While natural silicon carbide (moissanite) does exist, it is extremely rare and is not used in jewelry. The moissanite used in jewelry is entirely synthetic.
Its properties, such as brilliance and hardness, make it a common alternative to diamonds.
YAG (Yttrium Aluminum Garnet):
Originally developed for industrial and laser applications, YAG is sometimes used as a gemstone.
Although it is named a “garnet,” it is not related to the natural garnet family of minerals.
Strontium Titanate:
Developed in the mid-20th century as a diamond simulant.
It has a much higher dispersion than diamond, giving it a fiery brilliance, but it is too soft for practical jewelry use.
Synthetic Rutile:
While natural rutile exists, the synthetic version created in the lab has been used as a gemstone due to its high dispersion and brilliance.
The synthetic version is engineered for specific optical qualities.
Titanium Sapphire (Ti:Sapphire):
A synthetic material often used in lasers. While not commonly used in jewelry, it is a synthetic gemstone that does not naturally occur in this form.
These synthetic gemstones are often engineered for specific aesthetic, optical, or industrial purposes and are distinct from natural gemstones, either because they do not naturally occur in gem-quality form or because they are entirely man-made.
Synthetic Alexandrite (Czochralski or Flame Fusion):
Although natural alexandrite exists, synthetic versions often have unique compositions or colors that don’t occur naturally, created purely for novelty.
Boron Nitride Crystals:
Synthetic boron nitride can be engineered into gem-like forms. It’s extremely rare in nature and appears in fascinating, unusual forms in the lab.
Synthetic Opal (Novel Patterns):
Lab-grown opals can exhibit color patterns or transparency levels not seen in natural opals, such as extreme brightness or perfectly uniform “play-of-color.”
Synthetic Quartz Variants:
Quartz can be synthesized with inclusions or colorations (e.g., deep purple or unique patterns) that are unattainable in natural environments.
Colored Synthetic Diamonds:
Lab-created diamonds can be grown with colors that are extremely rare or impossible in nature, such as perfectly vibrant reds, blues, or even neon shades due to precise chemical doping.
Bismuth Crystals:
While not technically a gemstone, synthetic bismuth crystals are grown in labs and have rainbow-colored, step-like structures not naturally found in geological settings.
Synthetic Spinel:
While spinel exists naturally, synthetic spinel can be created in colors or with clarity not found in nature, such as vibrant neon hues.
Synthetic Perovskites:
Perovskites are naturally occurring but rare in gem-quality form. Synthetic versions, often used in solar panels, can be cut into unusual, sparkling gems.
Synthetic Corundum with Patterns:
Sapphire and ruby (corundum) can be synthesized with added colors or patterns, such as stars, gradients, or even mixed hues that are impossible naturally.
Gallium Nitride Crystals:
Used in electronics but can be fashioned into gemstones with unusual optical properties, entirely absent from nature.
Synthetic Fluorite Variants:
While fluorite exists in nature, synthetic fluorite can exhibit colors and patterns engineered for jewelry or purely aesthetic purposes.
Zirconium Carbide or Nitride:
These materials are synthetic and metallic, with a high refractive index and an unusual, futuristic appearance when polished.
Metal-Organic Framework (MOF) Crystals:
MOFs are a class of synthetic porous crystals with complex geometric structures and vibrant colors, making them unique and striking.
Hyper-Modified Glass or Vitreous Materials:
Glass-like gemstones doped with rare elements (such as europium or neodymium) can fluoresce or shift colors in ways impossible in natural stones.
Synthetic Garnets (Uncommon Types):
Garnets like gadolinium gallium garnet (GGG) or yttrium iron garnet (YIG) are synthesized for industrial purposes but can be cut into gemstones.
These stones are not just rare but impossible to find naturally, offering a unique and unconventional aesthetic perfect for someone looking to stand out.
Synthetic Alexandrite (Czochralski or Flame Fusion):
Although natural alexandrite exists, synthetic versions often have unique compositions or colors that don’t occur naturally, created purely for novelty.
Boron Nitride Crystals:
Synthetic boron nitride can be engineered into gem-like forms. It’s extremely rare in nature and appears in fascinating, unusual forms in the lab.
Synthetic Opal (Novel Patterns):
Lab-grown opals can exhibit color patterns or transparency levels not seen in natural opals, such as extreme brightness or perfectly uniform “play-of-color.”
Synthetic Quartz Variants:
Quartz can be synthesized with inclusions or colorations (e.g., deep purple or unique patterns) that are unattainable in natural environments.
Colored Synthetic Diamonds:
Lab-created diamonds can be grown with colors that are extremely rare or impossible in nature, such as perfectly vibrant reds, blues, or even neon shades due to precise chemical doping.
Bismuth Crystals:
While not technically a gemstone, synthetic bismuth crystals are grown in labs and have rainbow-colored, step-like structures not naturally found in geological settings.
Synthetic Spinel:
While spinel exists naturally, synthetic spinel can be created in colors or with clarity not found in nature, such as vibrant neon hues.
Synthetic Perovskites:
Perovskites are naturally occurring but rare in gem-quality form. Synthetic versions, often used in solar panels, can be cut into unusual, sparkling gems.
Synthetic Corundum with Patterns:
Sapphire and ruby (corundum) can be synthesized with added colors or patterns, such as stars, gradients, or even mixed hues that are impossible naturally.
Gallium Nitride Crystals:
Used in electronics but can be fashioned into gemstones with unusual optical properties, entirely absent from nature.
Synthetic Fluorite Variants:
While fluorite exists in nature, synthetic fluorite can exhibit colors and patterns engineered for jewelry or purely aesthetic purposes.
Zirconium Carbide or Nitride:
These materials are synthetic and metallic, with a high refractive index and an unusual, futuristic appearance when polished.
Metal-Organic Framework (MOF) Crystals:
MOFs are a class of synthetic porous crystals with complex geometric structures and vibrant colors, making them unique and striking.
Hyper-Modified Glass or Vitreous Materials:
Glass-like gemstones doped with rare elements (such as europium or neodymium) can fluoresce or shift colors in ways impossible in natural stones.
Synthetic Garnets (Uncommon Types):
Garnets like gadolinium gallium garnet (GGG) or yttrium iron garnet (YIG) are synthesized for industrial purposes but can be cut into gemstones.
These stones are not just rare but impossible to find naturally, offering a unique and unconventional aesthetic perfect for someone looking to stand out.
Although Moissanite isn’t mentioned twice, everything after “Synthetic Alexandrite” inclusively is mentioned twice. That means this was procedurally copy-pasted. Someone writing on their own would either CTRL+A then CTRL+C and make no mistakes, or not repeat themself at all.
Of course, we can also look at the half-formalized format that indicates something was copied from raw text and pasted into markdown, rather than formatted with markdown first.
Colon:
words words Colon:
words words Colon:
copy-paster spotted
Second, we cast doubt that a human wrote the source.
AI-isms vs. non AI-isms
Non-reused acronym definitions.
Garnets like… yttrium iron garnet (YIG)
This is probably taken straight from the Wikipedia’s site description for YIG. Usually humans don’t define an acronym only to never use it, unless they’re making a mistake, especially not for just making repeated structure. So either Wikipedia was in the training corpus or this was Googled.
5/23 sentences start with “While” (weak ai indicator)
no three-em dashes or obvious tricolons are overused (non ai-indicator)
no filler bullshit introduction or conclusion (non ai-indicator)
obvious repeated structure that you can feel (strong ai indicator)
“These stones are not just rare but impossible to find naturally, offering a unique and unconventional aesthetic perfect for someone looking to stand out.” (emphasis added)
Repetition of “unusual” and “rare” rather than more flavorful or useful adjectives (AI indicator)
We’re talking synthetic stuff. Would a human write about rarity?
Superficial, neutral-positive voice despite length and possible source. If this was pasted from a technical blog, I’d expect it to have more “I” and personal experiences, or more deep anecdotal flavor (AI indicator)
e.g. use of “fascinating” but doesn’t go deeper into any positivities
Third… let’s take a guess
So it was copy-pasted from somewhere, but I can’t imagine it being from a blog or website, and it isn’t directly from Wikipedia. It has some nonhuman mistakes, but is otherwise grammatical, neutral-positive, and repetitively structured. And it lacks that deeper flavor. So… it was an AI, but likely not openAI.
At least there aren’t any very “committal” facts, so the length but lack of depth suggests that everything’s maaaaaaybe true…
I thoroughly enjoyed your in-depth analysis and learned a few things. I think we need to understand how to spot if something was written by AI or not, and this is very helpful for that.
Moissanite is so pretty. I’m not much of a jewelry guy. And I’m not trans. But I’ve always wanted to wear lots of pretty sparkly things. I’m having a blast looking through all these fun possibilities. When I was in Atlanta a pedestrian walked by me wearing all white, and dripping in silver chains, he looked like a time traveler, I want to do that but with purple or green. Do you remember where you got your engagement ring stone?
That fucking site is going to cause so much unnecessary strife and difficultly. LLMs are trained on real speech; that site is going to get is wrong constantly. We all want there to be some magic bullet or to pretend that AI is so easily clockable, but the simple truth is that it simply isn’t and all shit like this does is end up making people who actually know how to use “advanced grammar” (said sarcastically) like semicolons and em dashes have to deal with a shit ton of harassment from idiotic chuds who can’t comprehend that a real person can be more eloquent than “me like good thing!”
Moissanite (Synthetic Silicon Carbide):
While natural silicon carbide (moissanite) does exist, it is extremely rare and is not used in jewelry. The moissanite used in jewelry is entirely synthetic. Its properties, such as brilliance and hardness, make it a common alternative to diamonds. YAG (Yttrium Aluminum Garnet):
Originally developed for industrial and laser applications, YAG is sometimes used as a gemstone. Although it is named a “garnet,” it is not related to the natural garnet family of minerals. Strontium Titanate:
Developed in the mid-20th century as a diamond simulant. It has a much higher dispersion than diamond, giving it a fiery brilliance, but it is too soft for practical jewelry use. Synthetic Rutile:
While natural rutile exists, the synthetic version created in the lab has been used as a gemstone due to its high dispersion and brilliance. The synthetic version is engineered for specific optical qualities. Titanium Sapphire (Ti:Sapphire):
A synthetic material often used in lasers. While not commonly used in jewelry, it is a synthetic gemstone that does not naturally occur in this form. These synthetic gemstones are often engineered for specific aesthetic, optical, or industrial purposes and are distinct from natural gemstones, either because they do not naturally occur in gem-quality form or because they are entirely man-made.
Synthetic Alexandrite (Czochralski or Flame Fusion):
Although natural alexandrite exists, synthetic versions often have unique compositions or colors that don’t occur naturally, created purely for novelty. Boron Nitride Crystals:
Synthetic boron nitride can be engineered into gem-like forms. It’s extremely rare in nature and appears in fascinating, unusual forms in the lab. Synthetic Opal (Novel Patterns):
Lab-grown opals can exhibit color patterns or transparency levels not seen in natural opals, such as extreme brightness or perfectly uniform “play-of-color.” Synthetic Quartz Variants:
Quartz can be synthesized with inclusions or colorations (e.g., deep purple or unique patterns) that are unattainable in natural environments. Colored Synthetic Diamonds:
Lab-created diamonds can be grown with colors that are extremely rare or impossible in nature, such as perfectly vibrant reds, blues, or even neon shades due to precise chemical doping. Bismuth Crystals:
While not technically a gemstone, synthetic bismuth crystals are grown in labs and have rainbow-colored, step-like structures not naturally found in geological settings. Synthetic Spinel:
While spinel exists naturally, synthetic spinel can be created in colors or with clarity not found in nature, such as vibrant neon hues. Synthetic Perovskites:
Perovskites are naturally occurring but rare in gem-quality form. Synthetic versions, often used in solar panels, can be cut into unusual, sparkling gems. Synthetic Corundum with Patterns:
Sapphire and ruby (corundum) can be synthesized with added colors or patterns, such as stars, gradients, or even mixed hues that are impossible naturally. Gallium Nitride Crystals:
Used in electronics but can be fashioned into gemstones with unusual optical properties, entirely absent from nature. Synthetic Fluorite Variants:
While fluorite exists in nature, synthetic fluorite can exhibit colors and patterns engineered for jewelry or purely aesthetic purposes. Zirconium Carbide or Nitride:
These materials are synthetic and metallic, with a high refractive index and an unusual, futuristic appearance when polished. Metal-Organic Framework (MOF) Crystals:
MOFs are a class of synthetic porous crystals with complex geometric structures and vibrant colors, making them unique and striking. Hyper-Modified Glass or Vitreous Materials:
Glass-like gemstones doped with rare elements (such as europium or neodymium) can fluoresce or shift colors in ways impossible in natural stones. Synthetic Garnets (Uncommon Types):
Garnets like gadolinium gallium garnet (GGG) or yttrium iron garnet (YIG) are synthesized for industrial purposes but can be cut into gemstones. These stones are not just rare but impossible to find naturally, offering a unique and unconventional aesthetic perfect for someone looking to stand out.
Synthetic Alexandrite (Czochralski or Flame Fusion):
Although natural alexandrite exists, synthetic versions often have unique compositions or colors that don’t occur naturally, created purely for novelty. Boron Nitride Crystals:
Synthetic boron nitride can be engineered into gem-like forms. It’s extremely rare in nature and appears in fascinating, unusual forms in the lab. Synthetic Opal (Novel Patterns):
Lab-grown opals can exhibit color patterns or transparency levels not seen in natural opals, such as extreme brightness or perfectly uniform “play-of-color.” Synthetic Quartz Variants:
Quartz can be synthesized with inclusions or colorations (e.g., deep purple or unique patterns) that are unattainable in natural environments. Colored Synthetic Diamonds:
Lab-created diamonds can be grown with colors that are extremely rare or impossible in nature, such as perfectly vibrant reds, blues, or even neon shades due to precise chemical doping. Bismuth Crystals:
While not technically a gemstone, synthetic bismuth crystals are grown in labs and have rainbow-colored, step-like structures not naturally found in geological settings. Synthetic Spinel:
While spinel exists naturally, synthetic spinel can be created in colors or with clarity not found in nature, such as vibrant neon hues. Synthetic Perovskites:
Perovskites are naturally occurring but rare in gem-quality form. Synthetic versions, often used in solar panels, can be cut into unusual, sparkling gems. Synthetic Corundum with Patterns:
Sapphire and ruby (corundum) can be synthesized with added colors or patterns, such as stars, gradients, or even mixed hues that are impossible naturally. Gallium Nitride Crystals:
Used in electronics but can be fashioned into gemstones with unusual optical properties, entirely absent from nature. Synthetic Fluorite Variants:
While fluorite exists in nature, synthetic fluorite can exhibit colors and patterns engineered for jewelry or purely aesthetic purposes. Zirconium Carbide or Nitride:
These materials are synthetic and metallic, with a high refractive index and an unusual, futuristic appearance when polished. Metal-Organic Framework (MOF) Crystals:
MOFs are a class of synthetic porous crystals with complex geometric structures and vibrant colors, making them unique and striking. Hyper-Modified Glass or Vitreous Materials:
Glass-like gemstones doped with rare elements (such as europium or neodymium) can fluoresce or shift colors in ways impossible in natural stones. Synthetic Garnets (Uncommon Types):
Garnets like gadolinium gallium garnet (GGG) or yttrium iron garnet (YIG) are synthesized for industrial purposes but can be cut into gemstones. These stones are not just rare but impossible to find naturally, offering a unique and unconventional aesthetic perfect for someone looking to stand out.
A lot of comments here are suspicious of you, so I’m going to try my hand at guessing whether this was AI.
Since GPTs are hilariously bad at detecting themselves, I’ll venture on the human spirit!
First, we establish truth 1: this is copy-pasted.
Although Moissanite isn’t mentioned twice, everything after “Synthetic Alexandrite” inclusively is mentioned twice. That means this was procedurally copy-pasted. Someone writing on their own would either CTRL+A then CTRL+C and make no mistakes, or not repeat themself at all.
Of course, we can also look at the half-formalized format that indicates something was copied from raw text and pasted into markdown, rather than formatted with markdown first.
copy-paster spotted
Second, we cast doubt that a human wrote the source.
Non-reused acronym definitions.
This is probably taken straight from the Wikipedia’s site description for YIG. Usually humans don’t define an acronym only to never use it, unless they’re making a mistake, especially not for just making repeated structure. So either Wikipedia was in the training corpus or this was Googled.
5/23 sentences start with “While” (weak ai indicator)
no three-em dashes or obvious tricolons are overused (non ai-indicator)
no filler bullshit introduction or conclusion (non ai-indicator)
obvious repeated structure that you can feel (strong ai indicator)
Suspiciously uncreative descriptions (ai indicator)
Repetition of “unusual” and “rare” rather than more flavorful or useful adjectives (AI indicator)
Superficial, neutral-positive voice despite length and possible source. If this was pasted from a technical blog, I’d expect it to have more “I” and personal experiences, or more deep anecdotal flavor (AI indicator)
Third… let’s take a guess
So it was copy-pasted from somewhere, but I can’t imagine it being from a blog or website, and it isn’t directly from Wikipedia. It has some nonhuman mistakes, but is otherwise grammatical, neutral-positive, and repetitively structured. And it lacks that deeper flavor. So… it was an AI, but likely not openAI.
At least there aren’t any very “committal” facts, so the length but lack of depth suggests that everything’s maaaaaaybe true…
I wasted my time typing this
I thoroughly enjoyed your in-depth analysis and learned a few things. I think we need to understand how to spot if something was written by AI or not, and this is very helpful for that.
Thank you! (˶ˆᗜˆ˵) ✧
I enjoyed your analysis, and appreciate the time you spent on it!
lol
Before I proposed, my (now)wife and I discussed this and we did some research, then went with Moissanite.
She has a ring with a huge very shiny stone that doesn’t break when it hits something, and we both also still have some money left.
It’s awesome that all these other options exist as well!
(Similarly, we got married at home with a friend as an officiant* and only close family present. It was great.
*He had earlier gotten himself ordained by mail so he could officiate the wedding of his own daughter.)
Moissanite is so pretty. I’m not much of a jewelry guy. And I’m not trans. But I’ve always wanted to wear lots of pretty sparkly things. I’m having a blast looking through all these fun possibilities. When I was in Atlanta a pedestrian walked by me wearing all white, and dripping in silver chains, he looked like a time traveler, I want to do that but with purple or green. Do you remember where you got your engagement ring stone?
Have you ever considered glitter as a starting point?
to marry someone? you monster
This is fascinating and badass. Now I want a crazy neon pink gemstone.
Me too, just researching gave me so many ideas, even if I never plan to buy one. They’re so pretty. Check out the quartz
Some of these vendor sites are crazy expensive but with a little more digging I bet I could find high quality, big beefy stones for under a hundo
Hmm…
That fucking site is going to cause so much unnecessary strife and difficultly. LLMs are trained on real speech; that site is going to get is wrong constantly. We all want there to be some magic bullet or to pretend that AI is so easily clockable, but the simple truth is that it simply isn’t and all shit like this does is end up making people who actually know how to use “advanced grammar” (said sarcastically) like semicolons and em dashes have to deal with a shit ton of harassment from idiotic chuds who can’t comprehend that a real person can be more eloquent than “me like good thing!”
yeah, well… Some website said you talk like a chat bot so hahah owned! /s
The hypocrisy of using AI to ferret out AI and then to act like that gives one any right to judge…
right? who cares who wrote it. it’s a hobby post, not a dissertation
Why does it say “likeley generated by AI”? If it’s 43%, that means it’s more likely to be written by a Human.
Those sites are really inaccurate afaik, but it does feel generated.
Probably because it was boring and repetitive by the 3/50th paragraph.
?
Well… Was it?
what
Heh it was
what
Ok, but is any of it wrong? That’s much more important to me, but I can’t speak for anyone else.