Chemobrionics: From Self-Assembled Material Architectures to the Origin of Life

被引:42
作者
Cardoso, Silvana S. S. [1 ]
Cartwright, Julyan H. E. [2 ,3 ]
Cejkova, Jitka [4 ]
Cronin, Leroy [5 ]
De Wit, Anne [6 ]
Giannerini, Simone [7 ]
Horvath, Dezso [8 ]
Rodrigues, Alirio [9 ]
Russell, Michael J. [10 ]
Sainz-Diaz, C. Ignacio [2 ]
Toth, Agota [11 ]
机构
[1] Univ Cambridge, Dept Chem Engn & Biotechnol, Cambridge, England
[2] Univ Granada, CSIC, Inst Andaluz Ciencias Tierra, Granada, Spain
[3] Inst Carlos I Fis Teor & Comp, Granada, Spain
[4] Univ Chem & Technol Prague, Dept Chem Engn, Prague, Czech Republic
[5] Univ Glasgow, Sch Chem, Glasgow, Lanark, Scotland
[6] Univ Libre Bruxelles ULB, Nonlinear Phys Chem Unit, Brussels, Belgium
[7] Univ Bologna, Dipartimento Sci Stat Paolo Fortunati, Bologna, Italy
[8] Univ Szeged, Dept Appl & Environm Chem, Szeged, Hungary
[9] Univ Porto, Dept Chem Engn, Porto, Portugal
[10] Univ Torino, Dipartimento Chim, Turin, Italy
[11] Univ Szeged, Dept Phys Chem & Mat Sci, Szeged, Hungary
来源
ARTIFICIAL LIFE | 2020年 / 26卷 / 03期
基金
英国工程与自然科学研究理事会;
关键词
Chemical garden; chemobrionics; origin of life; biomimetics; submarine alkaline vent theory; CHEMICAL GARDENS; PRECIPITATION; GROWTH; EMERGENCE; PHOSPHATE; REDOX; TUBES;
D O I
10.1162/artl_a_00323
中图分类号
TP18 [人工智能理论];
学科分类号
081104 ; 0812 ; 0835 ; 1405 ;
摘要
Self-organizing precipitation processes, such as chemical gardens forming biomimetic micro- and nanotubular forms, have the potential to show us new fundamental science to explore, quantify, and understand nonequilibrium physicochemical systems, and shed light on the conditions for life's emergence. The physics and chemistry of these phenomena, due to the assembly of material architectures under a flux of ions, and their exploitation in applications, have recently been termed chemobrionics. Advances in understanding in this area require a combination of expertise in physics, chemistry, mathematical modeling, biology, and nanoengineering, as well as in complex systems and nonlinear and materials sciences, giving rise to this new synergistic discipline of chemobrionics.
引用
收藏
页码:315 / 326
页数:12
相关论文
共 48 条
  • [31] Development of a Minimal Photosystem for Hydrogen Production in Inorganic Chemical Cells
    Nakanishi, Keita
    Cooper, Geoffrey J. T.
    Points, Laurie J.
    Bloor, Leanne G.
    Ohba, Masaaki
    Cronin, Leroy
    [J]. ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2018, 57 (40) : 13066 - 13070
  • [32] Neves J., 2019, TECHNICAL REPORT
  • [33] The Generation of an Organic Inverted Chemical Garden
    Pampalakis, Georgios
    [J]. CHEMISTRY-A EUROPEAN JOURNAL, 2016, 22 (20) : 6779 - 6782
  • [34] Pressure oscillations in a chemical garden
    Pantaleone, J.
    Toth, A.
    Horvath, D.
    RoseFigura, L.
    Morgan, W.
    Maselko, J.
    [J]. PHYSICAL REVIEW E, 2009, 79 (05):
  • [35] An all-inorganic polyoxometalate-polyoxocation chemical garden
    Points, Laurie J.
    Cooper, Geoffrey J. T.
    Dolbecq, Anne
    Mialane, Pierre
    Cronin, Leroy
    [J]. CHEMICAL COMMUNICATIONS, 2016, 52 (09) : 1911 - 1914
  • [36] Peristalticity-driven banded chemical garden
    Popity-Toth, E.
    Schuszter, G.
    Horvath, D.
    Toth, A.
    [J]. JOURNAL OF CHEMICAL PHYSICS, 2018, 148 (18)
  • [37] Osmotic contribution to the flow-driven tube formation of copper-phosphate and copper-silicate chemical gardens
    Rauscher, Evelin
    Schuszter, Gabor
    Bohner, Biborka
    Toth, Agota
    Horvath, Dezso
    [J]. PHYSICAL CHEMISTRY CHEMICAL PHYSICS, 2018, 20 (08) : 5766 - 5770
  • [38] First Life
    Russell, M
    [J]. AMERICAN SCIENTIST, 2006, 94 (01) : 32 - 39
  • [39] The emergence of life from iron monosulphide bubbles at a submarine hydrothermal redox and pH front
    Russell, MJ
    Hall, AJ
    [J]. JOURNAL OF THE GEOLOGICAL SOCIETY, 1997, 154 : 377 - 402
  • [40] Calcium Carbonate Mineralization in a Confined Geometry
    Schuszter, Gabor
    Brau, Fabian
    De Wit, A.
    [J]. ENVIRONMENTAL SCIENCE & TECHNOLOGY LETTERS, 2016, 3 (04): : 156 - 159
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