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The renaissance of continuum mechanics


Author(s):  Wei-qiu Chen

Affiliation(s):  . Department of Engineering Mechanics, Zhejiang University, Hangzhou 310027, China

Corresponding email(s):  chenwq@zju.edu.cn

Key Words:  Continuum mechanics, Quantum mechanics, Engineering, Current research activities, Renaissance


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Wei-qiu Chen. The renaissance of continuum mechanics[J]. Journal of Zhejiang University Science A,in press.Frontiers of Information Technology & Electronic Engineering,in press.https://doi.org/10.1631/jzus.A1400079

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Abstract: continuum mechanics, just as the name implies, deals with the mechanics problems of all continua, whose physical (or mechanical) properties are assumed to vary continuously in the spaces they occupy. continuum mechanics may be seen as the symbol of modern mechanics, which differs greatly from current physics, the two often being mixed up by people and even scientists. In this short paper, I will first try to give an illustration on the differences between (modern) mechanics and physics, in my personal view, and then focus on some important current research activities in continuum mechanics, attempting to identify its path to the near future. We can see that continuum mechanics, while having a dominating impact on engineering design in the 20th century, also plays a pivotal role in modern science, and is much closer to physics, chemistry, biology, etc. than ever before.

连续介质力学的复兴

概要:连续介质力学,正如其名称所喻示的,研究的是所有连续介质的力学问题。所谓连续介质,就是其宏观的物理或力学性质沿空间连续变化,而不必考虑各组成原子或分子的结构及其相互作用。连续介质力学可以看作是现代力学的标志,后者与现代物理学区别明显,但经常被大众甚至科学家所混淆。在此,首先从个人理解的角度阐述了现代力学与现代物理学的区别,特别指出现代力学与重大工程应用紧密相关,这从其新兴于二十世纪的三个分支学科——断裂力学、空气动力学和有限元的发展历史即可看出。然后,基于Web of Science的检索数据(见图1),清楚揭示了二十世纪五、六十年代是连续介质力学的形成期,七、八十年代是其平稳发展期,而从九十年代起至今就是其复兴期。最后,着重从三个方面展示了连续介质力学的复兴和新发展:在纳机电领域与量子力学的衔接,在能源等领域与化学的耦合,在生物学领域由生物力学向力生物学的转变。可以看到,正如其在二十世纪的工程设计中扮演了轴心角色一样,连续介质力学将通过学科交叉(与物理、化学、生物学、医学、信息科学、社会科学等)而在现代科学的版图中持续发挥重要作用。
关键词组:连续介质力学, 量子力学, 工程, 研究现状, 复兴

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

References

[1] Beyer,M.K, Clausen-Schaumann,H, 2005, Mechanochemistry: The mechanical activation of covalent bonds  Chemical Reviews, 105(8):2921-2948.


[2] Boldyrev,V.V, Tkčov,K, 2000, Mechanochemistry of solids: Past, present, and prospects  Journal of Materials Synthesis and Processing, 8(3-4):121-132.


[3] Bordag,M, Mohideen,U, Mostepanenko,V.M, 2001, New developments in the Casimir effect  Physics Reports, 353(1-3):1-205.


[4] Chen,C.Q, Shi,Y, Zhang,Y.S, 2006, Size dependence of Youngs modulus in ZnO nanowires  Physical Review Letters, 96(7):075505-.


[5] Chen,W.Q, 2011, Surface effect on Bleustein-Gulyaev wave in a piezoelectric half-space  Theoretical and Applied Mechanics Letters, 1(4):041001-.


[6] Cowin,S.C, 2004, Tissue growth and remodeling  Annual Review of Biomedical Engineering, 6(1):77-107.


[7] Cui,Z, Gao,F, Qu,J, 2012, A finite deformation stress-dependent chemical potential and its applications to lithium ion batteries  Journal of the Mechanics and Physics of Solids, 60(7):1280-1295.


[8] Duan,H.L, Wang,J, Karihaloo,B.L, 2008, Theory of elasticity at the nanoscale  Advances in Applied Mechanics, 42(1):1-68.

[9] Ekinci,K.L, Roukes,M.L, 2005, Nanoelectromechanical systems  Review of Scientific Instruments, 76(6):061101-.


[10] Epstein,M, 2010,    , ():-.


[11] Eringen,A.C, 1980, Mechanics of Continua. Robert E. Krieger Publishing Co.,Huntington, New York.

[12] Fish,J, 2006, Bridging the scales in nano engineering and science  Journal of Nanoparticle Research, 8(5):577-594.


[13] Freund,L.B, 2009, Characterizing the resistance generated by a molecular bond as it is forcibly separated  Proceedings of the National Academy of Sciences of the United States of America, 106(22):8818-8823.


[14] Fukada,E, 1968, Piezoelectricity in polymers and biological materials  Ultrasonics, 6(4):229-234.


[15] Fung,Y.C, 1990, Biomechanics: Motion, Flow, Stress and Growth. Springer,Berlin.


[16] Fung,Y.C, 1993, Biomechanics: Mechanical Properties of Living Tissues. Springer,Berlin.


[17] Fung,Y.C, 1996, Biomechanics: Circulation. Springer,Berlin.

[18] Gilman,J.J, 1996, Mechanochemistry  Science, 274(5284):65-.


[19] Girard,P.P, Cavalcanti-Adam,E.A, Kemkemer,R, 2007, Cellular chemomechanics at interfaces: Sensing, integration and response  Soft Matter, 3(3):307-326.


[20] Griffith,A.A, 1921, The phenomena of rupture and flow in solids  Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 221(582):163-198.


[21] Harik,V.M, 2001, Ranges of applicability for the continuum beam model in the mechanics of carbon nanotubes and nanorods  Solid State Communications, 120(7-8):331-335.


[22] Herglotz,G, 1911, ber die mechanik des deformierbaren krpers vom standpunkte der relativittstheorie  Annalen der Physik, 341(13):493-533.


[23] Hu,H.C, 1955, On some variational principles in the theory of elasticity and the theory of plasticity  Scientia Sinica, 4(1):33-54.

[24] Hu,L.B, Hueckel,T, 2007, Coupled chemo-mechanics of intergranular contact: Toward a three-scale mode  Computers and Geotechnics, 34(4):306-327.


[25] Huang,Z, Boulatov,R, 2011, Chemomechanics: Chemical kinetics for multiscale phenomena  Chemical Society Reviews, 40(5):2359-2384.


[26] Humphrey,J.D, 2003, Continuum biomechanics of soft biological tissues  Proceedings of the Royal Society of London A, 459(2029):3-46.


[27] Ingber,D.E, 2006, Cellular mechanotransduction: Putting all the pieces together again  The FASEB Journal, 20(7):811-827.


[28] Janmey,P.A, McCulloch,C.A, 2007, Cell mechanics: Integrating cell responses to mechanical stimuli  Annual Review of Biomedical Engineering, 9(1):1-34.


[29] Kim,D.H, Lu,N.S, Ma,R, 2011, Epidermal electronics  Science, 333(6044):838-843.


[30] Li,B, Cao,Y.P, Feng,X.Q, 2012, Mechanics of morphological instabilities and surface wrinkling in soft materials: A review  Soft Matter, 8(21):5728-5745.


[31] Liu,D.Y, Chen,W.Q, Zhang,C.Z, 2013, Improved beam theory for multilayer graphene nanoribbons with interlayer shear effect  Physics Letters A, 377(18):1297-1300.


[32] Liu,Y.M, Zhang,Y.H, Chow,M.J, 2012, Biological ferroelectricity uncovered in aortic walls by piezoresponse force microscopy  Physical Review Letters, 108(7):078103-.


[33] Maugin,G.A, 2013, Continuum Mechanics through the Twentieth Century. Springer,Berlin.


[34] Mller,I, 2007, A History of Thermodynamics. Springer,Berlin.

[35] Prandtl,L, 1904, ber Flssigkeitsbewegungen bei sehr kleiner Reibung  , Lecture on International Congress of Mathematicians, Heidelberg, p. -.

[36] Qian,D, Wagner,G.J, Liu,W.K, 2002, Mechanics of carbon nanotubes  Applied Mechanics Reviews, 55(6):495-533.


[37] Saha,R, Nix,W.D, 2002, Effects of the substrate on the determination of thin film mechanical properties by nanoindentation  Acta Materialia, 50(1):23-38.


[38] Schwab,K.C, Roukes,M.L, 2005, Putting mechanics into quantum mechanics  Physics Today, 58(7):36-42.


[39] Shenoy,V.B, 2005, Atomistic calculations of elastic properties of metallic fcc crystal surfaces  Physical Review B, 71(9):094104-.


[40] Shi,X.H, von dem Bussche,A, Hurt,R.H, 2011, Cell entry of one-dimensional nanomaterials occurs by tip recognition and rotation  Nature Nanotechnology, 6(6):714-719.


[41] Silling,S.A, Lehoucq,R.B, 2010, Peridynamic theory of solid mechanics  Advances in Applied Mechanics, 44(1):73-166.


[42] Skalak,R, Dasgupta,G, Moss,M, 1982, Analytical description of growth  Journal of Theoretical Biology, 94(3):555-577.


[43] Stoltz,J.F, Wang,X, 2002, From biomechanics to mechanobiology  Biorheology, 39(1):5-10.

[44] Taber,L, 1995, Biomechanics of growth, remodeling and morphogenesis  Applied Mechanics Reviews, 48(8):487-545.


[45] Tadmor,E.B, Phillips,R, Ortiz,M, 1996, Mixed atomistic and continuum models of deformation in solids  Langmuir, 12(19):4529-4534.


[46] Truesdell,C.A, Toupin,R.A, 1960, Bd. III/1 in Handbuch der Physik. Springer,Berlin.

[47] Truesdell,C.A, Noll,W, 1965, Bd. III/3 in Handbuch der Physik. Springer,Berlin.

[48] Tsien,H.S, 1953, Physical mechanics, a new field in engineering science  Journal of the American Rocket Society, 23(1):14-16.


[49] Turner,M.J, Clough,R.W, Martin,H.C, 1956, Stiffness and deflection analysis of complex structures  Journal of the Aeronautical Sciences, 25(9):805-823.


[50] Volokh,K.Y, 2013, Challenge of biomechanics  Molecular & Cellular Biomechanics, 10(2):107-135.

[51] Wang,Q, 2005, Wave propagation in carbon nanotubes via nonlocal continuum mechanics  Journal of Applied Physics, 98(12):124301-.


[52] Wilson,J.S, Virag,L, Di Achille,P, 2013, Bio-chemomechanics of intraluminal thrombus in abdominal aortic aneurysms  Journal of Biomechanical Engineering, 135(2):021011-.


[53] Wong,E.W, Sheehan,P.E, Lieber,C.M, 1997, Nanobeam mechanics: Elasticity, strength, and toughness of nanorods and nanotubes  Science, 277(5334):1971-.


[54] Xiao,X, Liu,P, Verbrugge,M.W, 2011, Improved cycling stability of silicon thin film electrodes through patterning for high energy density lithium batteries  Journal of Power Sources, 196(3):1409-1416.


[55] Yakobson,B.I, Brabec,C.J, Bernholc,J, 1996, Nanomechanics of carbon tubes: Instabilities beyond linear response  Physical Review Letters, 76(14):2511-2514.


[56] Young,R.J, Kinlocha,I.A, Gong,L, 2012, The mechanics of graphene nanocomposites: A review  Composites Science and Technology, 72(12):1459-1476.


[57] Zhang,P, Huang,Y, Geubelle,P.H, 2002, The elastic modulus of single-wall carbon nanotubes: a continuum analysis incorporating interatomic potentials  International Journal of Solids and Structures, 39(13-14):3893-3906.


[58] Zhang,W.L, Lin,Y, Qian,J, 2013, Tuning molecular adhesion via material anisotropy  Advanced Functional Materials, 23(37):4729-4738.


[59] Zhang,X, Jiao,K, Sharma,P, 2006, An atomistic and non-classical continuum field theoretic perspective of elastic interactions between defects (force dipoles) of various symmetries and application to graphene  Journal of the Mechanics and Physics of Solids, 54(11):2304-2329.


[60] Zhao,K.J, Pharr,M, Vlassak,J.J, 2011, Inelastic hosts as electrodes for high-capacity lithium-ion batteries  Journal of Applied Physics, 109(1):016110-.



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