Talk:Crystallographic defects in diamond

Untitled
A few notes regarding my expansion: Any comments or questions? -- Hadal 21:35, 12 July 2005 (UTC)
 * I've tried to explain the theory as clearly and succinctly as I'm able, so I invite anyone with a stronger background in solid state physics to amend or expand as necessary.
 * I did not write a subsection on interstitial atoms; I may get around to this sooner rather than later, but I'm not exactly comfortable in doing so because I can't seem to find references that don't conflict with each other.
 * To Stepanovas: I've included inline references to back up statements where appropriate, so I think it would be helpful if you could do the same for your material (e.g., the C form to A form conversion).
 * I used old-style parenthetical inline refs because I don't really like the Template:Ref style nor its Note equivalent; I reference the same work more than once, which isn't something these templates can do very well.


 * Hadal, yet again great work! Regarding intrinsic defects, see dislocation for a better grounding in the materials science end (for one, edge and screw are the preferred terms to glide and shuffle). I will try to dig up my solid state physics and physical chemistry texts for some more insight and references. - Bantman 19:41, July 13, 2005 (UTC)


 * Thanks! I did wonder if the glide/shuffle terminology was idiosyncratic to the authors cited, but I felt it best not to contradict them in the event that the terms had a special meaning in semiconductor research. (A quick Google reveals at least a handful of related publications using the present terms.) I also forgot to link to the dislocation article; it may be best to restructure this article to reflect the former. -- Hadal 04:57, 17 July 2005 (UTC)


 * old-style inline refs are good. But references, which you added, are not primary. Those are latest works which dose not reflects initial researches and discoveries. I will work at it. Stepanovas 07:36, 14 July 2005 (UTC)


 * I see you found a primary reference for Kaiser and Bond; thanks for that. The other refs are good enough though, aren't they? Secondary references are fine for Wikipedia, as we're not exactly trying to write a journal paper. Furthermore, the refs I used are considered authoritative in my field; gemmology does encompass some aspects of diamond's crystallographic defects, and to that end I've contributed what I could. Anderson and Payne are as primary as you can get when referencing gem spectra in general. -- Hadal 04:57, 17 July 2005 (UTC)

Discussion
Stepanovas 15:36, 16 July 2005 (UTC)
 * B2 not nitrogenous defect, N3 content never high.
 * aforementioned Cape series What is it?


 * B2 was already treated as a nitrogenous defect before I arrived, so I wasn't about to contradict that placement without further research. N3 content is not precisely "high", but neither are most the others; we're talking fractions of a percentage by mass in most cases (at least in gem-grade stones). Your "up to one percent by mass" is superlative rather than typical, is it not? In my field, the N3 line is diagnostic for diamond.
 * The Cape series is explained under B1 center, as well as under Material properties of diamond. It's a common term for Type IaA + IaB mixed material, and includes nearly all (98%) diamonds. Since so many diamonds exhibit the N3 line, I thought it pertinent to mention. Do you not agree? I realise the article's emphasis is on IR spectra, but that's just one of several angles of investigation. The N3 line is (IMO) major by virtue of its presence in the visible spectrum and its orchestral relationship with the other defects. It is not major in terms of mass, but it is very persistent. (So why did you remove UV/VIS from the list of methods?)
 * Also, why did you remove my qualifying statement, "... provided the diamond is cooled to very low (ca. -180&deg;C) temperatures"? It is my understanding that cryogenic temperatures are required (or at least a de facto standard) for accurate IR spectra, as diamond is such an efficient thermal conductor: the warmer the diamond is, the more diffuse the spectrum is (due to atomic vibrations). This isn't a new concept, but if you think it's somehow unremarkable, I'll leave it be.
 * Hadal 04:57, 17 July 2005 (UTC)

because spectops may be recived under different tempersatures.


 * vacansy in diamond is not F-Center because diamond is not ionic crystal.
 * Green color is due defficult defects consisting from nitrogen, vacansies and intersticials.

Stepanovas 15:59, 18 July 2005 (UTC)


 * Irradiated diamonds do have F-Centers: in this context, F-Center is a synonym of color center. See page 4 of this PDF from the Mineralogical-Geochemical Institute of the University of Freiburg or page 2 of this article by Paul F. Hlava of Sandia National Laboratories for two examples of this usage. However, because some authors reserve "F-Center" exclusively for ionic crystals, I've replaced the term with "color center" to avoid confusion. In future, I would appreciate it if you could constructively edit the specific term you have a problem with, rather than simply remove a large chunk of referenced text.
 * The green (and in some cases blue) colour of irradiated diamond is the result of these color centers; the mechanism is fundamentally different than impurity-derived colour. While the vacancies do interact with interstitials, it seems irradiation alone does not produce the high temperatures needed for vacancy migration. Rather, the consensus is that nitrogen-radiation defect complexes are only likely after annealing, which also agrees with my cited references. For further examples, see and . Natural annealing via long-term geothermal heating probably does produce vacancy-nitrogen defects, but the point is that the heat is a required element for NV defect complexes.
 * We have so many references now that I'll likely stick with them when doing future expansions. There's still a bit more info to harvest, such as hydrogen in Type IIc (ooh!) diamonds.
 * I think the article's maturing nicely. -- Hadal 04:41, 19 July 2005 (UTC)

Fluorescence and other questions
Agthorr June 15, 2006:

This is a great article. I've learned a lot, but I still have some unanswered questions. I'm hoping some of the authors of the article might be able to find answers for them (or point me in the right direction) and update the article with the additional information.

I've been trying to better understand the blue fluorescence seen in many available-to-the-consumer diamonds. I know its caused by the absorbtion of UV light, exciting an electron, which shortly thereafter radiates blue light. The description of the N3 and N2 centers state that they absorb UV light; are these the centers that cause fluorescence? Or is it caused by a different kind of defect?

I've heard many conflicting reports about the "oily" or "milky" look of fluorescing colorless diamonds. Everyone seems to agree that very strongly fluorescencing stones have the oily look and that mildly fluorescing diamonds are fine. For moderate and strong fluorescence I find a lot of disagreement. Some people swear up and down that all such stones appear oily. Some people swear up and down that all such stones appear oily when viewed under significant UV lightly (e.g., daylight). Some people (such as this GIA report) state that *only* very strongly fluorescencing diamonds exhibit the oily or milky appearance. Finally, other people state that the oily or milky look depends on the particular stone, and some strongly fluorescing stones have it, while others do not.

Based on what's in the article now, I get the sense that a milky look could be the result of many colorless defects (such as A or B1 centers) that don't alter the color of the stone, but nevertheless reduce transparency. Is that possible? Do A or B1 centers lead to translucency (as opposed to transparency)?


 * Milky, cloudy, or oily appearance are all things that can occur independently of fluorescence. However, in a certain percentage of very strong blue fluorescent stones (3% according to the GIA) one or more of these features appear under sources rich in uv (e.g., daylight) but not in uv-free lighting conditions. To what extent, if any, the same phenomenon may be visible in stones of lesser fluorescence (for example, under very intense filtered uv light) is something on which I have no information, although it's obviously a question that needs answering. Zyxwv99 (talk) 19:23, 6 May 2013 (UTC)

Delisted GA
This article has been removed from the Ga list as it has failed WP:WIAGA criteria 2b. Feel free to renominate the article once these issues have been addressed. Tarret 23:42, 23 October 2006 (UTC)

Failed 2009 GA nom
After over a month on the list, I have failed this for two reasons:


 * Uncited statements. Some serious ones, which I'll list later. In an article that cites eighty-two scholarly papers published in reputable scientific journals, so much that my printed copy requires three pages at 10 points to show almost all of them, there is no excuse for this).


 * General prose sloppiness. There are missing pronouns and articles all over the place, from non-native English-speaker edits, I'll venture. Some paragraphs seem to be disconnected collections of thematically related sentences. And the overall organization within sections is inconsistent and disorganized. I also feel it's a little heavy on the jargon, even granted that this is a fairly technical subject.

I will go into specifics later tonight on the subpage. Daniel Case (talk) 23:38, 30 January 2009 (UTC)

N3 does not induce color on its own?
Has somebody checked multiple sources on this? Zyxwv99 (talk) 19:17, 6 May 2013 (UTC)

Okay, I think I figured it out. N3 is apparently phosphorescent. It absorbs photons of 415.5 nm which raises an electron to a higher energy level. Then one microsecond later the electron drops back down, emitting a photon of the same wavelength as was absorbed. I was confused because the article did not specify the nature of the emission. I though maybe it was fluorescence. Zyxwv99 (talk) 00:54, 7 May 2013 (UTC)
 * N3 has a short luminescence lifetime (nanoseconds, not microseconds), and the intensity is not strong enough to impart color under usual illumination (sunlight or office light). N3 contributes to color only via absorption. N3 concentrations are usually low, and its absorption starts roughly from its zero-phonon line at 415 nm and extends into UV, i.e. almost beyond the spectral sensitivity of human eye. However, N3 is always accompanied by N2, which absorbs green and results in straw-yellow color in a small percentage of diamonds. Materialscientist (talk) 01:05, 7 May 2013 (UTC)

Assessment comment
Substituted at 12:30, 29 April 2016 (UTC)

External links modified
Hello fellow Wikipedians,

I have just modified one external link on Crystallographic defects in diamond. Please take a moment to review my edit. If you have any questions, or need the bot to ignore the links, or the page altogether, please visit this simple FaQ for additional information. I made the following changes:
 * Added archive https://web.archive.org/web/20050528202931/http://www.icem15.com/Documents/Diamonds.pdf to http://www.icem15.com/Documents/Diamonds.pdf

When you have finished reviewing my changes, you may follow the instructions on the template below to fix any issues with the URLs.

Cheers.— InternetArchiveBot  (Report bug) 04:07, 15 August 2017 (UTC)