing, has the lowest catechin content (approximately 15–20% lower than green tea) but the highest concentration of delicate aldehydic aromatics — particularly phenylacetaldehyde (rose-like) and nonanal (fatty, waxy). The flavor is subtle, sweet, and floral, with almost no astringency.

    Replicating white tea in an RTD product is challenging precisely because of its subtlety: consumers have very low tolerance for off-notes in a white tea product, making high-purity raw materials and minimal processing essential. White tea flavor concentrates typically require specialty fractionation to preserve the delicate aldehyde balance that defines the profile.

    4.4 Oolong Tea: The Complexity Challenge

    Partially oxidized oolong teas occupy the chemical space between green and black tea, with oxidation levels ranging from 15% to 85%. This creates extraordinarily diverse flavor profiles — from the fresh, fruity, floral character of lightly oxidized Taiwan High Mountain oolong to the rich, roasted, caramel notes of heavily fired Wuyi Rock oolong (Da Hong Pao).

    The most aroma-intensive oolongs — particularly Taiwanese Oriental Beauty (Dongfang Meiren) — are characterized by the unique biosynthesis of linalool oxide and phenylacetaldehyde triggered by leafhopper insect activity on the tea plant. These compounds create the characteristic “honey-like” or “muscatel” aroma that commands significant market premium in specialty RTD formulations.

    5. Industrial Formulation Strategies: Stability, Scalability, and Compliance

    5.1 Thermal Processing Challenges: Preserving Flavor Through Pasteurization

    Industrial iced tea production requires either HTST (High Temperature Short Time) pasteurization (72°C/15 sec) or UHT processing (135°C/3–5 sec) for microbiological stability. Both processes impose significant thermal stress on the flavor system:

    • Aldehydes (benzaldehyde, phenylacetaldehyde): highly volatile, 50–70% loss during UHT
    • Terpene alcohols (linalool, geraniol): 30–50% loss during UHT; moderate loss during HTST
    • Catechins: relatively stable; <5% degradation during standard pasteurization
    • Theaflavins: moderate degradation at UHT conditions; thearubigins more stable
    • Caffeine: very stable; negligible thermal degradation under RTD conditions

    The flavor formulation strategy must compensate for these losses. Standard approaches include: (1) aroma over-dosing (adding 1.5–2.5x the target concentration of heat-labile compounds before processing), (2) microencapsulation (protecting volatiles in cyclodextrin or modified starch shells before processing), and (3) post-process flavor addition (injecting pre-sterile flavor directly into the product line after the thermal step).

    5.2 pH Management and Tannin Precipitation

    Iced tea is typically formulated at pH 3.0–4.0 for flavor balance and microbiological stability (organic acid additions). However, pH strongly influences catechin stability and color:

    • Below pH 3.0: catechins are highly stable but the beverage may taste excessively sour
    • pH 3.0–4.5: optimal flavor balance; moderate catechin stability; acceptable color
    • Above pH 5.0: rapid catechin epimerization and tannin precipitation; color browning accelerates

    The acidulant choice matters significantly: citric acid is preferred for clean, bright acid character in citrus-infused iced teas; malic acid provides a softer, fruitier sourness suitable for peach or raspberry iced tea profiles; tartaric acid is used in premium applications for its wine-like acid complexity.

    5.3 Regulatory Considerations and Clean Label Compliance

    Global regulatory frameworks for iced tea flavors vary significantly:

    For manufacturers targeting clean-label positioning, CUIGUAI Flavoring offers FEMA GRAS-reviewed, natural flavor concentrates formulated without artificial colors, artificial preservatives, or non-declared flavor enhancers — meeting the requirements of EU Regulation 1334/2008, FDA natural flavor definitions, and GB 2760 standards. This regulatory versatility is particularly valuable for brands exporting across multiple markets.

    For a deeper understanding of how advanced flavor systems can help beverage brands extend product freshness while maintaining clean-label compliance, we recommend our technical article: Natural Shelf Life Extension with Food-Grade Flavors.

    6. Flavor Carrier Systems and Delivery Formats for Iced Tea

    The physical form in which iced tea flavors are delivered to beverage manufacturers significantly affects formulation flexibility, dosing precision, and final product quality.

    6.1 Liquid Flavor Concentrates

    Liquid concentrates — typically 5–40x strength, dissolved in propylene glycol, vegetable glycerin, or ethanol — offer the highest aroma fidelity because they preserve the full volatility profile of the tea extract. They are the preferred format for premium RTD beverages where authentic flavor character is the primary value proposition.

    Typical dosage rates: 0.05–0.5% w/w in the final beverage. Water-soluble liquid flavors are directly miscible with the beverage base; emulsified liquid flavors (for use in applications requiring turbidity enhancement) are formulated with emulsifiers and weighting agents.

    6.2 Spray-Dried Powder Flavors

    Spray-dried tea flavor powders are produced by encapsulating the liquid concentrate in a maltodextrin or gum arabic matrix, then drying to a free-flowing powder. They are ideal for instant iced tea powders, effervescent sachets, and stick-pack applications

    Key technical parameters: moisture content <3.5%, particle size 100–300 μm, encapsulation efficiency >85%. At CUIGUAI Flavoring, our spray-dried tea flavor range achieves >90% encapsulation efficiency for linalool and geraniol — preserving the top-note freshness through the reconstitution process.

    6.3 Tea Extract Concentrates (True Botanical Extracts)

    For the highest-authenticity applications, CUIGUAI Flavoring also produces standardized tea extract concentrates — true botanical extracts standardized to specific catechin and theaflavin content levels. These extracts bridge the gap between flavor additives and functional ingredient suppliers, enabling manufacturers to simultaneously deliver authentic flavor and documented antioxidant content — a powerful positioning for health-conscious RTD tea brands.

    Standardized extract specifications typically include: total polyphenols 40–70% (Folin-Ciocalteu method), theaflavins 5–15% (for black tea extracts), and EGCG 25–45% (for green tea extracts). Batch certificates of analysis with full polyphenol profiling are provided for each production lot.

    7. Advanced Applications: Beyond Classic Iced Tea

    7.1 Fruit-Infused Iced Tea Blends

    Fruit-infused iced teas — peach, lemon, raspberry, passion fruit — represent the largest volume segment of the RTD iced tea category. Successful formulation requires careful compatibility testing between the tea polyphenol fraction and the fruit flavor system, since certain fruit esters (particularly those with free carbonyl groups) can react with catechins to form off-flavor adducts during storage.

    Best practice: use thermally stable ester analogs rather than native fruit esters in the base flavor, and add any volatile fruit top-notes via encapsulated post-processing addition. Peach iced tea, the world’s largest RTD tea flavor, achieves its characteristic profile through a careful balance of gamma-undecalactone (peach lactone), benzaldehyde (almond/floral), and linalool against the astringent tea base.

    7.2 Milk Tea and Bubble Tea Applications

    The explosive global growth of bubble tea (boba) and milk tea concepts has created entirely new technical demands for tea flavor manufacturers. Milk tea applications require tea flavor systems that remain stable in the presence of dairy proteins (caseins, whey proteins) and non-dairy alternatives (oat milk, almond milk, coconut milk)

    The key challenge is polyphenol-protein binding: catechins readily complex with milk proteins, reducing both the perceived astringency of the tea AND the bioavailability of the protein. Flavor systems designed for milk tea applications must account for this binding by either dosing to compensate for the catechin binding effect or using structurally modified polyphenol analogs that retain flavor activity but have reduced protein-binding affinity.

    7.3 Functional Iced Tea: Adaptogens, Nootropics, and Botanicals

    The functional beverage revolution has reached iced tea. Manufacturers are increasingly adding adaptogens (ashwagandha, rhodiola), nootropics (lion’s mane, bacopa), and botanical extracts (hibiscus, chamomile, elderflower) to iced tea bases, creating multi-functional beverages that combine the familiar tea category with specific health positioning claims.

    This creates significant flavor engineering challenges, as many adaptogenic and botanical extracts carry intense bitter, earthy, or herbaceous flavors that must be harmonized with the tea base profile. Advanced flavor masking and modulation techniques — using bitter-blocking compounds, umami enhancers, and specialized sweetener combinations — are essential for producing consumer-acceptable functional iced tea products.

    8. Conclusion: The Future of Iced Tea Flavor Formulation

    The science of creating realistic iced tea profiles is one of the most intellectually rewarding — and commercially consequential — domains in beverage flavor chemistry. It requires an integrated understanding of plant biochemistry, extraction engineering, thermal processing science, sensory psychophysics, and regulatory compliance.

    Three trends will define the next decade of iced tea flavor innovation:

    • Hyper-varietal specificity: consumers increasingly seek RTD teas that authentically represent specific geographic origins — Ceylon from Nuwara Eliya, Darjeeling First Flush, Taiwanese High Mountain — requiring GC-MS-backed flavor fidelity that goes far beyond generic “black tea flavor.”
    • Cold brew authenticity at scale: the demand for cold-brew-style iced tea profiles will continue growing, requiring manufacturers to invest in extraction technology and encapsulation science that preserves the cold brew aroma fingerprint through industrial-scale thermal processing.
    • Functional integration: iced tea will continue its evolution from a simple refreshment to a functional beverage platform, requiring flavor systems that can harmonize tea character with complex botanical and functional ingredient profiles.

    At CUIGUAI Flavoring, we are at the forefront of all three trends — combining deep analytical chemistry capabilities, a library of over 20,000 proprietary flavor formulas, and close technical collaboration with beverage manufacturers to develop iced tea flavor solutions that are authentic, stable, scalable, and regulatory-ready for global markets.

    CUIGUAI Flavoring's beverage R&D laboratory featuring GC-MS analysis equipment, polyphenol fractionation systems, and tea flavor concentrate production lines — supporting authentic iced tea flavor development for global RTD manufacturers.

    Tea Flavor Lab

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    References & Authority Sources

    [1] ACS Publications. “Total Phenol, Catechin, and Caffeine Contents of Teas Commonly Consumed in the United Kingdom.” Journal of Agricultural and Food Chemistry, 2001. doi:10.1021/jf010153l

    [2] NCBI PubMed Central. “Effects of different brewing conditions on catechin content and sensory evaluation.” PMC ID: PMC4573099. 2015.

    [3] NCBI PubMed Central. “Deciphering the Flavor Chemistry, Processing and Quality Evaluation of Tea.” PMC ID: PMC12939469. 2025.

    [4] Elsevier. “Effects of different types of water on the sensory and chemical properties of brewed tea.” Food Research International, 2026. doi: 10.1016/j.foodres.2026.

    [5] Fact.MR. “Ice Tea Market Analysis 2025–2035.” November 2025. Available at: factmr.com.

    [6] The Insight Partners. “RTD Iced Tea Market Demand, Share & Growth by 2034.” 2025. Available at: theinsightpartners.com.

    [7] FEMA – Flavor and Extract Manufacturers Association. “FEMA GRAS Program.” Available at: www.femaflavor.org.

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