Jump to content

Talk:Radium

Page contents not supported in other languages.
From Wikipedia, the free encyclopedia
Good articleRadium has been listed as one of the Natural sciences good articles under the good article criteria. If you can improve it further, please do so. If it no longer meets these criteria, you can reassess it.
On this day... Article milestones
DateProcessResult
October 4, 2014Good article nomineeNot listed
July 15, 2021Good article nomineeNot listed
June 26, 2022Good article nomineeNot listed
October 25, 2024Good article nomineeListed
On this day... Facts from this article were featured on Wikipedia's Main Page in the "On this day..." column on December 26, 2007, December 26, 2008, December 26, 2009, December 26, 2013, December 26, 2015, December 26, 2017, December 26, 2018, December 26, 2020, and December 26, 2022.
Current status: Good article

Semi-protected edit request on 22 December 2023

[edit]

Change "Formerly, around the 1950s, it was used as a radioactive source for ..." To "From the 1910s, it was used as a radioactive source for ..."

Reference https://en.m.wikipedia.org/wiki/Radium_Girls Mhurrell1953 (talk) 03:26, 22 December 2023 (UTC) mhurrell1953[reply]

 Not done: please provide reliable sources that support the change you want to be made. ayakanaa ( t · c ) 05:43, 23 December 2023 (UTC)[reply]

A +1 oxidation state?

[edit]

https://www.nature.com/articles/s41586-020-2299-4 Should I add the +1 oxidation state to the infobox for this article? It seems reasonable, since the radium in RaF gave away one electron to a fluorine. SupercriticalXenon (talk) 14:41, 25 May 2024 (UTC)[reply]

Physics beyond the standard model

[edit]

Is the information in the article under Modern applications regarding radium's place in "new models" of physics due to breaking forces useful? It seems overly technical in relation to the rest of the article and the sources provided don't make much mention of radium in particular. Could be some kind of WP:SYNTH? Reconrabbit 19:37, 13 August 2024 (UTC)[reply]

Glaring error

[edit]

"In the early history of the study of radioactivity, the different natural isotopes of radium were given different names..."

No, they were not - there was no way to separate them at that time.

Someone please fix this. The most effectual Bob Cat (talk) 13:24, 24 August 2024 (UTC)[reply]

I think you are assuming someone had a mixture of the different isotopes in a sample they knew to be the "same chemical element" and then separated them into the various isotopes. Instead, different isotopes come from different sources based on being products of different elements' decay-chains. And the isotopes might have different properties, such as different radioactivity. If I start with X and get Y that then has behavior Z and you start with A and get B that has behavior C, we might not know at first that Y and B are the same element. Thus there were substances known as "Actinium X", "Thorium X", and "Mesothorium 1" that turned out to be radium-233, 234, and 238, respectively. DMacks (talk) 17:08, 24 August 2024 (UTC)[reply]

GA Review

[edit]

The following discussion is closed. Please do not modify it. Subsequent comments should be made on the appropriate discussion page. No further edits should be made to this discussion.


GA toolbox
Reviewing
This review is transcluded from Talk:Radium/GA4. The edit link for this section can be used to add comments to the review.

Nominator: Reconrabbit (talk · contribs) 16:10, 15 August 2024 (UTC)[reply]

Reviewer: Jens Lallensack (talk · contribs) 12:03, 9 October 2024 (UTC)[reply]


I will review this. --Jens Lallensack (talk) 12:03, 9 October 2024 (UTC)[reply]

  • I worry that the infobox image (Radium226.jpg) is misleading, because I'm not sure if we can directly see any Radium in the first place there? The viewer will think that the piece shown is Radium, but it is not. Maybe it is better to leave it without an image, or to use the "Radium-226 radiation source" image instead. The Radium226.jpg could be used later in the article. In any case, it needs a proper caption explaining what can be seen.
  • When radium decays, it emits ionizing radiation as a by-product, which can excite fluorescent chemicals and cause radioluminescence. – But isn't that the case for any ionizing radiation? The fluorescence and radioluminescence are not specific for radium, so why mention it here (and not other effects, like health effects)?
    • These properties are particularly important to the history of radium. Relatively few other elements that emit ionizing radiation were used for this property. Its toxicity is mentioned immediately afterwards (with an added note on why it's so toxic).
  • What are "Radium watch hands"? Needs link or explanation.
  • Pure radium is a volatile silvery-white metal, although its lighter congeners calcium, strontium, and barium have a slight yellow tint. This tint rapidly vanishes on exposure to air, yielding a black layer of what is probably radium nitride (Ra3N2). – I can't follow here: How can the yellow tint in calcium, strontium, and barium result in radium nitride?
    • I've tried to clarify this by stating that it's radium's lustre (as stated in the NRC report) that becomes a black layer, rather than the "tint".
  • though mesothorium 1 in particular was still used for some time, with a footnote explaining that it referred to 228Ra. – Was that only in a single paper? Is there a seconsary source for the claim that mesothorium was still used? If not, I suggest to remove this.
    • I believe I added this statement when searching literature for this particular phrase; it may have been a preference of the author and not representative of the field as a whole. I can remove it here.
  • Some of radium-226's decay products received historical names including "radium", ranging from radium A to radium G, with the letter indicating approximately how far they were down the chain from their parent 226Ra: Radium emanation = 222Rn, Ra A = 218Po, Ra B = 214Pb, Ra C = 214Bi, Ra C1 = 214Po, Ra C2 = 210Tl, Ra D = 210Pb, Ra E = 210Bi, Ra F = 210Po, and Ra G = 206Pb. – Again, do we have a secondary source here (one that is recent enough to give an overview over historical terminology)? If not, that could be a sign that this is not relevant enough for this general article.
    • I found some broader sources, but not broad enough to justify keeping this in the article for the element in general. As such the whole paragraph is moved to isotopes of radium, but the editors more involved in radiochemistry may choose to get rid of it altogether.
  • In the early history of the study of radioactivity – I would say that this entire paragraph does not really fit in. It is a bit difficult to follow, as it requires knowledge that is only introduced in the next paragraph. If you want to keep it, move to the History section?
  • and always exhibits its group oxidation state – I found this wording to be strange; can it possibly not exhibit its group oxidation state of +2?
    • This has been changed to just reflect what is stated by the NRC.
  • Radium oxide (RaO) has not been characterized well past its existence, despite oxides being common compounds for the other alkaline earth metals – remove "past its existence", I think it only confuses and does not really add anything?
    • Considering removing mention of radium oxide altogether as it barely seems to exist, but this sentence should be in better shape now.
  • luminous – link, or does that just mean radioluminescence?
    • The literature is frustrating on this point. The cause of the luminescence is almost definitely due to the excitation of nitrogen in the air as stated in the next paragraph for radium bromide, but no such thing is ever stated for the chloride.
  • In July 1898, while studying pitchblende, – Why mention again that they were studying pitchblende? It's still the same study, right?
    • I have to re-check the ACS source, but I believe this was a separate study. The phrasing is not clear on this.
  • nuclear panels – what do you mean with that?
    • Referring to "instrument panels" as in "nuclear instrument" - the latter wording isn't replicated in the source so it's been changed in the article to reflect that.
  • Section Commercial use – The section title is too broad here, it surely would also include the glowing paint discussed in the previous section.
    • I renamed it to "Quackery", as that's most of what it contains - though that could be a contentious title, I'm sure there is a better one out there.
  • In the U.S., nasal radium irradiation was also administered to children to prevent middle-ear problems or enlarged tonsils from the late 1940s through the early 1970s. – Why isn't this placed under "medical uses"? Isn't it a medical use?
    • The implication is that this use falls under "quackery", though the literature doesn't seem to agree with that. It's been moved.
  • Radium (usually in the form of radium chloride or radium bromide) was used in medicine to produce radon gas, which in turn was used as a cancer treatment; for example, several of these radon sources were used in Canada in the 1920s and 1930s. However, many treatments that were used in the early 1900s are not used anymore because of the harmful effects radium bromide exposure caused. – But you said that the treatments use Radon, not radium bromide?
    • Radon is produced by radium in the form of radium bromide (or radium chloride). It would not be possible to perform a radon exposure treatment without first being exposed to the radium precursor. I could state that again if it's unclear.
  • This was the same method used to treat Henrietta Lacks, the host of the original HeLa cells, for cervical cancer. – Context for this information is unclear. When was it? Did it also involve Kelly?
  • Structure of "Medical uses" section seems a bit random: first you discuss cancer treatment, then the uses in genetics research, then cancer treatment again.
    • I tried to move this around a bit, now that it's "medical and research uses".
  • Howard Atwood Kelly, one of the founding physicians of Johns Hopkins Hospital, – you place a lot of emphasis here on Kelly. I worry about undue weight; maybe the paragraph could be more general/broader?
    • Excised as described above.
  • In medical uses, you show the Radior ad, but none of that is discussed in the article?
    • It should be an example of the products related to radioactive quackery mentioned in the previous paragraphs - it's been moved and given more context, though it isn't as relevant as it could be.
  • was the silver mines – "were" the silver mines?
    • This sentence gave me trouble, it's now "the silver mines [...] were the only large sources."
  • The formation of an Austrian monopoly and the strong urge of other countries to have access to radium led to a worldwide search for uranium ores. The United States took over as leading producer in the early 1910s. The carnotite sands in Colorado provide some of the element, but richer ores are found in the Congo and the area of the Great Bear Lake and the Great Slave Lake of northwestern Canada. Neither of the deposits is mined for radium but the uranium content makes mining profitable.[34][69] – The first sentences are about the early 20th century, but the last two are written in present tense. How do they relate to the history?
    • The last two sentences were of unclear relevance, especially since this is veering more into "uranium" territory than radium specifically, which is not even obtained from uranium ores in the current time period (According to later references). Removed.
  • In 1954, the total worldwide supply of purified radium amounted to about 5 pounds (2.3 kg).[44] The chief radium-producing countries are Belgium, Canada, the Czech Republic, Slovakia, the United Kingdom, and Russia. – Same issue here. You describe the history but then there is a sentence in present tense?
    • I've tried to rearrange this to be less confusing time-wise.
  • The metal is isolated by reducing radium oxide with aluminium metal in a vacuum at 1,200 °C.[30] – This sentence seems out of place. You discuss how radium is produced further up in the section; shouldn't this be there, too?
    • It's now up there. Meant to imply that the current method of isolating the metal is this method as it is done in 2018, but it is better placed in the preceding paragraph.
  • Symmetry breaking forces – what is this; wikilink or explain?
    • I've linked it - the modern applications of radium are I admit somewhat beyond my expertise.
  • At the time of the Manhattan Project in the 1940s, the "tolerance level" for workers was set at 0.1 micrograms of ingested radium.[87] – Sentence seems out-of-place and out-of-context where it currently is. It should be discussed together with modern levels and regulations, no?
    • It's in a more appropriate location now, though the wording was rearranged in other parts, mainly related to the NRC.
  • and it must be handled in tight glove boxes with significant airstream circulation – this regulation applies where? Worldwide?
    • I got rid of that whole paragraph. The description is from Ullmann's Encyclopedia of Industrial Chemistry and it's quite thin on this element.
  • The world's largest concentration of 226Ra is stored within the Interim Waste Containment Structure, approximately 9.6 mi (15.4 km) north of Niagara Falls, New York.[89] – What is meant by the "largest concentration"? Is this extracted radium, or radium content of atomic waste?
    • This is referring to "radioactive residue", most likely waste materials. I'm not certain how relevant this is to the article, considering that. Edit: Removed.
  • In the United States, the Environmental Protection Agency-defined Maximum Contaminant Level for radium is 5 pCi/L for drinking water;[90] the Occupational Safety and Health Administration does not specifically set exposure limits for radium, and instead limits ionizing radiation exposure in units of roentgen equivalent man based on the exposed area of the body. Radioactive material exposure is regulated more closely by the Nuclear Regulatory Commission,[91] which sets the exposure limit to 226Ra at 0.01 μCi. Outside of the United States, exposure to radium is regulated by the International Commission on Radiological Protection and the World Health Organization.[92] – This gives a lot of details about the US, but no details about the rest of the world. I think it should instead focus on WHO regulations, maybe followed by some country-specific regulations (including, but not limited to, the US). --Jens Lallensack (talk) 22:32, 12 October 2024 (UTC)[reply]
    • I dug into this and came up with a lot of info from the IAEA and the ICRP. I could go more in depth on it but what it boils down to is that most of the recommendations come from the ICRP, which are disseminated through regional and international organizations and eventually form into country-specific regulations. It's just that most of the English-language information talks about the US regulations (location and literature access at my US-based institution probably also influences my searches).

Sources spot check

  • Radium oxide (RaO) has not been characterized well past its existence, despite oxides being common compounds for the other alkaline earth metals – Can't find this in the source.
  • In the mid-1920s, a lawsuit was filed against the United States Radium Corporation by five dying "Radium Girls" – Can't find this in the source.
    • The source for this is used several paragraphs on. I've copied it over. Warrants review of the rest...
  • What makes source 55 a reliable source? Looks like a personal website?
    • Assuming this refers to dissident-media.org, I am looking into it.

Confirming source-text integrity (Nominator)

Bulk properties
  • [1]: I don't have the book, but 514.8 pm is corroborated by WebElements using a 1968 source.
  • [2]: Numbers of isotopes, isomers, and their relative stability all supported by the data in the most recent NUBASE publication.
  • [3]:
  • [4]: "supposedly because of the formation of a nitride", "melting pont of 700C or 960C", "The element exhibits only one oxidation state (+2) in solution", "Because of its highly basic character, the divalent ion is not easily complexed. Hence, most radium compounds are simple ionic salts.", "turning yellow and ultimately dark with age owing to self-decomposition from the alpha radiation"
  • [5]: "Boiling point: not well established", "principally for the treatment of cancer by subjecting tumours to the gamma radiation of its daughter isotopes". Statement on the safety of intact painted devices not found, replaced with Canadian Nuclear Safety Commission source.
  • [6]: can't access archive.org right now (to add a page number), but the page on Barium confirms the boiling/melting point trends within Group 2
  • [7]: in abstract: "5.148 ± 0.015 angstrom" (1 angstrom is equal to 100 picometers)
  • [8]: confirms both Ra and Ba have crystal structure bcc at 1 atm.
  • [9]: Confirms both Ra and Ba have crystal structure bcc at 1 atm in plainer terms. Also includes density of radium and barium (the former is higher than the latter). "ratio" discussion could be justified as WP:CALC but I took that out.
  • [10]: Describes the sources of Radium isotopes and their half-lives. The text also uses the definition of "primordial nuclide" to justify some of this explanation. I've inserted the NUBASE2020 reference as a citation on "uranium and thorium have very long half-lives". Orange tickY Need to find a reference for the name-drop and date of E. Eoler on decomposition of the azide. It was "Ebler", not Eoler. Removed this source and added two others that support the claim.
Chemistry
  • [20]: "Studies on both RaF2 [229] and RaAt2 [230] indicate that the 6s and 6p orbitals on Ra participate in the bonding, creating a degree of covalency in the bonding."
  • [21]:
  • [22]: "Radium coprecipitates with all barium compounds (and to a lesser extent with most strontium and lead compounds)"
  • [23]: "it tarnishes rapidly even in dry air (forming a nitride)"
  • [24]: "It reacts readily with water, evolving hydrogen and forming a soluble hydroxide" "Radium hydroxide is the most soluble of the alkaline earth hydroxides and more basic than barium hydroxide. It is more soluble than actinium and thorium hydroxides and can be separated from these elements by their precipitation with ammonia." "When small quantities of barium impurity are present the crystals of radium chloride sometimes have a rose color." "the solubility of radium chloride decreases more rapidly with increasing acid concentration than does that of barium chloride. However, the enrichment per fractional crystallization step decreases for barium-radium mixtures highly concentrated in radium because of double salt formation between the two chlorides. Final separation of radium from barium has customarily been carried out by fractional crystallization of the bromides" "Crystals of radium bromide occasionally explode." "The air immediately surrounding a sample of radium bromide glows and shows all of the bands in the nitrogen spectrum. The luminosity is probably due to the impact of the a radiation on the nitrogen molecules of air"
  • [25]: "In addition to those listed, the phosphate, oxalate, and sulfite coprecipitate with the corresponding barium compounds and are probably themselves insoluble."
  • [26]: "Because of its great insolubility radium sulfate is less dangerous biologically than most radium compounds."
  • [27]: "Because of its large ionic radius, radium forms weak complexes and is not well extracted from aqueous solutions except at high pH values." "The use of 226Ra as a γ emitter in nuclear medicine for cancer therapy lost its importance when larger and cheaper 60Co sources became available" "Radium metal is prepared by reduction of the oxide by aluminum at 1200 °C in vacuum." "Radium is mainly used to prepare 227Ac via neutron capture in a nuclear reactor."
Occurrence
  • [28]:
  • [29]: "Radium is present in all uranium minerals, and could be extracted, if desired, from the extensive wastes of uranium processing" "There is about 1 g of radium in 7 tons of pitchblende" (calculating for 1 ton yields 1/7 gram). Previous statement about thorium minerals is extrapolated from "radium is part of the thorium decay chain" previously stated.
  • [30]:
Luminescent paint
  • [41]: "A watch may have approximately 1 microgram of radium on it,"
  • [42]: "After her sisters joined in the lawsuit against USRC", "The "Radium Girls"", "Indeed, no radium-induced malignancy has yet been observed in anyone who entered the dial painting industry after 1925"
  • [43]: "...by wiping the brush clean between their lips the proper erasing point could be obtained. This led to the so-called practice of "tipping" or pointing the brush in the lips."
  • [44]: Author of the site, William Kovaric, is a historian and cites his sources pretty extensively. "The causes of death in the Orange cases were listed as phosphorous poisoning, mouth ulcers and syphilis, but factory workers suspected that the dial painting ingredients had something to do with it."
  • [45]: "Light produced from luminescence devices is used directly in visual devices to produce signals that require dependable operation [...] For applications in micro-devices, however, a much higher specific activity is required, which only can be provided by 147Pm, 155Eu, and 171Tm", "industrial processes using synthetic molecules and various materials can lead to the production of "technogenic" tritium [...] residues from factories manufacturing luminous safety lighting"
  • [46]: I don't have this source. ☒N and have no way to vouch for it being correct or not
  • [47]: "Tritium is considered to have low radiotoxicity, compared, for example with radium or cesium, because it emits relatively low energy beta particles which cannot penetrate the skin."
  • [48]: Replaced with some sources that give the decay energy in plain numbers instead of having to calculate it from the NUBASE document.
  • [49]: "Insignificant [No 3H betas pass through the dead layer of skin]"
  • [50]:
  • [51]: Replaced with Canadian Nuclear Safety Commission source.
Modern applications
  • [69]: "Radioactive molecules are especially attractive for precision tests in the search for BSM physics,[...] Radioactive elements such as Ra are particularly promising[...]" "we laser cooled radium ions for the first time and did fundamental measurements and tests on radium ions and radium-containing molecular ions that laid the groundwork for future precision measurements. These work also opens up other opportunities with radium ions including quantum information science [7] and optical clocks [8]." (not ideal as a primary source, but peer-reviewed at least)
  • [70]: "for a many-electron atom with unpaired electron in an s1/2 or p1/2 orbital, R - 10Z3a2⁠." "Near the nucleus the electronic orbital is nearly Coulombic and as a consequence, the electronic velocity ve is proportional to the nuclear charge Z" I really don't understand this bit.
  • [71]: "The resulting Schiff moment, which depends on three unknown 𝑇-violating pion-nucleon coupling constants, is much larger than in 199Hg, the isotope with the best current experimental limit on its atomic electric-dipole moment."
  • [72]: "Ra+ provides a very promising route toward the most precise measurement of atomic parity violation (APV)." "Clock performance based on the transitions in Ra+ has been investigated [...] the transition has a corresponding natural linewidth of 0.265 Hz."
  • [73]: "The clock uses a single trapped 226Ra+ ion and operates on the 7⁢𝑠 2𝑆1/2→6⁢𝑑 2𝐷5/2 electric quadrupole transition" "These features, along with the photonic-technology compatible wavelengths of Ra+ and the low optical power requirements of an ion clock make it an intriguing candidate for a transportable optical clock"
  • [74]: "[C]esium-137 brachytherapy sources began to replace radium sources" "Relatively short-lived radionuclides, such as cobalt-60, have no upper concentration limit for Class C (or even Class B) because the radioactive material decays sufficiently over the centuries for the hazard to diminish below regulatory limits" I can't access the other book in the reference though.
  • [75]: "The FDA has hit the green light for Xofigo--initially called Alpharadin or radium-223 chloride--for castration-resistant prostate cancer" document specifically referring to it as a "solution" has been added
  • [76]: Referring to castration-resistant PCa: "In conclusion, Ra-223 represents a bone-homing radiopharmaceutical with disease-modifying properties."
  • [77]: "225Ra has been used experimentally for therapeutic irradiation, as this is the only isotope of radium that does not have a gaseous decay product"
  • [78]: "the Ra-Be source, prepared by mixing and compressing radium bromide with beryllium powder, increases steadily in neutron activity"
  • [79]: "The Brookhaven National Laboratory(BNL) Sigma Pile contains a Radium-Beryllium (Ra-Be) neutron source; which is embedded in a cube of graphite blocks."
  • [80]: "Also most (α, n)-neutron sources based on 226Ra were replaced by 241Am – Be sources even if the number of emitted neutrons in 226Ra sources are higher (for RaBeF4: 1.84×106 neutrons per second and per gram 226Ra)."
Hazards
  • [81]:
  • [82]: The early history of radiation history, including the involvement of the ICRP and the Röntgen Society, is described.
  • [83]: Meetings and developments in radiation regulations are discussed beyond the 1920s.
  • [84]: "The need for an international radiological protection committee was discussed, and the task was to ensure that a number of physicists interested in radiation protection would be present at the next ICR."
  • [85]: Table 7-1 describes international authorities on radium as the WHO and ICRP.
  • [86]: Source makes references to IAEA standards when discussing NORM which includes radium, and specifically the International Basic Safety Standards.
  • [87]: "At its 55th regular session, the IAEA General Conference, in resolution GC(55)/RES/9, encouraged Member States "to use safety standards issued by the IAEA in their national regulatory programmes, and noted the need to consider the periodic alignment of national regulations and guidance to internationally established standards and guidance"."
  • [88]: Describes a mission by the IAEA to manage 226Ra radiotherapy devices.
  • [89]: Describes a mission by the IAEA to manage 226Ra in Canada.
  • [90]: Describes the ongoing IAEA radium management program.
  • [91]: "EPA has established a Maximum Contaminant Level (MCL) of 5 picoCuries per liter (pCi/L) for any combination of radium-226 and radium-228 in drinking water."
  • [92]: "Allowing for a safety factor of between one and two orders of magnitude, this so-called "tolerance level", later termed the "maximum permissible body burden" for radium, was determined to be 0.1 uCi."
  • [93]: OSHA ionizing radiation exposure standards are listed in rem and a note on the NRC's regulation of radiation sources is present.
  • [94]: "Any individual intact timepiece containing less than 0.037 megabecquerel (1.0 microcurie) of radioactivity is exempt from regulatory requirements"
  • [95]: Lists member countries of the NEA, with links to specific regulatory structures in each.
  • [96]: Describes Korean nuclear management structure and general international flow of regulatory development in relation to radioisotopes.
  • [97]: Describes efforts by IAEA to establish governance structure over radioactive material in Africa, where few countries have laws or groups regulating such.
  • [98]: Detail on efforts by the IAEA to establish governance over radioactive material in the Congo. (Information on non-IAEA groups working to do this is not forthcoming, which is why only IAEA is mentioned here.)

Conclusion: The article still needs work to reach GA level. The chemistry content is good and well-written, but the problems are further down in the article. The main weakness seems to be the applications and historical uses sections. The sources spot-check unfortunately did not pass. I would need to ask you to check the other sources yourself, and when you believe that everything is ok, I would have to do another spot check. If you think you can solve everything within two weeks, I am happy to keep the review on hold; if you need longer, I would be happy to pick up the review again in a new GA nomination if you like. Let me know what you think. --Jens Lallensack (talk) 22:32, 12 October 2024 (UTC)[reply]

I realize in this review that I made a lot of assumptions about the previous authors of this article, and that I also fell into a lot of mistakes trying to maintain the same structure, ending up with weird chronology and missing sourcing in the middle of paragraphs. Organization is tough and I make assumptions about what is obvious and what isn't. In the coming week I will do my utmost to address the concerns raised, then start on the process of checking all the sources I did not add myself. I'll be in a better spot to say where I can bring this article by 18 October. Reconrabbit 02:04, 13 October 2024 (UTC)[reply]
@Jens Lallensack: After working through all of the recommendations, I'm mostly content with how the text has come out, but would like to know how it looks and if there are still issues of undue weight. I believe I should be able to review the sources used within the week but will first evaluate if I even have access to a lot of the old references first. Thanks. Reconrabbit 21:07, 21 October 2024 (UTC)[reply]
Impressive work! Once we are confident about the text-source integrity, I can promote this. One point though: which are not enforced by the IAEA but are freely available for adoption by members of the organization. – That certainly does not mean that the regulation is only freely available to members but not to non-members? Maybe just remove that part? --Jens Lallensack (talk) 22:16, 21 October 2024 (UTC)[reply]
  • Hey, great work on the sources! I am wondering now if you really have to check very single source. If you checked a large sample of sources that do not have issues, maybe that's a sign that others are probably ok, too. Checking every single one is best, of course, especially if you plan to take this to WP:FAC at some point, but I won't require that in this GAN. --Jens Lallensack (talk) 21:32, 23 October 2024 (UTC)[reply]
    I am going to narrow my focus then to the areas I did not change majorly in my work on the article, those being "Bulk properties" (already checked except for [3]), "Chemistry", "Occurrence", "Luminescent paint", and "Modern applications". Reconrabbit 00:00, 24 October 2024 (UTC)[reply]
    @Jens Lallensack: I went through these areas and did a survey of text-source integrity, with changes in a few areas. I marked the sources I couldn't access with though I have some confidence in the reliability of those sources if not a direct quote for each statement. I also had trouble with [70] because it's been a while since I studied field theory and if that's ground for removing that information or seeking other counsel then please let me know. Reconrabbit 20:35, 25 October 2024 (UTC)[reply]

Closing note: Thank you for your comprehensive revisions. This is been a big chunk of work, and a very important contribution. I checked some of the sources and all seems fine. Congrats! --Jens Lallensack (talk) 21:03, 25 October 2024 (UTC)[reply]

The discussion above is closed. Please do not modify it. Subsequent comments should be made on the appropriate discussion page. No further edits should be made to this discussion.

State of matter of radium in a long and easy paragraph

[edit]

Tell me please Thanks 154.198.105.25 (talk) 11:31, 3 November 2024 (UTC)[reply]

Baryonic. Preimage (talk) 14:40, 3 December 2024 (UTC)[reply]