13 February 2021 | New Scientist | 19SOME Chinese noblemen were
using cosmetic face cream
2700 years ago. Archaeologists
have found an ornate bronze jar
containing the remains of a face
cream, which was made from a
mixture of animal fat and a rare
substance called moonmilk that
is found in caves.
The discovery is the earliest
evidence of a Chinese man using
cosmetics, although Chinese
women did so earlier than this.
In 2017 and 2018, Yimin Yang
at the University of the Chinese
Academy of Sciences in Beijing
and his colleagues excavated a site
called Liujiawa in northern China.It dates from the Spring and Autumn
period (771 to 476 BC) of Chinese
history, centuries before the country
was first unified by the Qin dynasty.
During this period, Liujiawa was the
capital city of a state called Rui.
In the 2700-year-old tomb of a
nobleman, the researchers found abronze jar. Inside were lumps of a
soft, yellow-white material. They
immediately suspected that this
was cosmetic cream. Chemical
analyses later confirmed this and
revealed two main ingredients.
The first was animal fat,
which came from a ruminantanimal that had been fed lots
of grass-like plants.
The second ingredient was a
form of watery calcium carbonate
called moonmilk. It is a soft, white,
creamy substance that forms inside
caves. The cream would have made
the man’s face white, says Yang
(Archaeometry, doi.org/ftvg).
The face cream is the earliest
example associated with a Chinese
man. However, evidence of Chinese
women using cosmetics goes back
further. In 2016, Yang’s team
studied red cosmetic sticks from
1980 to 1450 BC, which were
buried with women in China. ❚UNRAVELLING knots just got
easier. One of the biggest problems
in the mathematical study of
knots is recognising the difference
between an actual knot and a piece
of string that can be untangled
into a single loop. A new algorithm
can find this “unknot” far faster
than any previous one can.
Mathematically, the definition
of a knot is a closed curve – like a
piece of string with the ends tied
together – that can’t be untangled
into a simple loop. Anything that
can be untangled into a simple
loop, no matter how complicated
or tangled it appears at first, is
called the unknot. “Just like zero
isn’t a number, the unknot isn’t
a knot,” says Mark Dennis at the
University of Birmingham, UK.
Mathematicians have been
working on algorithms to tell
whether a given knot is actually
the unknot for about 100 years,
and pioneering mathematicianand computer scientist Alan
Turing even wrote about it in his
final published paper in 1954.
Now, Marc Lackenby at the
University of Oxford has come up
with an algorithm that can make
this distinction far faster, which he
presented at a recent seminar at
the University of California, Davis.
“Although finding the unknot
seems quite intuitive because
throughout our lives we areuntangling wires and pieces
of string and headphone cords
and things, it turns out that
mathematically it touches on
much more abstract areas of
maths, questions to do with
geometry in higher-dimensional
spaces,” says Dennis. “There areknot diagrams that you need to
make more complicated before
you can simplify them down,” he
says, and computers aren’t great
at recognising when to do so.
The level of complexity of
a given knot is defined by the
number of crossings it contains.
A crossing is the spot at which one
part of the string passes over or
under another part, and any tangle
that can be manipulated so that
it has no crossings is the unknot.
“You might expect it not to be a
difficult problem, and the issue is
that when you start to think about
how a computer would actually
decide such a question, you realise
that you don’t have the right tools
to even come to a decisive answer
about whether a thing is or isn’t
knotted,” says Lackenby.
Other mathematicians have
designed algorithms that can find
whether a given tangle is knotted
or not, but every added crossingdoubles the time needed to solve
the problem. Lackenby’s algorithm
can figure it out faster than that.
His work relies on defining each
knot as representing the edge
of a three-dimensional shape.
“You can imagine a round
unknot just lying in the plane,
well that’s the boundary of a disc,”
says Lackenby. “Or you can imagine
taking a strip of paper and gluing it
together in a loop with some little
twists in it, and the boundary of
that strip of paper will be a knot.”
If the shape corresponding
to a knot can be manipulated
and simplified into a disc, that
knot is actually the unknot.
Determining whether a knot
is the unknot has far-ranging
applications, from studying
how DNA is tangled up within
cells to understanding the loops
of plasma that make up stars,
so a faster algorithm could be
enormously helpful. ❚MathsLeah CraneDR.^ BI
N^ HAN,^ UNIVERS
ITYOFCHINESE
ACAD
EMY^ OF^ SCIENCES^CH
INANews
“ There are knot diagrams
that you need to make
more complicated before
you can simplify them”ArchaeologyMichael MarshallBreakthrough for 100-year-old
knotty maths problem
The 2700-year-old bronze
jar (left) and the face cream it
contained (right) were found
in northern China1 cm 1 cmAncient face cream
was made from cave
‘milk’ and animal fat