Phosphide bromide

In today's world, Phosphide bromide has become a topic of great relevance and interest to a wide variety of people. Its impact and scope are so significant that they do not go unnoticed in any area. From the academic field, through the work world, to the personal sphere, Phosphide bromide arouses great interest and debate. As we delve into this topic, we will realize the importance it has in today's society and how its influence has been growing over time. In addition, we will explore its implications, challenges and potential solutions, with the aim of thoroughly understanding this phenomenon and its consequences in our daily lives.

Phosphide bromides or bromide phosphides are compounds containing anions composed of bromide (Br) and phosphide (P3−) anions. Usually phosphorus is covalently connected into more complex structures. They can be considered as mixed anion compounds. They are in the category of pnictidehalides. Related compounds include the phosphide chlorides, phosphide iodides, nitride bromides, arsenide bromides, and antimonide bromides.

List

formula system space group unit cell Å volume density comment ref
Ca2PBr cubic I43d a=5.96 Z=2 red brown [1]
Ca2PBr hexagonal R3m a=4.23 c=20.9 Z=3 [1]
Cu12P20Br10 triclinic P a = 9.886, b = 13.190, c = 14.763, α = 70.83°, β = 82.68°, γ = 80.13°, Z = 2 1786.1 [2]
Cu13P15Br12 [3]
Cu6PS5Br cubic P43m a=9.732 Z=4 921.8 4.701 red [4]
(CuBr)2P8Se3 orthorhombic Pbcm a=8.761 b=11.957 c=13.858 Z=4 1451.8 [5]
Sr2PBr cubic I43d a=9.31 Z=2 brown violet [1]
Sr2PBr hexagonal R3m a=4.44 c=22.0 Z=3 dark reddish brown [1]
Sr2P7Br cubic P213 a=9.789 Z=4 938.0 3.342 red band gap 2.1 eV [6]
Y2PBr2 rhombohedral a=3.9807 c=29.250 [7]
Ag6PS5Br cubic P43m a=10.3765 Z=4 1117.26 5.460 red [4]
Cd5P2Br4 orthorhombic Pna21 a=12.189, b=7.7080, c=13.664 [8]
Sn24P19.3Br8 [9]
Sn17Zn7P22Br8 cubic Pm3n a=10.7449 [10]
Sn24−xInxP19.2+0.2x x<16 cubic Pm3n [11]
Si30+xP16–xTe8–xBrx x = 1–6.4 cubic Pm3n a=9.9720 - 10.0405 [12]
Ba2PBr hexagonal R3m a=4.67 c=23.3 Z=3 [1]
Ba2P7Br monoclinic P21/m a=6.294 b=6.835 c=11.850 β=95.819 Z=2 507.2 3.742 orange [13]
La2PBr2 trigonal P3m1 a=4.311 c=11.000 Z=1 177.04 5.28 [7]
La3Zn4P6.6Br0.8 orthorhombic Cmcm a=4.099 b=14.229 c=20.388 Z=4 1189.0 5.290 black [14]
Eu2PBr R3m a = 4.385, c = 21.90, Z = 3 [15]
W4(PBr)Br10 monoclinic C12/m1 a=14.0933 b=10.3228 c=11.8169 β=93.906 Z=4 1715.16 dark green [16]
Hg2P3Br orthorhombic Pbcn a = 8.014, b = 8.902, c = 7.823, Z = 4 [17]
Hg7P4Br6 monoclinic P21/c a = 6.0452, b = 19.848, c = 7.5596 β = 104.214° Z=2 879.3 7.582 brown [18]
(Hg2P)2HgBr4 monoclinic P21 a=7.776 b=12.226 c=7.930 β=121.34 Z=2 643.9 7.141 discovered in 1907; bright yellow; air with light sensitive [19]
(SnBr3) cubic P213 a=12.490 Z=4 [20]

References

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  4. ^ a b Gao, Lihua; Wu, Xiaowen; Yang, Daqing; Tian, Xinyu; Xu, Jingjing; Zhang, Bingbing; Wu, Kui (2021). "M 6 PS 5 X (M = Ag, Cu; X = Cl, Br) chalcohalides exhibiting strong nonlinear optical responses and high laser damage resistances". Dalton Transactions. 50 (48): 17901–17905. doi:10.1039/D1DT03251H. ISSN 1477-9226. PMID 34851337. S2CID 244148134.
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  7. ^ a b Oeckler, Oliver; Mattausch, Hansjürgen; Simon, Arndt (2007-11-01). "Einige Phosphidhalogenide des Lanthans und verwandte Verbindungen/ Some Phosphide Halides of Lanthanum and Related Compounds". Zeitschrift für Naturforschung B. 62 (11): 1377–1382. doi:10.1515/znb-2007-1105. ISSN 1865-7117. S2CID 95077294.
  8. ^ M.M., Shatruk; L.N., Reshetova; A.V., Shevel'kov; B.A., Popovkin (2000). "Cd5P2Br4 - the first cadmium analogue of salts of Millon's base" [Cd5P2Br4 - the first cadmium analogue of salts of Millon's base]. Zhurnal Neorganicheskoj Khimii (in Russian). 45 (4). ISSN 0044-457X.
  9. ^ Stefanoski, S.; Reshetova, L. N.; Shevelkov, A. V.; Nolas, G. S. (July 2009). "Low-Temperature Transport Properties of Sn24P19.3Br8 and Sn17Zn7P22Br8". Journal of Electronic Materials. 38 (7): 985–989. Bibcode:2009JEMat..38..985S. doi:10.1007/s11664-008-0644-8. ISSN 0361-5235. S2CID 135898461.
  10. ^ Kovnir, Kirill A.; Shatruk, Mikhail M.; Reshetova, Lyudmila N.; Presniakov, Igor A.; Dikarev, Evgeny V.; Baitinger, Michael; Haarmann, Frank; Schnelle, Walter; Baenitz, Michael; Grin, Yuri; Shevelkov, Andrei V. (August 2005). "Novel compounds Sn20Zn4P22−vI8 (), Sn17Zn7P22I8, and Sn17Zn7P22Br8: Synthesis, properties, and special features of their clathrate-like crystal structures". Solid State Sciences. 7 (8): 957–968. doi:10.1016/j.solidstatesciences.2005.04.002.
  11. ^ Reshetova, L. N.; Shevelkov, A. V. (January 2012). "Synthesis and clathrate-type crystal structure of a solid solution in the Sn-In-P-Br system". Russian Chemical Bulletin. 61 (1): 28–32. doi:10.1007/s11172-012-0004-y. ISSN 1066-5285. S2CID 95316491.
  12. ^ Abramchuk, Nikolay S.; Carrillo-Cabrera, Wilder; Veremchuk, Igor; Oeschler, Niels; Olenev, Andrei V.; Prots, Yurii; Burkhardt, Ulrich; Dikarev, Evgeny V.; Grin, Juri; Shevelkov, Andrei V. (2012-11-05). "Homo- and Heterovalent Substitutions in the New Clathrates I Si 30 P 16 Te 8– x Se x and Si 30+ x P 16– x Te 8– x Br x : Synthesis, Crystal Structure, and Thermoelectric Properties". Inorganic Chemistry. 51 (21): 11396–11405. doi:10.1021/ic3010097. ISSN 0020-1669. PMID 23072375.
  13. ^ Dolyniuk, Juli-Anna; Kovnir, Kirill (2013-08-26). "Zintl Salts Ba2P7X (X = Cl, Br, and I): Synthesis, Crystal, and Electronic Structures". Crystals. 3 (3): 431–442. doi:10.3390/cryst3030431. ISSN 2073-4352.
  14. ^ Wang, Jian; Kaseman, Derrick; Lee, Kathleen; Sen, Sabyasachi; Kovnir, Kirill (2016-07-12). "Enclathration of X@La 4 Tetrahedra in Channels of Zn–P Frameworks in La 3 Zn 4 P 6 X (X = Cl, Br)". Chemistry of Materials. 28 (13): 4741–4750. doi:10.1021/acs.chemmater.6b01752. ISSN 0897-4756.
  15. ^ Hadenfeldt, C.; Held, W. (September 1986). "Darstellung, eigenschaften und kristallstruktur der Europium(ii)-phosphidhalogenide Eu2PCl, Eu2PBr und Eu2PI". Journal of the Less Common Metals (in German). 123 (1–2): 25–35. doi:10.1016/0022-5088(86)90111-6.
  16. ^ Ströbele, Markus; Eichele, Klaus; Meyer, Hans-Jürgen (2015-02-02). "Cluster Harvesting in the WBr 6 –P System". Inorganic Chemistry. 54 (3): 989–992. doi:10.1021/ic502333u. ISSN 0020-1669. PMID 25392957.
  17. ^ Shevelkov, A. V.; Dikarev, E. V.; Popovkin, B. A. (1994-07-01). Shevelkov, A. V.; Dikarev, E. V.; Popovkin, B. A. (eds.). "Helical (P 1− ) chains in the structures of Hg 2 P 3 Br and Hg 2 P 3 Cl". Zeitschrift für Kristallographie - Crystalline Materials. 209 (7): 583–585. Bibcode:1994ZK....209..583S. doi:10.1524/zkri.1994.209.7.583. ISSN 2194-4946.
  18. ^ Shevelkov, A.V.; Dikarev, E.V.; Popovkin, B.A. (June 1993). "Syntheses and Crystal Structure of Hg7P4Br6". Journal of Solid State Chemistry. 104 (2): 177–180. Bibcode:1993JSSCh.104..177S. doi:10.1006/jssc.1993.1151.
  19. ^ Shevelkov, Andrei V.; Mustyakimov, Marat Yu.; Dikarev, Evgeny V.; Popovkin, Boris A. (1996). "(Hg2P)2HgBr4: a phosphorus analogue of the Millon's base salts". Journal of the Chemical Society, Dalton Transactions (1): 147–148. doi:10.1039/dt9960000147. ISSN 0300-9246.
  20. ^ Olenev, Andrei V.; Baranov, Alexei I.; Shevelkov, Andrei V.; Popovkin, Boris A. (2002). "A New Family of Supramolecular Complexes with 3D Cationic Hg/Z Frameworks, SnX3− Guest Anions (Z = P, as, Sb; X = Cl, Br, I): Crystal Structures and Host−Guest Interactions". European Journal of Inorganic Chemistry. 2002 (3): 547–553. doi:10.1002/1099-0682(200203)2002:3<547::AID-EJIC547>3.0.CO;2-N.
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