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Vol 231
Pages:
287
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RUS ENG
Metallurgy and concentration

Development of research of low-dimension metal-containing systems from P.P. Weymarn to our days

Authors:
I. V. Pleskunov1
A. G. Syrkov2
About authors
  • 1 — Representative office of IMC Montan Company in the Republic of Belarus
  • 2 — Saint-Petersburg Mining University
Date submitted:
2018-01-14
Date accepted:
2018-03-08
Date published:
2018-06-25

Abstract

The article analyzes main laws discovered by P.P.Weymarn (1879-1935) during his work at the Saint-Petersburg Mining University, they are connected with obtaining metal-containing disperse substances with nanometer particle size. It enlists priority papers in this field (1906-1915) and describes peculiarities of P.P.Weymarn scientific school which has several connections to modern research being conducted at the Saint-Petersburg Mining University in the field of «nanotechnology» as well as by foreign scientists. The paper reveals continuity in the field of several objects (disperse metals) and the methodology of studying the properties and stoichiometry of substances depending on dispersity. It provides information on achievements in synthesis of surface nanostructured metals and low-dimension forms of substances in various porous matrixes. Among the studies of the XXI century developing Weymarn’s ideas there can be noted solid-state hydride synthesis of metals, layering of different-sized molecules of ammonium compounds on metals (Al, Cu, Ni, Fe), as well as synthesis of metal nanostructures (Ag, Cu, Bi) using porous glass as a particle size stabilizing matrix. In the latter case, the dispersity of the metal increases while its melting point decreases.

10.25515/pmi.2018.3.287
Go to volume 231

References

  1. Веймарн П.П. К дисперсоидной химии хлорной меди в бензоле / П.П.Веймарн, И.Б.Каган // Записки Горного института. 1912. Т. 4. С. 75-95.
  2. Веймарн П.П. Новая систематика агрегатных состояний материи и основной закон дисперсоидологии // Записки Горного института. 1912. Т. 4. С. 126-143.
  3. Веймарн П.П. Об электропроводности металлов и их сплавов с точек зрения дисперсоидной химии // Записки Горного института. 1911. Т. 3. С. 349-353.
  4. Веймарн П.П. Простой общий метод получения любого тела в состоянии твердых коллоидных растворов любой степени дисперсности, начиная от молекулярной / П.П.Веймарн, И.Б.Каган // Записки Горного института. 1910. Т. 2. С. 398-399.
  5. Пак В.Н. Формирование и электрическая проводимость низкоразмерных структур меди в пористом стекле / В.Н.Пак, О.В.Голов // Журнал общей химии. 2015. Т. 85. № 5. С. 535-538.
  6. Пористое стекло в качестве реактора синтеза наночастиц висмута / В.Н.Пак, О.В.Голов, В.М.Грабов, В.М.Стожаров, Е.В.Демидов // Журнал общей химии. 2015. Т. 85. № 10. С. 1600-1604.
  7. Сырков А.Г. Исследования в области наноструктур и наноматериалов в СПГГИ (ТУ) / А.Г.Сырков, И.Н.Белоглазов // Цветные металлы. 2007. № 10. С. 91-94.
  8. Сырков А.Г. Международный семинар-симпозиум «Нанофизика и наноматериалы» // Конденсированные среды и межфазные границы. 2016. Т. 18. № 1. С. 161-167.
  9. Сырков А.Г. О приоритете Санкт-Петербургского горного университета в области науки о нанотехнологиях и наноматериалах // Записки Горного института. 2016. Т. 221. С. 730-736.
  10. Хисамутдинова Н.В. Химик Петр Петрович фон Веймарн в России и Японии // Вестник Дальневосточного отделения Российской академии наук. 2011. № 5. С. 134-141.
  11. Ag core-satellite nanostructures with a tunable silica-spaced nanogap for surface enhanced Raman scattering / Z.Rong, R.Xiao, C.Wang, D.Wang, S.Wang // Langmuir. 2015. Vol. 31. N. 29. P. 8129-8137.
  12. Bazhin V.Yu. Strengthening and metallization of layered graphite materials surface by lithium ions during electrochemical interaction / V.Yu.Bazhin, A.V.Saitov // Smart Nanocomposites. 2016. Vol. 7. N 2. P. 229-232.
  13. Bogdanov S.P. Iodide transport-method of synthesis of inorganic materials (Book chapter). Synthesis, characterization and modeling of nano-sized structures. New York: Nova Science Publishers, Inc., 2017. 175 p.
  14. Electrocatalytic oxygen reduction performance of silver nanoparticle decorated electrochemically exfoliated graphene / J.H.Lopes, S.Ye, J.T.Gostick, J.E.Barralet, G.Merle // Langmuir. 2015. Vol. 31. P. 9718-9727.
  15. Hristyuk N.A. The use of Iodine transport for cromizing steel with different carbon content / N.A.Hristyuk, S.P.Bogdanov // Smart Nanocomposites. 2016. Vol. 7. N 2. P. 189-190.
  16. Kashima K. En Eminent Chemist // Industrial and Engineering Chemistry. 1924. Vol. 16. P. 540-543.
  17. Kovalchuk A.A. Processing of carbon nanoparticles by sublimation / A.A.Kovalchuk, A.A.Prikhodko, N.N.Rozhkova // Smart Nanocomposites. 2016. Vol. 7. N 2. P. 259-260.
  18. Modelling the behavior of carbon nanoparticles C44 when heated in an Argon Atmosphere. Computer experiment / N.M.Barbin, V.P.Dan, D.I.Terentiev, S.G.Alekseev // Smart Nanocomposites. 2016. Vol. 7. N 1. P. 1-8.
  19. Molecular layering of 2D films and superlattices / R.A.Bisengaliev, B.V.Novikov, V.B.Aleskovskii, V.E.Drozd // Physics of the Solid State. 1998. Vol. 40. N 5. P. 754-755.
  20. Nakano M. Thermal decomposition of silver acetate: physico-geometrical kinetic features and formation of silver nanoparticles / M.Nakano, T.Fujiwara, W.Koga // Journal of Physical Chemistry C. 2016. Vol. 120. P. 8841-8854.
  21. Pak V.N. Evolution of Copper (II) Oxide Nanostructures in Porous Glass Matrix / V.N.Pak, O.V.Golov, D.V.Formus // Smart Nanocomposites. 2016. Vol. 7. N 1. P. 27-31.
  22. Pak V.N. Porous Glass and Nanostructured Materials / V.N.Pak, Yu.Yu.Gavronskaya, T.M.Burkat. New York: Nova Science Publishers, Inc., 2015. 113 p.
  23. Rozhkova N.N. From grapheme fragments of shungite nanocarbon to graphite // Smart Nanocomposites. 2016. Vol. 7. N 2. P. 265-270.
  24. Saltykov S.N. The influence of low-carbonaceous steel structure in electrochemical and corrosion behavior / S.N.Saltykov, N.V.Tarasova, A.M.Khoviv // Smart Nanocomposites. 2016. Vol. 7. N 2. P. 233-238.
  25. Syrkov A.G. Development of solid state hydride synthesis of surface-nanostuctured disperse metals / A.G.Syrkov, V.R.Kabirov, V.S.Kavun // Smart Nanocomposites. 2016. Vol. 7. N 2. P. 121-126.
  26. Syrkov A.G. Surface-nanostructured metals and their tribochemical properties (Book chapter). Smart nanoobjects: from laboratory to industry. New York: Nova Science Publishers, Inc., 2013. 214 p.
  27. Syrkov A.G. Synergetic improvement of aluminium reactivity in the presence on the surface of quaternary ammonium compounds // Russian Journal of General Chemistry. 2013. Vol. 83. N 8. P. 1621-1622.
  28. Understanding the growth mechanisms of Ag nanoparticles controlled by plasmon-induced charge transfers in Ag-TiO2 films / Z.Liu, N.Destouches, G.Vitrant, Y.Lefkir et al. // Journal of Physical Chemistry C. 2015. Vol. 119. P. 9496-9505.
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Development of research of low-dimension metal-containing systems from P.P. Weymarn to our days

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