By
Bryan Boyne (g.g.)
Cut quality is the only diamond value factor that is the result of human input. This vital factor may be the most difficult to understand because it is the most technical, but gaining a basic understanding of diamond cut is important to making a wise buying decision. Cut refers to the proportioning, alignment and finish of a diamond's polished faces or facets. Proper cutting enables a diamond to perform at its best and release its full potential for fire and brilliance. A well cut diamond will be more beautiful and more valuable than a diamond whose cut quality has been compromised for carat weight.
*Note: The word "cut" is also used in reference to a diamond's shape - round brilliant cut, marquise cut, princess cut, etc. It is less confusing to restrict the term "cut" to a discussion of the proportions, facet alignment and finish of a polished diamond.
A diamond cutter must spend more time and sacrifice more of the rough crystal in order to produce a well cut finished stone, thereby ending up with a smaller diamond than had he taken liberties with cut quality. Well cut diamonds therefore yield less carat weight from the rough and are consequently more expensive to produce.
The importance of diamond cut cannot be over emphasized. The consensus view of virtually every diamond expert can be summed up in the words on the website of the GIA (Gemological Institute of America). The allure of a particular diamond depends more on cut than anything else.
The following illustrations show the various parts of a diamond and measurements used in the analysis of a diamonds cut:
Image courtesy of AGS Laboratories
Below is a depiction of the basic behavior of light entering a diamond. A well cut diamond will refract and reflect a high percentage of light back to the eye, whereas a poorly cut diamond will allow light to leak out the bottom resulting in diminished brilliance and fire.
The AGS Laboratories perform the most comprehensive and critical cut quality analysis of any lab in the world. It is therefore instructive to understand the range of factors taken into account by this rigorous and scientifically vetted cut grading system. There are eleven individual factors evaluated:
Light Performance Factors
Proportions Factors
Finish Factors
The AGSL Light Performance grading system evaluates every facet of the diamond, both major and minor, in arriving at a cut grade for each aspect. For a detailed explanation please see our article entitled AGS Cut Grading . The article is part of a comprehensive series written in collaboration with the American Gem Society Laboratories that also includes light performance based cut grading of Princess diamonds
The three aspects of diamond beauty are generally referred to as fire, brilliance and scintillation (sparkle). They are distinct but inter-related characteristics. For a diamond to express its full potential and to be as beautiful as possible, it must be crafted such that these characteristics are optimized in a balanced way.
Fire refers to the ability of a faceted diamond to act as a prism and to break white light into the individual colors of the visible spectrum. Under lighting conditions conducive to the observation of fire, a well cut diamond will exhibit sparks of red, green, yellow, and blue in the process of the light interacting with each of the diamonds facets and being returned to the eye.
Diamond Fire and Scintillation
Brilliance is generally thought of as the total amount of light returned to the eye resulting in the overall brightness of the stone.
Scintillation is the sparkle of the diamond created by the dynamic on-off pattern of blinking facets in response to movement. In order to have maximum sparkle the cut of a diamond has to be designed and executed to create a balance of brightness and positive contrast.The quality of a diamond's cut is a complicated interaction of proportions, facet angles, and finishing factors. Many combinations can result in beautiful finished stones. Because the above mentioned performance elements are distinct and interrelated, it is possible for the cutter to make tradeoffs in the design process. For instance, making the table facet a little larger may make the stone slightly more brilliant and slightly less fiery. So, even amongst the best diamond cuts there is still room for differences in personal preference and taste.
Diamonds of top cut quality are often referred to as Ideal Diamonds. Of the two most well respected laboratories only AGSL (American Gem Society Laboratories) actually certifies diamonds as Ideal. Their scientifically rigorous light performance based system analyzes eleven different aspects of cut quality and involves analysis of a 3D model of every facet of the diamond. This system enables AGSL to scientifically analyze and grade cut quality on round as well as princess diamonds, and several other shapes including oval, Asscher, emerald cut and cushion. Diamonds that earn the AGS Ideal grade are the best of the best in terms of cut quality.
The GIA cut grading system is broader and more forgiving and involves comparing a limited set of measurements to predetermined tables. Excellent is the highest grade in this system, and overall diamond cut grading is limited to round diamonds. (The cut related aspects of polish and symmetry are reported on all diamonds, but only rounds receive an overall cut grade at GIA). Because of the stature of GIA worldwide, there is a tendency for consumers to equate GIA Excellent with Ideal, despite the fact that a great number of GIA Excellent cut grades will fall well outside of the AGS Ideal category. Having said that, a diamond with a cut grade of Excellent from GIA will be very pretty (provided there are no clarity features that diminish light performance). For more information about differences in cut grades between the two labs please see the articles about AGS vs GIA grading and AGS0 vs GIA EX
IDEAL CUT DIAMONDS
Compare
1.150 G VS1 Round Ideal
A CUT ABOVE®
$9,450
Light Perf. Polish Symmetry Depth % Table % Crown Angle Star Pavilion Angle Crown % Lower Girdle Measurements Fluorescence Eye Clean View Details
Compare
1.158 F VS1 Round Ideal
A CUT ABOVE®
$9,950
Light Perf. Polish Symmetry Depth % Table % Crown Angle Star Pavilion Angle Crown % Lower Girdle Measurements Fluorescence Eye Clean View Details
Compare
1.120 F VS1 Round Ideal
A CUT ABOVE®
$9,660
Light Perf. Polish Symmetry Depth % Table % Crown Angle Star Pavilion Angle Crown % Lower Girdle Measurements Fluorescence Eye Clean View Details
Compare
1.122 F VS1 Round Ideal
A CUT ABOVE®
$9,660
Light Perf. Polish Symmetry Depth % Table % Crown Angle Star Pavilion Angle Crown % Lower Girdle Measurements Fluorescence Eye Clean View Details
LOAD MORE
The concept of an "ideal" cut gained widespread notoriety in when mathematician Marcel Tolkowsky from Belgium published a study of the behavior of light in a cut diamond and came up with a formula for proportions that would result in the most beautiful round diamond. Prior to this time, American diamond cutters had also arrived at similar conclusions about proportions that resulted in the best optics. Modern science has tended to validate work of these pioneers who were going against the grain of a diamond industry that favored highest yield over best light performance.
The beauty of selecting an AGS Ideal diamond is that the guesswork and the need for calculating all the inter-related measurements and angles has been done for you. This allows you to focus attention on the other things that matter: color, clarity and size.
In addition to the various tests performed at the laboratories in order to render a quality report, there are a variety of diagnostic tools available for assessing diamond craftsmanship and light performance that are available to the trade and to the consumer market. Reflector tools such as ASET and Ideal-Scope reveal details about how a diamond is handling light. Hearts and Arrows viewers give a visual picture of a diamonds optical precision. Other online tools such as Holloway Cut Advisor (HCA) provide quick filters for spotting diamonds with poor proportions. Highly accurate non-contact measuring devices such as Sarine DiaScan provide detailed data and reports and generate 3D models of a diamond that can be used in sophisticated ray tracing programs such as Octonus DiamCalc
Hearts and Arrows Viewer
Diamond shapes other than round are referred to as fancy shapes. Almost any shape is possible and there are new designs coming into the market as new diamond cutting technologies and techniques are developed. Determining a cut grade for fancy shapes is far more complicated than for rounds, and as a result only the AGS light performance system is capable of accounting for the complexity. Even with this adaptive scientific system, not all shapes have yet been fully worked out.
One of the most important aspects in fancies is the overall outline of the shape, deriving primarily from its length to width ratio. The outline will affect the eye appeal of the diamond as well as the overall design of a finished piece of jewelry. To some extent this is a subjective factor allowing for different tastes. For instance, some people might prefer a long slender marquise for a design that accentuates a long slender finger. Likewise, a pendant design might favor an elongated pear shape over one with broad shoulders.
Whiteflash specializes in ideal cut round and princess diamonds, and normally does not stock other fancy shapes. However, our expertise in diamond light performance and our access to the global diamond network enables us to source top quality diamonds through our Virtual Diamond Service . Our GIA trained diamond consultants are highly experienced at guiding customers through a search for the diamond that is just right for their preferences and budget.
Below are guidelines that we use in our search for high performing fancy cut diamonds. Falling within these guidelines is not a guarantee that a diamond will be a top performer, but they serve as a good starting point for searching through databases of available inventory. Because performance of fancy cuts is much harder to predict from specifications alone, for the customer looking for a top performing fancy it is essential to have the diamond professionally inspected and to see light performance imagery before making a final decision.
Shape
Depth
Table
Girdle
Length to Width Ratio
Emerald
60-65%
56-64%
Thin-Thick
1.3-1.75
Oval
59-63%
57-62%
Thin-Med/Med/Thick
1.33-1.66
Radiant
65-69%
56-63%
Thin-Thick
1.00-1.50
Marquise
59-63%
57-62%
Thin-Med/Med/Thick
1.80-2.10
Pear
59-63%
57-62%
Thin-Med/Med/Thick
1.30-1.55
Heart
59-63%
57-62%
Thin-Med/Med/Thick
0.95-1.05
Princess
73-75%
57-68%
If you want to learn more, please visit our website Litian Century.
Thin-Med/Med/Thick
1.00-1.05
Asscher
67-70%
57-65%
Thin-Med/Med/Thick
1.00-1.05
Cushion
59-66%
53-63%
Thin-Med/Med/Thick
Personal Preference
Diamond cut is the number one factor determining a diamonds beauty. Choosing an AGS Ideal is recommended for those looking for the best of the best in terms of light performance. Choosing a GIA Excellent cut will assure you of very nice performance and in some cases performance at the top of the scale. In order to determine actual light performance on GIA diamonds, extra testing is required.
There are two approaches used to analyze diamond cut quality. Traditional proportion assessment utilizes a 2 dimensional approach that takes the outer measurements of a diamond and predicts how it will handle light. Modern performance assessment measures the actual light behavior of the diamond and compares it to established standards.
In this article we will discuss both, but focus on the latter as it is the way of the future.
The Gemological Institute of America (GIA) uses a proportion based system which provides an overall cut grade for round diamonds only. The GIA system consists of 5 grades: Excellent, Very Good, Good, Fair and Poor. The system takes into account seven factors: brightness, fire and scintillation (appearance based aspects) and weight ratio, durability, polish and symmetry (craftsmanship aspects). The cut grade is rendered by comparing measurements to predefined grading tables based upon GIAs extensive research.
The American Gem Society Laboratories (AGSL) grades the cut of round diamonds and some fancy shapes based on light performance with scores from 0 (Ideal) to 10. This system takes into account eleven factors: brightness, dispersion, leakage and contrast (Light performance aspects) and girdle thickness, culet, weight ratio, durability, and tilt (proportion factors) and polish and symmetry (finish aspects). Light performance is calculated mathematically by ray tracing a 3 dimensional model of the diamond and taking into account the contribution of every facet.
You might say that proportions assessment looks at the container and performance assessment looks at the contents. Because the AGS cut grading system is much more sophisticated and less forgiving, consumers looking for the finest cut craftsmanship prefer AGS reports when available.
A diamond has facets that allow light to enter, become refracted and exit in a rainbow of colors. When combined the light appears as white sparkles and when dispersed into its component colors appears as colored sparkles. Certain angles and measurements are proven to optimize these effects. The facet arrangement of the standard round brilliant diamond permits reliable proportion-based analysis by knowing a few key proportions. However, since these measurements are the result of averaging and rounding, deviations in a diamonds faceting precision are not revealed by this method of analysis.
Fancy shape diamonds are more complex and cannot be as accurately predicted using proportions alone.
Before proceeding it is important to know the locations of various facets on a round brilliant diamond and become familiar with the role proportions play in light performance:
Round Brilliant Diamond Facet Map
Light performance based cut grading such as computerized ray tracing of a 3D scan of the diamond as done by AGSL, takes into account the contribution of every facet to overall performance. Proportion based systems look at a limited number of averaged and rounded measurements.
In a mathematician and diamond cutter named Marcel Tolkowsky published a book called Diamond Design wherein he mathematically calculated a set of proportions for the Ideal round brilliant.
Tolkowskys observations of diamonds cut to these proportions, as well as the observations of others in the trade, served to validate his calculations and his work was widely embraced. His measurements became a standard by which the best cut diamonds were judged, and ultimately formed the basis for the first laboratory cut grading system AGS Laboratories in . As laboratories develop new systems we know that other beautiful configurations are possible, but Tolkowskys work has been largely validated by modern science.
It is important to note that although Tolkowsky is considered the father of the ideal cut, several visionary American diamond cutters were advocating very nearly the same proportions decades earlier. The story of these remarkable pioneers is wonderfully chronicled in Al Gibertsons book American Cut The First 100 Years
Basic proportions assessment is done by comparing a diamonds measurements to proven ranges on charts. Over time charts have been developed to predict the potential of a diamond based on its proportions. In the American Gem Society Laboratories (AGSL), became the first lab to perform cut quality analysis on the round brilliant diamond, with grading based on proportions near Tolkowskys. Since that time the AGS has evolved to a performance assessment system (), with cut grading extended to certain fancy shapes as well. AGS proportion charts are still used as a reference for round brilliants where limited information is available.
Round diamonds with overall measurements in this range are considered to have traditional ideal proportions. As mentioned above, in AGS transitioned to ray tracing performance assessment, and diamonds at the outer limits of this traditional range may no longer receive their top grade. Faceting precision (3D facet alignment) will also impact the final grade.
Stricter than traditional AGS proportions, below are the Whiteflash proportion guidelines for A CUT ABOVE® Hearts & Arrows diamonds. Round brilliant diamonds cut with precision in this range of measurements receive the highest ratings in both proportions and performance grading systems.
A CUT ABOVE® diamonds must AGSL light performance grade of Ideal, exhibit perfect hearts and arrows patterning and pass multiple additional tests and evaluations by the Whiteflash review team. For a full understanding of these elite diamonds, please see our specifications and qualifications page.*A CUT ABOVE® super ideal diamonds in both round and princess cut are available only through Whiteflash and are always in-stock with a comprehensive set of data and imagery posted to the website.
Another type of proportions assessment involves plugging measurements into a cut estimator for a computer assisted prediction of performance.
In the s an Australian geologist named Garry Holloway introduced the HCA tool, a free online cut analyzer that gained significant popularity and is still in use today. Analyzing 5 basic measurements, it is possible to get an indication of predicted performance. It outputs a numerical result (2 or less is considered the top range), along with a text based descriptions of brightness, fire and spread.
As a two dimensional tool capable of assessing only a limited number of facets, the HCA is of no value when 3 dimensional analyses such as an AGS light performance report, or when light performance imagery such as ASET or Ideal-Scope is available. But it can be used effectively as s filter to eliminate problematic proportion combinations from a pool of diamonds such as virtual inventories found online.
In GIA introduced their cut grading system together with a similar free online cut estimator. The Facetware tool assesses additional information about the diamond, but is still essentially a proportion based system. The input data is compared to pre-defined grade tables to render an estimate of the cut grade it would likely receive at the GIA lab.
Where proportions assessment is a prediction based on measurements, performance assessment looks at the actual light behavior of a diamond. Diamond performance has traditionally been described in terms of brilliance, fire and scintillation.
Brilliance or Brightness essentially refers to quantity of light returning from the diamond. Fire (technically known as dispersion), is the degree to which the white light is broken out or dispersed into spectral colors. Scintillation is sparkle - a dynamic effect associated with movement requiring positive contrast for an on/off blinking effect.
In recent years other descriptors have been added to enhance our understanding of diamonds visual properties: Contrast and Pattern describe the arrangement of light and dark areas resulting from reflections. Leakage describes areas that do not reflect light back to the viewer. Methods of performance assessment measure the overall quantity and quality of light output of a diamond and compare it to established standards.
The symmetrical facet arrangement of the round brilliant diamond permits meaningful analysis by knowing some basic proportions, but fancy shapes are more complex and cannot be decisively predicted in this manner. Light performance analysis is valuable for all diamonds but particularly useful for fancy shapes. Since GIA only provides an overall cut grade on rounds, it is particularly important to have additional diagnostics to fully understand the cut quality of fancies.
The most sophisticated and stringent cut grading system in use today is scientifically vetted the light performance system in use at AGSL. Each diamond is scanned and individually modeled and 40,000 virtual light rays are traced at a variety of tilt angles to measure performance aspects of brightness, dispersion (fire), contrast and light leakage.
AGS Light Performance Grading Hemisphere
For an overview of the science and process please see our article on AGSL Cut Grading . In addition to round diamonds AGSL also performs cut grading on fancy shapes. For a detailed look at grading of the most popular fancy shape please see Princess Cut Grading at AGSL.
Sophisticated fee-based tools are used by some diamond cutters, researchers, and gemologists using a digital scan of the diamond (such as a Sarine file) to analyze a 3D model that can be manipulated with specialized software. One such program is DiamCalc by OctoNus. With the help of virtual performance simulations this software enables broad design conclusions to be drawn about various proportion sets.
When evaluating a specific diamond, actual reflector images and comprehensive analysis of the live diamond are preferable to assessment by simulation. However, a great deal can be learned using this advanced tool.
In the s a Japanese scientist named Okuda developed methods to study light performance using colored reflectors in magnified scopes. By color-coding light entering the crown of the diamond he was able to track the amount of light returned properly to the viewer's eye. Over the next 30 years other innovators developed such tools as the FireScope(TM) and the Gilbertson-Scope which were used to improve diamond cutting techniques.
Reflector assessment was popularized at the turn of the century with Garry Holloways ideal-scope , a simple magnifying tube containing a red reflector. An ideal-scope photograph shows which areas of a diamond return light to the viewers eye and which areas allow light to leak out. An Ideal Scope image is a handy visual tool for judging diamond light performance.
In the AGS introduced a similar tool, the Angular Spectrum Evaluation Tool or ASET (pronounced asset). Based on a similar principal, the ASET shows light return with greater detail as light is color-coded 3 ways. Blue (obscuration contrast), red (high angle, high intensity light return), green (lower angle, lower intensity light return). An ASET image therefore provides more specific information than Ideal-Scope about how the diamond is handling light.
Patterning resulting from different levels of faceting design and precision can impact light performance and diamond beauty in significant ways. Well-proportioned diamonds cut to a very high level of 3 dimensional symmetry (also referred to as optical symmetry or optical precision), exhibit a unique pattern of hearts (face down - pavilion view) and arrows (face up - table view). This Hearts and Arrows pattern (H&A) is visible under a special reflector device.
An accurate hearts and arrows pattern indicates that corresponding facets are lined up precisely in three dimensions such that their light handling capabilities are optimized. Diamonds with H&A pattern can still have light performance deficits that can be detected by ASET and Ideal Scope. The combination of ideal proportions with optical precision maximizes the benefits of hearts and arrows patterning.
A number of other devices have been developed to attempt to measure and analyze a diamonds light output. ImaGem and BrillianceScope are among the most well-known. These machines provide interesting demonstrations and information that may be useful, but each gives different results. Some of these technologies have been adopted by chain jewelry stores for use in diamond presentations.
We have tested a number of automated/computerized light output measurement devices but have found none that give relevant and repeatable results. We realize the value of the concept to consumers and may adopt such a machine in the future if it can be proven to be repeatable and provide results consistent with scientifically vetted grading systems such as AGSL.
IN STOCK DIAMONDS
Compare
1.150 G VS1 Round Ideal
A CUT ABOVE®
$9,450
Light Perf. Polish Symmetry Depth % Table % Crown Angle Star Pavilion Angle Crown % Lower Girdle Measurements Fluorescence Eye Clean View Details
Compare
1.158 F VS1 Round Ideal
A CUT ABOVE®
$9,950
Light Perf. Polish Symmetry Depth % Table % Crown Angle Star Pavilion Angle Crown % Lower Girdle Measurements Fluorescence Eye Clean View Details
Compare
1.120 F VS1 Round Ideal
A CUT ABOVE®
$9,660
Light Perf. Polish Symmetry Depth % Table % Crown Angle Star Pavilion Angle Crown % Lower Girdle Measurements Fluorescence Eye Clean View Details
Compare
1.122 F VS1 Round Ideal
A CUT ABOVE®
$9,660
Light Perf. Polish Symmetry Depth % Table % Crown Angle Star Pavilion Angle Crown % Lower Girdle Measurements Fluorescence Eye Clean View Details
LOAD MORE
Mathematical estimators, reflector images, and even sophisticated ray tracing technologies each have their place and can be very useful. But diamonds are dynamic and the perception of beauty is complex, and ultimately subjective. We dont all respond the same way to the same visual stimuli. Ultimately the human eye is the best tool of all.
For someone not experienced in looking at diamonds, consulting a trained independent professional is a very good idea. Certain diamond characteristics are very subtle and hard for the untrained eye to appreciate. But subtle aspects can impact performance in meaningful ways, so expert advice is the best way to make sure you are getting everything you bargained for in your diamond purchase.
If youre shopping on the internet, finding diamonds with traditional ideal proportions is a fast way to locate good candidates. Online cut estimators can serves as preliminary filters. Then you can use reflector images and other performance data to see which has the best light return and patterning. Diamonds that have been ray traced, such as AGSL certified stones, provide an even higher level of understanding. But human observation is always the final arbiter of beauty and overall value in a purchase. The best of all worlds is to have all the diagnostics for a full technical understanding and documentation of the diamond, and visual confirmation of its beauty.
The amount of information available about a given diamond varies dramatically in the market. Some merchants offer very limited analysis while others specialize in providing complete evaluations including images , videos, and light performance lab reports.
A very positive by-product of internet e-commerce is that consumers are becoming better educated about diamond quality and how to assess it for themselves. When shopping in retail stores you should seek the same data, imagery, and documentation that you would expect on the internet.
The RPMs of the machine spindle should be noted when selecting the right blade specification of your application. So that the blade will be tensioned to run at the operating speed. This will insure a true running blade. Adherence to recommended speed is very important. Improper blade speeds can be rectified in many cases with a pulley change or change in blade diameter. Blade specification can be modified to some degree is speed is not correct, however deviation from recommended SFM should be amended for maximum performance. Make sure the cutting machine you are using is designed or can be adapter to be used for your application. Many machines are designed for other diamond blade applications and may not be ideal for you to use.
Ultra Thin & High Precison Diamond Blades can be used either at low or high speeds. There are advantages and disadvantages of each process. Diamond may break (fracture) at very high speeds, and fall out at very slow speeds. An optimum surface speed / RPM's must be selected to balance out the two disadvantages. Diamond Blade life will usually increase at slower cutting speeds. However the increase in labor costs, utilities costs, depreciation of equipment and other overhead expenses. Will usually offset the saving of diamond blade life and other consumables. Cutting Speed & Surface Finish Quality is often the most important consideration when selecting the right diamond blade for your application. The operator mush choose a balance between life of the blades and their cutting rate. Diamond has a higher impact strength than the material being machined. During the sawing operation, the diamond ruptures the material by impact. Each diamond is able to transfer the electrical power from your cutting machine, into momentum that breaks the material on nano / micro level.
By increasing power on your saw, your diamond blade RPM's and surface speed will increase as well. Hence, each diamond will chip off a smaller amount of material, reducing its impact force on material being machined. And reducing cutting resistance. In theory, by increasing surface speed / RPM's, each diamond should receive a smaller impact force. However, because impact is supported by a smaller volume, the impact force with this low volume is actually increased. There is a higher probability that the diamond particles will break or shatter. Hence, cutting materials at very low surface speeds, creates a large impact force between diamond and material being machined. Although the diamond may not break, the risk that the diamond will be pulled out of diamond blade and causing premature failure of the blade increases.
For more Diamond Cutting Toolsinformation, please contact us. We will provide professional answers.