These false-color SEM images reveal microscopic flower structures created by manipulating a chemical gradient to control crystalline self-assembly. (Image courtesy of Wim L. Noorduin.)

Cambridge, Mass. - May 16, 2013 - "Spring is like a perhaps hand," wrote the poet E. E. Cummings: "carefully / moving a perhaps / fraction of flower here placing / an inch of air there... / without breaking anything."

With the hand of nature trained on a beaker of chemical fluid, the most delicate flower structures have been formed in a Harvard laboratory—and not at the scale of inches, but microns.

These minuscule sculptures, curved and delicate, don't resemble the cubic or jagged forms normally associated with crystals, though that's what they are. Rather, fields of carnations and marigolds seem to bloom from the surface of a submerged glass slide, assembling themselves a molecule at a time.

By simply manipulating chemical gradients in a beaker of fluid, Wim L. Noorduin, a postdoctoral fellow at the Harvard School of Engineering and Applied Sciences (SEAS) and lead author of a paper appearing on the cover of the May 17 issue of Science, has found that he can control the growth behavior of these crystals to create precisely tailored structures.

"For at least 200 years, people have been intrigued by how complex shapes could have evolved in nature. This work helps to demonstrate what’s possible just through environmental, chemical changes," says Noorduin.

The precipitation of the crystals depends on a reaction of compounds that are diffusing through a liquid solution. The crystals grow toward or away from certain chemical gradients as the pH of the reaction shifts back and forth. The conditions of the reaction dictate whether the structure resembles broad, radiating leaves, a thin stem, or a rosette of petals.

It is not unusual for chemical gradients to influence growth in nature; for example, delicately curved marine shells form from calcium carbonate under water, and gradients of signaling molecules in a human embryo help set up the plan for the body. Similarly, Harvard biologist Howard Berg has shown that bacteria living in colonies can sense and react to plumes of chemicals from one another, which causes them to grow, as a colony, into intricate geometric patterns.

Replicating this type of effect in the laboratory was a matter of identifying a suitable chemical reaction and testing, again and again, how variables like the pH, temperature, and exposure to air might affect the nanoscale structures.

The project fits right in with the work of Joanna Aizenberg, an expert in biologically inspired materials science, biomineralization, and self-assembly, and principal investigator for this research.

Aizenberg is the Amy Smith Berylson Professor of Materials Science at Harvard SEAS, Professor of Chemistry and Chemical Biology in the Harvard Department of Chemistry and Chemical Biology, and a Core Faculty Member of the Wyss Institute for Biologically Inspired Engineering at Harvard.

Her recent work has included the invention of an extremely slippery material, inspired by the pitcher plant, and the discovery of how bacteria use their flagella to cling to the surfaces of medical implants.

"Our approach is to study biological systems, to think what they can do that we can’t, and then to use these approaches to optimize existing technologies or create new ones," says Aizenberg. "Our vision really is to build as organisms do."

To create the flower structures, Noorduin and his colleagues dissolve barium chloride (a salt) and sodium silicate (also known as waterglass) into a beaker of water. Carbon dioxide from air naturally dissolves in the water, setting off a reaction which precipitates barium carbonate crystals. As a byproduct, it also lowers the pH of the solution immediately surrounding the crystals, which then triggers a reaction with the dissolved waterglass. This second reaction adds a layer of silica to the growing structures, uses up the acid from the solution, and allows the formation of barium carbonate crystals to continue.

"You can really collaborate with the self-assembly process," says Noorduin. "The precipitation happens spontaneously, but if you want to change something then you can just manipulate the conditions of the reaction and sculpt the forms while they're growing."

Increasing the concentration of carbon dioxide, for instance, helps to create 'broad-leafed' structures. Reversing the pH gradient at the right moment can create curved, ruffled structures.

Noorduin and his colleagues have grown the crystals on glass slides and metal blades; they've even grown a field of flowers in front of President Lincoln's seat on a one-cent coin.

"When you look through the electron microscope, it really feels a bit like you’re diving in the ocean, seeing huge fields of coral and sponges," describes Noorduin. "Sometimes I forget to take images because it's so nice to explore."

Image courtesy of Wim L. Noorduin.

In addition to her roles at Harvard SEAS, the Department of Chemistry and Chemical Biology, and the Wyss Institute, Joanna Aizenberg is Director of the Kavli Institute for Bionano Science and Technology at Harvard and Director of the Science Program at the Radcliffe Institute for Advanced Study.

Coauthors included Alison Grinthal, a research scientist at Harvard SEAS, and L. Mahadevan, who is the Lola England de Valpine Professor of Applied Mathematics at SEAS, Professor of Organismic and Evolutionary Biology and of Physics, and a Core Faculty Member at the Wyss Institute.

The project was supported by National Science Foundation grants to the Harvard Materials Research Science and Engineering Center (DMR-0820484) and the Harvard Center for Nanoscale Systems (ECS-0335765); and by the Netherlands Organization for Scientific Research.

He was among eight Foreign Members and 44 new Fellows welcomed on May 3 by the United Kingdom's elite national academy.

Hutchinson is a seminal scholar in the field of solid mechanics and materials engineering, and is more highly cited than any other researcher in this area.

Hutchinson studied engineering mechanics as an undergraduate at Lehigh University. After earning his Ph.D. in mechanical engineering at Harvard in 1963, he spent a year in Denmark before returning to join the Harvard faculty, where he very soon made dramatic contributions to the study of buckling in elastic structures.

Over a 50-year career at Harvard, he has been one of the major developers of nonlinear fracture mechanics. He has made groundbreaking contributions in micromechanics, including plasticity of polycrystals, cracking of fiber-reinforced ceramics, and delamination of thermal barrier coatings.

For example, ceramic thermal barrier coatings (TBCs) are widely used in aircraft and power generation turbines to shield the engine blades and other metal components from high temperatures. However, the use of TBCs contributes to an industry trend toward engines that operate at even higher temperatures, which threatens the durability of the coatings.

Concern for plastic deformation at the scale of microns led to his publications in strain-gradient plasticity, which have sparked a world-wide explosion in research on this topic.

“Science helps us to better understand ourselves and the natural world around us and has a huge role to play in future economic prosperity and the health of our planet and its 7 billion people," said Sir Paul Nurse, President of the Royal Society, in a press release. "In the coming decades we are going to find ourselves more and more dependent on the solutions."

"These scientists who have been elected to the Fellowship of the Royal Society have already contributed much to the scientific endeavour following in the footsteps of pioneers such as Newton, Darwin and Einstein," Nurse added, "and it gives me great pleasure to welcome them into our ranks.”

About the Royal Society

The Royal Society is a self-governing Fellowship of many of the world’s most distinguished scientists drawn from all areas of science, engineering, and medicine. The Society’s fundamental purpose, reflected in its founding Charters of the 1660s, is to recognise, promote, and support excellence in science and to encourage the development and use of science for the benefit of humanity. The Society has played a part in some of the most fundamental, significant, and life-changing discoveries in scientific history and Royal Society scientists continue to make outstanding contributions to science in many research areas.

Adapted from materials provided by the Royal Society.

The prizes are awarded only once every two years, and recognize the very highest level of achievements in applied and fundamental research in optical physics. The awards will be presented in a special plenary ceremony on May 14, 2013, during the Conference on Lasers and Electro-Optics (CLEO) Europe, held during the World of Photonics Congress in Munich, Germany.

Capasso joined Harvard University in 2003 after 27 years at Bell Labs where he was Member of Technical Staff, Department Head and Vice President for Physical Research.

In announcing the 2013 Prize for Applied Aspects of Quantum Electronics and Optics, EPS cited Capasso's “seminal contributions to the invention and demonstration of the quantum cascade laser."

His research has also focused on nanoscale science and technology encompassing a broad range of topics including band-structure engineering of semiconductor nanostructures and quantum devices, the investigation of attractive and repulsive Casimir forces, plasmonics, and flat optics based on metasurfaces.

He is a member of the National Academy of Sciences, the National Academy of Engineering and a fellow of the American Academy of Arts and Sciences.

His awards include the IEEE Sarnoff Award in Electronics (1991), the Materials Research Society Medal (1995), the Wetherill Medal of the Franklin Institute (1997), the Rank Prize in Optoelectronics (1998), the Optical Society Wood Prize (2001), the IEEE Edison Medal (2004), the APS Arthur Schawlow Prize in Laser Science (2004), the King Faisal Prize (2005), the Berthold Leibinger Zukunft Prize (2010), the Julius Springer Prize in Applied Physics (2010), the Jan Czochralski Award for lifetime achievements in Materials Science (2011), and the SPIE Gold Medal (2013).

In addition to the prize for "applied aspects," the EPS awards a second prize for the "fundamental aspects" of quantum electronics and optics. Maciej Lewenstein, ICREA Research Professor and Head of the Quantum Optics Theory Group at The Institute of Photonic Sciences (ICFO) in Barcelona, Spain, will receive the fundamental prize for his "outstanding contributions to several areas of theoretical quantum optics and to the use of quantum gases for quantum information and to attosecond optics."

About the European Physical Society - Quantum Electronics and Optics Division

The European Physical Society provides an international forum for physicists and acts as a federation of national physical societies. Founded in 1968, the EPS plays a leading role in both scientific and policy activities within the community of European physicists. The Quantum Electronics and Optics Division (QEOD) of the EPS acts as a focal point for European research in optics and photonics through its wide range of strategic activities, sponsorship and conference organisation.  In addition to the major awards described above, it also awards Young Researcher (Fresnel) and Ph.D. Student Prizes.