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Crystal engineering

An example of crystal engineering using hydrogen bonding reported by Wuest and coworkers in J. Am. Chem. Soc., 2007, 4306–4322.

Crystal engineering is the design and synthesis of molecular solid-state structures with desired properties, based on an understanding and exploitation of intermolecular interactions. The two main strategies currently in use for crystal engineering are based on hydrogen bonding and coordination complexation. These may be understood with key concepts such as the supramolecular synthon and the secondary building unit.


  • History of term 1
  • Non-covalent control of structure 2
  • In two dimensions 3
  • Polymorphism 4
  • Specialized journals 5
  • See also 6
  • References 7
  • External links 8

History of term

The term ‘crystal engineering’ was first used in 1971 by Schmidt in connection with photodimerisation reactions in crystalline cinnamic acids. Since this initial use, the meaning of the term has broadened considerably to include many aspects of solid-state supramolecular chemistry. A useful modern definition is that provided by Gautam Radhakrishna Desiraju, who in 1988 defined crystal engineering as "the understanding of intermolecular interactions in the context of crystal packing and the utilization of such understanding in the design of new solids with desired physical and chemical properties." Since many of the bulk properties of molecular materials are dictated by the manner in which the molecules are ordered in the solid state, it is clear that an ability to control this ordering would afford control over these properties.

Non-covalent control of structure

Crystal engineering relies on ionic interactions can also be important. However, the two most commonly used strategies in crystal engineering exploit hydrogen bonds and coordination bonds.

Cambridge Structural Database (CSD) provides an excellent tool for assessing the efficiency of particular synthons. The supramolecular synthon approach has been successfully applied in the synthesis of one-dimensional tapes, two-dimensional sheets and three-dimensional structures. The CSD today contains atomic positional parameters for nearly 300 000 crystal structures, and this forms the basis for heuristic or synthon-based or "experimental" crystal engineering.

In two dimensions

The study and formation of 2D architectures (i.e., molecularly thick architectures) has rapidly emerged as a branch of engineering with molecules. The formation (often referred as molecular self-assembly depending on its deposition process) of such architectures lies in the use of solid interfaces to create adsorbed monolayers. Such monolayers may feature spatial crystallinity in an investigated time-window, thus the terminology of 2D crystal engineering is well suited. However the dynamic and wide range of monolayer morphologies ranging from amorphous to network structures have made of the term (2D) supramolecular engineering a more accurate term. Specifically, supramolecular engineering refers to "(The) design (of) molecular units in such way that a predictable structure is obtained" or as "the design, synthesis and self-assembly of well-defined molecular modules into tailor-made supramolecular architectures".


Polymorphism is the phenomenon wherein the same chemical compound exists in different crystal forms. In the initial days of crystal engineering, polymorphism was not properly understood and incompletely studied. Today, it is one of the most exciting branches of the subject partly because polymorphic forms of drugs may be entitled to independent patent protection if they show new and improved properties over the known crystal forms. With the growing importance of generic drugs, the importance of crystal engineering to the pharmaceutical industry is expected to grow exponentially.[1]

Specialized journals

Crystal engineering is a rapidly expanding discipline as revealed by the recent appearance of several international scientific journals in which the topic plays a major role. These include CrystEngComm from the Royal Society of Chemistry and Crystal Growth & Design from the American Chemical Society.

See also


  1. ^ Braga D et al Crystal Polymorphism and Multiple Crystal Forms Struct Bond (2009) 132: 25–50. DOI:10.1007/430 2008 7
  1. ^ G. M. J. Schmidt, Pure Appl. Chem., 1971, (27), 647
  2. ^ G. R. Desiraju, Crystal Engineering: The design of Organic Solids, Elsevier, 1989, Amsterdam
  3. ^ Venkat R. Thalladi, B. Satish Goud, Vanessa J. Hoy, Frank H. Allen, Judith A. K. Howard and Gautam R. Desiraju, Chemical Communications, 1996, 401–402 Abstract
  4. ^ J. V. Barth, G. Constantini, K. Kern, Engineering atomic and molecular nanostructures at surfaces, 'Nature, 2005, (437), 671–679.
  5. ^ C.-A. Palma, M. Bonini, T. Breiner, P. Samori, Supramolecular Crystal Engineering at the Solid–Liquid Interface from First Principles: Toward Unraveling the Thermodynamics of 2D Self‐Assembly, Advanced Materials, 2009, (21), 1383–1386 doi:10.1002/adma.200802068
  6. ^ J. A. A. W. Elemans, S.B. Lei S. De Feyter, Molecular and Supramolecular Networks on Surfaces: From Two-Dimensional Crystal Engineering to Reactivity Angewandte Chemie Int. Ed., 2009, (48), 7298–7332 doi:10.1002/anie.200806339
  7. ^ J. Simon, P. Bassoul, Design of molecular materials: supramolecular engineering, 2000 Wiley-VCH
  8. ^ A. Ciesielski, C.-A. Palma, M. Bonini, P. Samori, Towards Supramolecular Engineering of Functional Nanomaterials: Pre-Programming Multi-Component 2D Self-Assembly at Solid-Liquid Interfaces, Advanced Materials, 2010, (22), 3506–3520 doi:10.1002/adma.201001582

External links

  • Crystal Growth and Design
  • CrystEngComm
  • Cambridge Structural Database
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