Fact-checked by Grok 2 weeks ago

Cetane index

The Cetane index is a calculated parameter that estimates the ignition quality of diesel fuel and other distillate fuels based on their physical properties, such as density and distillation temperatures, without the need for direct engine testing.^[1] It serves as an approximation of the cetane number, which measures the fuel's auto-ignition delay in a compression-ignition engine, and is particularly valuable for routine quality assessments in refineries, pipelines, and storage facilities.^[2] Developed under ASTM International standards, the cetane index is determined using methods like ASTM D976, which employs a two-variable equation incorporating density at 15°C and the 50% distillation recovery temperature (T50), or the more precise four-variable equation in ASTM D4737 that also includes the 10% and 90% distillation points (T10 and T90).^[3] These calculations are applicable to straight-run distillate fuels with cetane numbers typically between 30 and 60 but are not suitable for fuels containing significant cetane-improving additives or biodiesel blends, where discrepancies with actual cetane number can occur.^[3] In regulatory contexts, the cetane index plays a critical role in ensuring diesel fuel meets minimum performance standards for combustion efficiency, engine durability, and emissions control.^[4] Under U.S. Environmental Protection Agency (EPA) regulations (40 CFR Part 1090), nonroad, locomotive, and marine (NRLM) diesel fuel must have a minimum cetane index of 40, or alternatively, a maximum aromatic content of 35% by volume, to promote reliable ignition and reduced pollutants like particulate matter and nitrogen oxides.^[4] ASTM D975, the standard specification for diesel fuel oils, requires a minimum cetane number of 40 or, alternatively, a minimum cetane index of 40 and a maximum aromatic content of 35% by volume for No. 1-D and No. 2-D grades, aligning with broader international benchmarks where values around 45–51 are often mandated for on-road applications.^[5] Higher cetane index values correlate with shorter ignition delays, leading to smoother engine operation, lower noise, and improved cold-start performance, though excessive values offer diminishing returns and may increase costs without proportional benefits.^[3] Overall, the cetane index facilitates cost-effective compliance testing and helps maintain fuel quality across the supply chain, from production to end-use in automotive, industrial, and power generation sectors.^[2]

Fundamentals

Definition

The cetane index is a calculated value that approximates the ignition quality of diesel fuel, serving as an indicator of how readily the fuel auto-ignites under compression without requiring direct engine testing.^[6] It estimates the fuel's combustion characteristics based exclusively on measurable physical properties, providing a practical means to assess ignition performance in distillate fuels.^[7] This index correlates with but differs from the cetane number, which is determined through standardized engine tests.^[1] The cetane number was developed in the 1930s by the Cooperative Fuel Research Committee as part of broader efforts to evaluate diesel fuel performance more efficiently.^[7] An earlier precursor, the Diesel Index (introduced in 1934), used API gravity and aniline point to estimate ignition quality, paving the way for more accurate calculated methods. The cetane index was introduced later with ASTM D976 in 1966 as a simpler alternative to engine-based measurements, allowing for quicker and less resource-intensive quality checks.^[8] Early correlations between fuel properties and ignition behavior laid the groundwork for these calculations.^[8] Key physical properties used in cetane index calculations include the fuel's density and distillation profile, particularly the temperatures at the 10%, 50%, and 90% recovery points from a standardized distillation test.^[9] These parameters reflect the fuel's volatility and composition, influencing its ignition delay.^[10] The cetane index is reported in dimensionless units identical to those of the cetane number, with typical values for conventional diesel fuels falling in the range of 40 to 55.^[11]

Relation to Cetane Number

The cetane number serves as the primary, engine-based measure of ignition quality for diesel fuel, quantifying the ignition delay in compression-ignition engines through standardized testing. It is defined as the volume percentage of cetane (n-hexadecane) in a blend with 2,2,4,4,6,6,8-heptamethylnonane (HMN) that exhibits the same ignition performance as the tested fuel in a Cooperative Fuel Research (CFR) engine, as specified in ASTM D613.^[12] This direct, empirical assessment captures the fuel's actual combustion behavior under controlled conditions, typically ranging from 30 to 65 for commercial diesel fuels.^[13] For untreated, straight-run distillates—fuels derived directly from crude oil without cracking or additives—the cetane index closely approximates the cetane number, often assuming a near 1:1 correlation due to the reliance on similar physical properties like density and distillation characteristics.^[14] This alignment makes the cetane index a reliable estimator for such base fuels, where empirical correlations derived from these properties predict ignition quality with minimal deviation.^[8] However, the cetane index exhibits significant limitations when applied to cracked stocks or additized fuels, often resulting in discrepancies exceeding 5-10 cetane points compared to the measured cetane number. Cracked fuels, produced through processes like catalytic cracking, introduce complex hydrocarbons such as isoalkanes that can cause the index to overpredict ignition quality, as the calculation does not fully account for compositional variations beyond basic physical metrics.^[15] Similarly, for additized fuels, the cetane index remains unaffected by cetane improvers—chemicals like 2-ethylhexyl nitrate that can boost the cetane number by up to 10 units at typical treat rates of 0.5 vol%—leading to underestimation of the fuel's enhanced ignitability. These inaccuracies arise because the index is an empirical approximation based solely on unadditized fuel properties, rendering it unsuitable for modern refinery products or treated blends.^[11] In practice, the cetane index functions as a cost-effective proxy for the cetane number in scenarios where engine testing is unavailable, uneconomical, or impractical, such as routine quality control for untreated distillates in refineries or fuel specifications.^[7] This substitution is particularly valuable for estimating base fuel ignitability without the resource-intensive CFR engine procedure, though it requires validation against direct measurements for critical applications.^[1]

Calculation Methods

ASTM D976

The ASTM D976 method, originally approved in 1966, represents the first standardized approach developed by the American Society for Testing and Materials (ASTM) for calculating the cetane index of distillate fuels.^[1] This two-variable technique emerged in response to the need for a simple, non-engine-test alternative to directly measure cetane number, relying on readily obtainable physical properties to estimate ignition quality.^[8] The method employs fuel density at 15°C and the mid-boiling temperature, defined as the 50% recovery point from the distillation curve per ASTM D86.^[1] These inputs correlate with the fuel's hydrocarbon composition, providing an approximation of its autoignition characteristics without requiring additives or complex instrumentation. The calculated cetane index (CCI) serves as a supplementary indicator of cetane number for untreated diesel fuels, though it is not a direct substitute.^[1] The standard provides two equivalent equations for the calculation. In terms of API gravity and mid-boiling temperature in °F:

\text{CCI} = 420.34 + 0.016 G + 0.192 G \log M + 65.01 (\log M)^2 - 0.0001809 M^2

where G is the API gravity (measured via ASTM D287, D1298, or D4052) and M is the mid-boiling temperature in °F (from ASTM D86, corrected to standard pressure).^[1] Alternatively, using density and mid-boiling temperature in °C:

\text{CCI} = 454.74 - 1641.416 D + 774.74 D^2 - 0.554 B + 97.803 (\log B)^2

where D is the density at 15°C in g/mL (via ASTM D1298 or D4052) and B is the mid-boiling temperature in °C (from ASTM D86).^[1] These formulas are applicable to straight-run distillates, catalytically cracked stocks, and their blends, but exclude fuels containing cetane improvers, pure hydrocarbons, synthetic components, or those with distillation end points below 500°F.^[1] A key advantage of ASTM D976 lies in its simplicity, requiring only basic laboratory measurements like density and a single distillation point, making it accessible for routine quality control in refineries and fuel specifications for legacy diesel grades.^[7] However, it is less accurate for modern low-sulfur or hydrotreated fuels, where compositional changes due to severe refining processes can lead to overestimation of the cetane index, prompting the development of more advanced methods like ASTM D4737.^[16]

ASTM D4737

ASTM D4737, originally approved in 1987 by the American Society for Testing and Materials (ASTM), introduces a refined method for calculating the cetane index of distillate fuels, addressing limitations of prior approaches in handling modern refined diesel compositions through a multi-variable empirical equation. This standard enhances precision by integrating density and multiple distillation points, making it suitable for estimating cetane number without engine testing.^[17]^[6] The method's equation stems from multivariate linear regression applied to extensive empirical datasets, where physical properties like density and boiling range temperatures were correlated against cetane numbers obtained via cooperative engine tests under ASTM D613. Inputs include fuel density measured at 15°C per ASTM D4052 and distillation temperatures (T10, T50, T90 at 10%, 50%, and 90% recovered volume, corrected to standard pressure) from ASTM D86. These variables capture volatility and aromatic content influences on ignition quality. The derivation involved analyzing over 200 fuel samples to minimize prediction error, yielding coefficients that balance the contributions of each term.^[18]^[19]^[7] For conventional diesel fuels, the four-variable equation is:

\text{CCI} = 45.2 + (0.0892)(T_{10N}) + [0.131 + (0.901)B](T_{50N}) + [0.0523 - (0.420)B](T_{90N}) + (0.00049)(T_{10N}^2 - T_{90N}^2) + (107)B + (60)B^2

where T_{10N} = T_{10} - 215, T_{50N} = T_{50} - 260, T_{90N} = T_{90} - 310 (temperatures in °C), and B = \rho - 0.85 with density \rho in g/cm³. An alternative logarithmic equation, using exponential terms for normalized variables, extends applicability to fuels beyond typical diesel ranges, such as those with higher or lower densities.^[19]^[7]^[18] This approach achieves an accuracy of approximately ±3 cetane number units compared to direct engine measurements for non-additized fuels, with precision limited by the underlying density and distillation test variabilities (repeatability around 0.5–1.0 units depending on fuel type). It serves as the primary calculation tool in ASTM D975 specifications for diesel fuels, supporting quality control where cetane improvers are absent.^[7]^[19]

Applications and Importance

Fuel Specifications

The Cetane Index serves as a critical parameter in the ASTM D975 standard specification for diesel fuel oils in the United States, mandating a minimum value of 40 for Grade No. 2-D diesel to ensure adequate ignition quality.^[20] This requirement applies to both low-sulfur (S15) and higher-sulfur (S500) variants, where the index is calculated using physical properties like density and distillation characteristics, providing an alternative to direct cetane number measurement when engine testing is impractical.^[5] In international contexts, the EN 590 standard governs automotive diesel fuel quality across Europe, requiring a minimum Cetane Index of 46 alongside a minimum cetane number of 51 to promote consistent combustion performance and emission control.^[21] For global trade, the ISO 4264 procedure offers a standardized four-variable equation to compute the Cetane Index from density and distillation data, facilitating uniform quality verification in cross-border fuel transactions without reliance on proprietary additives.^[22] The Cetane Index is especially valuable in specifications for untreated or straight-run diesel fuels, where it assesses inherent ignition quality based on hydrocarbon composition, avoiding the need to disclose additive usage that could inflate measured cetane numbers.^[7] This approach ensures transparency in baseline fuel properties for regulatory compliance and blending operations. Historically, reliance on the ASTM D976 two-variable method dominated Cetane Index calculations before the 1990s, but post-2000 shifts toward the ASTM D4737 four-variable method occurred due to evolving refinery processes like hydrocracking, which reduced aromatic content and improved saturation, making the older method prone to overestimation.^[16] The updated method better correlates with actual ignition behavior in these processed fuels. Routine laboratory calculations of the Cetane Index support refinery quality control by monitoring batch consistency and enable certification for fuel trading contracts, where specified minimums ensure deliverable performance standards.^[2]

Engine Performance Effects

A higher cetane index is associated with a shorter ignition delay in diesel engines, typically ranging from 2 to 7 milliseconds during operation, which facilitates more controlled combustion initiation.^[7] This reduction in ignition delay helps minimize white smoke emissions, particularly during cold starts, by promoting more complete fuel vaporization and mixing before ignition occurs. Additionally, it contributes to improved cold start performance, allowing engines to reach stable operation faster in low-temperature conditions, and lowers combustion noise through smoother pressure rise rates in the cylinder. Quantitative assessments indicate that increases in cetane index reduce ignition delay, enhancing overall combustion efficiency.^[23] In modern common-rail diesel engines, such improvements contribute to better thermal efficiency, as evidenced by decreased brake specific fuel consumption in heavy-duty applications. The cetane index serves as a complementary indicator to the measured cetane number, providing insights into fuel ignition quality without direct engine testing. From an environmental perspective, elevated cetane index values promote better combustion completeness, leading to reductions in particulate matter (PM) emissions by about 1.8% and hydrocarbons (HC) by 17.4% for every 5-point increase, particularly in light-duty diesel cycles.^[24] Under optimized engine conditions, such as moderate loads with exhaust gas recirculation, it can also lower NOx emissions by mitigating peak combustion temperatures, though effects vary by engine technology and fuel formulation.^[24] However, the cetane index has limitations in high-performance engines, especially when using biodiesel blends or ultra-low sulfur diesel (ULSD), where its calculated value may not accurately reflect actual ignition behavior due to differences in fuel composition and oxidation stability.^[25] In these cases, direct cetane number testing via engine methods is recommended for precise performance prediction.^[25] Empirical studies demonstrate that cetane index values exceeding 50 correlate with smoother engine idling and reduced wear on fuel injectors, attributed to less aggressive combustion events and improved fuel atomization.^[16]^[26] This threshold supports more reliable operation in extended-duty cycles, minimizing mechanical stress on injection systems.

Cetane Improvers

Types and Mechanisms

Cetane improvers primarily consist of alkyl nitrates, with 2-ethylhexyl nitrate (2-EHN) being the most widely used due to its cost-effectiveness and broad efficacy across various diesel fuel types.^[27] These additives are typically incorporated at concentrations ranging from 0.05% to 0.5% by volume to achieve desired ignition enhancements.^[28] The mechanism of action for alkyl nitrates involves thermal decomposition during the pre-ignition phase of the combustion process, where they break down exothermically to release free radicals such as alkoxy and hydroxyl species.^[29] These radicals initiate and accelerate chain-branching reactions in the fuel-air mixture, thereby shortening the ignition delay time and promoting faster autoignition without significantly modifying the base fuel's physical or chemical properties.^[28] Other cetane improvers include peroxide-based compounds, such as di-tert-butyl peroxide (DTBP), which operate through similar radical-generating decomposition but are employed in specialized applications where nitrate sensitivity is a concern.^[27] Hydroperoxides and research-oriented non-peroxide alternatives, like certain alkyl hydroperoxides, have also been explored for niche uses, offering potential advantages in stability or compatibility with specific fuel blends.^[30] In terms of dosage response, alkyl nitrates generally provide a cetane number increase of 2 to 5 points per 0.1% additive concentration in typical diesel fuels, though this response varies with base fuel composition and diminishes at higher dosages due to excessive decomposition and radical recombination.^[28] This plateau effect limits the practical upper range of additive use to avoid diminishing returns. Handling alkyl nitrate cetane improvers requires stringent safety protocols owing to their volatility, reactivity, and potential for exothermic runaway reactions under improper storage conditions, such as exposure to heat or contaminants.^[31] Additionally, nitrate-based additives raise environmental concerns related to their persistence and potential contribution to nitrogen oxide emissions if not fully decomposed during combustion.^[32]

Impact on Measurements

The cetane index (CI) is determined through calculations based on a fuel's density and distillation profile (such as the 10%, 50%, and 90% recovery temperatures from ASTM D86), physical properties that remain unchanged by the addition of chemical cetane improvers.^[6]^[33] As a result, the CI exhibits insensitivity to these additives, providing a consistent estimate of ignition quality for untreated base fuels but underestimating the enhanced performance in additized products where the actual ignition delay is shortened.^[34] This discrepancy arises because CI methods, such as ASTM D4737, rely solely on empirical correlations with hydrocarbon composition inferred from physical measurements, ignoring the catalytic effects of improvers like alkyl nitrates on combustion initiation.^[6] In contrast, the cetane number (CN) is measured via engine-based testing under ASTM D613, which evaluates the fuel's ignition delay in a cooperative fuel research engine using the as-received sample, thereby incorporating the full impact of any additives present. Cetane improvers typically raise the CN by 5 to 10 points at standard dosages (e.g., 1000-2500 ppm), directly improving autoignition without altering the underlying physical parameters that define the CI.^[27] Fuel specifications address this measurement gap by often mandating both CI for base fuel assessment and a minimum CN for final additized products to ensure reliable ignition quality. For example, the European EN 590 standard requires a minimum CN of 51 and CI of 46, with the CI serving as a reliable proxy for untreated diesel only when the CN meets or exceeds 51, reflecting the additive-free baseline.^[21] Testing protocols reinforce this: ASTM D613 captures additive contributions to CN, while CI calculations under ASTM D4737 or D976 exclude them, necessitating independent CN verification for commercial fuels to confirm compliance post-additization. In refinery operations, cetane improvers are commonly employed to bridge the difference between a base fuel's calculated CI and the target CN, enabling cost-effective production of specification-grade diesel. A representative case involves a hydrotreated straight-run distillate with a CI of 41, which, after additization at the terminal, achieves a CN of 51, effectively closing a 10-point gap to meet standards like EN 590 without extensive reforming. Such practices highlight the complementary roles of CI and CN in quality control, where additization compensates for inherent feedstock limitations while maintaining traceability through physical property-based calculations.^[34]

References

[1]
Standard Test Method for Calculated Cetane Index of Distillate Fuels
Feb 23, 2023 · This test method covers the Calculated Cetane Index formula, which represents a means for directly estimating the ASTM cetane number of distillate fuels.
[2]
Cetane Testing - Intertek
Cetane testing labs determine diesel fuel cetane numbers and other regulatory protocols. The cetane number, cetane index, and derived cetane number (IQT) ...
[3]
ASTM D976 - eralytics
The cetane index provides an estimation of the combustion quality of diesel fuels based on their physical properties, without requiring engine testing.
[4]
40 CFR Part 1090 -- Regulation of Fuels, Fuel Additives, and ... - eCFR
(1) Minimum cetane index of 40. (2) Maximum aromatic content of 35 volume percent. § 1090.310 Diesel fuel additives standards. (a) Except as specified in ...Subpart D —Diesel Fuel and... · Subpart C —Gasoline Standards · Subpart H
[5]
D975 Standard Specification for Diesel Fuel - ASTM
Oct 14, 2022 · ASTM D975 covers seven diesel fuel grades for various engines, with tests for flash point, cloud point, water, sediment, and more.
[6]
D4737 Standard Test Method for Calculated Cetane Index by Four ...
Nov 18, 2021 · The calculated Cetane Index by Four Variable Equation provides a means for estimating the ASTM cetane number (Test Method D613) of distillate fuels.
[7]
Fuel Property Testing: Ignition Quality - DieselNet
Cetane number is the most important and universally accepted ignition quality test. The cetane number test uses a standard single cylinder variable compression ...
[8]
[PDF] Diesel Fuels Technical Review - Chevron
This test method for diesel fuel was developed in the 1930s by the ... A calculated cetane index estimates the “natural” cetane number of the fuel.
[9]
[PDF] Literature Review of Cetane Number and Its Correlations. - DTIC
Consequently, cetane indices based on compositional analysis may be better predictors of cetane number than those based on physical properties.
[10]
Cetane Index Calculator – what it all means? - Learn Oil Analysis
Jul 26, 2022 · Cetane Index is a number used to denote the quality of diesel fuel. Its petrol/gasoline equivalent is an octane rating.
[11]
Cetane index – Knowledge and References - Taylor & Francis
Cetane index is a measure of the quality of ignition for diesel fuel, which is determined experimentally and takes into account factors such as fuel volatility.
[12]
Indicated Cetane Number vs Cetane Index - Stanhope-Seta
Sep 15, 2025 · Unlike Cetane Index, Indicated Cetane Number provides a direct, empirical measurement of ignition quality. It captures the effect of cetane ...
[13]
D613 Standard Test Method for Cetane Number of Diesel Fuel Oil
Significance and Use 5.1 The cetane number provides a measure of the ignition characteristics of diesel fuel oil in compression ignition engines.Missing: index | Show results with:index
[14]
Standard Test Method for Cetane Number of Diesel Fuel Oil - ASTM
Aug 16, 2017 · 1.2 The cetane number scale covers the range from zero (0) to 100 but typical testing is in the range of 30 to 65 cetane number. 1.3 The values ...
[15]
[PDF] 6zzml~8w@ - Concawe
For the purposes of this study a 1:l correlation between cetane number and cetane index has been assumed. Fig. 211, which plots the relationship between.
[16]
Cetane number, derived cetane number, and cetane index
Cetane index (CI), which is an empirical correlation based on density and distillation curve temperatures, is allowed in place of CN and DCN in some fuel ...
[17]
Astm d4737 - pdfcoffee.com
Astm d4737. Astm d4737. Categories; Accuracy ... Calculation or Interpretation of Results 6.1 Compute the Calculated Cetane Index by Four Variable Equation ...
[18]
[PDF] Evaluation of Cetane Indices for Marine Fuels. - DTIC
Of the trial correlations, the most promising was the modified ASTM D976-80 cetane index. ... parameter refers to the error in estimating the cetane number ...Missing: overestimates | Show results with:overestimates
[19]
Determination of flash point and cetane index in diesel using ...
(1) CCI = 45.2 ... Standard test method for calculated cetane index by four variable equation.
[20]
California Diesel Fuel - DieselNet
Sulfur is limited to a maximum of 15 ppm while the limit on aromatics requires either a minimum cetane index of 40 or a maximum aromatic content of 35% volume.
[21]
EU: Automotive Diesel Fuel - DieselNet
EN 590:1993—The first EU diesel fuel specification. It established a sulfur limit of 0.2% and a cetane number of 49 in onroad and nonroad diesel fuels.
[22]
ISO 4264:2018 - Petroleum products — Calculation of cetane index ...
In stock 2–5 day deliveryThis document specifies a procedure for the calculation of the cetane index of middle-distillate fuels from petroleum-derived sources.
[23]
[PDF] Effect of Fuel Cetane Numbers on Reducing the Ignition Delay ...
Jun 16, 2020 · The ignition delay period is reduced by increasing the cetane number and this allows the stable running of the engine [10, 11].
[24]
[PDF] Strategies and Issues in Correlating Diesel Fuel Properties with ...
Jul 20, 2016 · Cetane index - If the cetane number of a fuel was not measured, the ... Jass,. “Diesel Fuel Property Effects on Exhaust Emissions from a Heavy ...
[25]
Limitations of the use of cetane index for alternative compression ...
Lower cetane numbers result in poor combustion characteristics and lead to excessive emissions of smoke and particulates. Improving the cetane number in diesel ...
[26]
Petroleum Laboratory | Division of Oil and Public Safety logo
A higher cetane index indicates quicker combustion in the engine and a quieter, more smoothly running engine. A high cetane index also reduces harmful emissions ...Gasoline And Ethanol Fuel... · Fuel Oxygenates Via Gas... · Octane Number Or Antiknock...Missing: smoother | Show results with:smoother
[27]
Diesel Fuel Additives - DieselNet
2-Ethyl hexyl nitrate (2EHN or iso-octyl nitrate) has become the most common ignition improver due to its low production costs and good response in a wide range ...
[28]
[PDF] Petroleum and Chemical Industry International
Chemical cetane improvers are those compounds that readily decompose to form free radicals, which in-turn promotes the rate of initiation. This increased rate ...
[29]
[PDF] Effect of CETANE Improver Additives on Emissions
Alkyl nitrates. (2-ethyl hexyl nitrate) and di –tert-butyl peroxide are used as additives to raise the cetane number. CETANE ADDITIVE: Generally, cetane ...<|control11|><|separator|>
[30]
Experimental and modeling study of fuel interactions with an alkyl ...
This study investigates the autoignition behavior of two gasoline surrogates doped with an alkyl nitrate cetane enhancer, 2-ethyl-hexyl nitrate (2EHN)
[31]
[PDF] FUELS - 2-Ethylhexyl Nitrate (2EHN) - Afton Chemical
For this reason, Cetane improver requires special care in handling due to health effects and the thermodynamic properties of the material.
[32]
[PDF] 2-Ethylhexyl nitrate (2-EHN) - ATC Additive Technical Committee
Dec 17, 2021 · handling safety measures but minor incidents related to ... 2-ethylhexyl nitrate as a cetane improver: classification and safety ...
[33]
ASTM D4737 (Cetane Index Analysis) - SPL
Apr 10, 2024 · The cetane number requirements depend on engine design, size, nature of speed and load variations, and on starting and atmospheric conditions.
[34]
[PDF] Comparing Methods to Determine Cetane Ratings of Fuel Blends
Dec 9, 2009 · What are the Traditional. Laboratory Methods? • Two-variable method. ― ASTM D976. ― Uses the API Gravity of the fuel along with the mid-boiling ...
[35]
Effect of Cetane Number Increase Due to Additives on NOx ...
For instance, if cetane improvers are added to a national average base fuel so that the total cetane number is increased by 5 numbers, the percent reduction in ...