赤木奈香美是一位来自日本的艺术家，她将动态的实时油漆、墨水和其他液体的流动作为其作品的核心。她使用各种颜色，鼓励液体流动和混合，创造出华丽而复杂的图案，这些图案会转化成意想不到的形状和色调。她还进行公共“活绘画”表演，将她的作品投射到大型表面上，并伴以音乐。观众看到场地墙壁上覆盖着彩色形状，这些形状源于她干预的自然过程。这些形状看起来是抽象的，但它们的变化通常类似于运动中的生物。

🎨 赤木奈香美是一位日本艺术家，她将动态的实时油漆、墨水和其他液体的流动作为其作品的核心。她使用各种颜色，鼓励液体流动和混合，创造出华丽而复杂的图案，这些图案会转化成意想不到的形状和色调。

🎤 她还进行公共“活绘画”表演，将她的作品投射到大型表面上，并伴以音乐。观众看到场地墙壁上覆盖着彩色形状，这些形状源于她干预的自然过程。这些形状看起来是抽象的，但它们的变化通常类似于运动中的生物。

🧪 赤木奈香美在作品中融入了科学元素，她研究了液体的行为，并利用了诸如铁磁流体等材料，这些材料最初是由NASA工程师为了在微重力环境下泵送液体火箭燃料而发明的。

🌳 赤木奈香美还与材料科学家合作，分析了树枝状图案的形成过程，并将其与流体的粘度和表面张力之间的相互作用联系起来。

🖼️ 她的作品也具有深刻的意义，例如，她作品中出现的泡沫与西方艺术中出现的“虚荣”传统有关。

🚀 赤木奈香美表示，她希望继续学习构成这个世界物理学和科学知识，并用视觉表达来表达“世界是美丽的”。

Any artist who paints is intuitively an expert in empirical fluid mechanics, manipulating liquid and pigment for aesthetic effect. The paint is usually brushed onto a surface material, although it can also be splattered onto a horizontal canvas in a technique made famous by Jackson Pollock or even layered on with a palette knife, as in the works of Paul Cezanne or Henri Matisse. But however the paint is delivered, once it dries, the result is always a fixed, static image.

Japanese artist Akiko Nakayama is different. Based in Tokyo, she makes the dynamic real-time flow of paint, ink and other liquids the centre of her work. Using a variety of colours, she encourages the fluids to move and mix, creating gorgeous, intricate patterns that transmute into unexpected forms and shades.

What also sets Nakayama apart is that she doesn’t work in private. Instead, she performs public “Alive painting” sessions, projecting her creations onto large surfaces, to the accompaniment of music. Audiences see the walls of the venue covered with coloured shapes that arise from natural processes modified by her intervention. The forms look abstract, but in their mutations often resemble living creatures in motion.

Inspired by ink

Born in 1988, Nakayama was trained in conventional techniques of Eastern and Western painting, earning degrees in fine art from Tokyo Zokei University in 2012 and 2014. Her interest in dynamic art goes back to a childhood calligraphy class, where she found herself enthralled by the beauty of the ink flowing in the water while washing her brush.

“It was more beautiful than the characters [I had written],” she recalls, finding herself “fascinated by the freedom of the ink”. Later, while learning to draw, she always preferred to capture a “moment of time” in her sketches. Eventually, Nakayama taught herself how to make patterns from moving fluids, motivated by Johann Wolfgang von Goethe’s treatise Theory of Colours (1810).

Best known as a writer, Goethe also took a keen interest in science and his book critiques Isaac Newton’s work on the physical properties of light. Goethe instead offered his own more subjective insights into his experiments with colour and the beauty they produce. Despite its flaws as a physical theory of light, reading the book encouraged Nakayama to develop methods to pour and agitate various paints in Petri dishes, and to project the results in real time using a camera designed for close-up viewing.

She started learning about liquids, reading research papers and even began examining the behaviour of water droplets under strobe lights. Nakayama also looked into studies of zero gravity on liquids by JAXA, the Japanese space agency. After finding a 10 ml sample of ferrofluid – a nanoscale ferromagnetic colloidal liquid – in a student science kit, she started using the material in her presentations, manipulating it with a small, permanent magnet.

Nakayama’s art has an unexpected link with space science because ferrofluids were invented in 1963 by NASA engineer Steve Papell, who sought a way to pump liquid rocket fuel in microgravity environments. By putting tiny iron oxide particles into the fuel, he found that the liquid could be drawn into the rocket engine by an electromagnet. Ferrofluids were never used by NASA, but they have many applications in industry, medicine and consumer products.

Secret science of painting

Having presented dozens of live performances, exhibitions and commissioned works in Japan and internationally over the last decade, other scientific connections have emerged for Nakayama. She has, for example, mixed acrylic ink with alcohol, dropping the fluid onto a thin layer of acrylic paint to create wonderfully intricate branched, tree-like dendritic forms.

In 2023 her painting caught the attention of materials scientists San To Chan and Eliot Fried at the Okinawa Institute of Science and Technology in Japan. They ended up working with Nakayama to analyse dendritic spreading in terms of the interplay of the different viscosities and surface tensions of the fluids (figure 1).

Chan and Fried published their findings, concluding that the structures have a fractal dimension of 1.68, which is characteristic of “diffusion-limited aggregation” – a process that involves particles clustering together as they diffuse through a medium (PNAS Nexus 3 59).

The two researchers also investigated the liquid parameters so that an experimentalist or artist could tune the arrangement to vary the dendritic results. Nakayama calls this result a “map” that allows her to purposefully create varied artistic patterns rather than “going on an adventure blindly”. Chan and Fried have even drawn up a list of practical instructions so that anyone inclined can make their own dendritic paintings at home.

Another researcher who has also delved into the connection between fluid dynamics and art is Roberto Zenit, a mechanical engineer at Brown University in the US. Zenit has shown that Jackson Pollock created his famous abstract compositions by carefully controlling the motion of viscous filaments (Phys. Rev. Fluids 4 110507). Pollock also avoided hydrodynamic instabilities that would have otherwise made the paint break up before it hit the canvas (PLOS One 14 e0223706).

Deeper meanings

Although Nakayama likes to explore the science behind her artworks, she has not lost sight of the deeper meanings in art. She told me, for example, that the bubbles that sometimes arise as she creates liquid shapes have a connection with the so-called “Vanitas” tradition in art that emerged in western Europe in the 16th and 17th centuries.

Derived from the Latin word for “vanity”, this kind of art was not about having an over-inflated belief in oneself as the word might suggest. Instead, these still-life paintings, largely by Dutch artists, would often have symbols and images that indicate the transience and fragility of life, such as snuffed-out candles with wisps of smoke, or fragile soap bubbles blown from a pipe.

The real bubbles in Nakayama’s artworks always stay spherical thanks to their strong surface tension, thereby displaying – in her mind – a human-like mixture of strength and vulnerability. It’s not quite the same as the fragility of the Vanitas paintings, but for Nakayama – who acknowledges that she’s not a scientist – her works are all about creating “a visual conversation between an artist and science”.

Asked about her future directions in art, however, Nakayama’s response makes immediate sense to any scientist. “Finding universal forms of natural phenomena in paintings is a joy and discovery for me,” she says. “I would be happy to continue to learn about the physics and science that make up this world, and to use visual expression to say ‘the world is beautiful’.”

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