The structure of a flower, termed its
morphology, can be considered in two parts: the vegetative part, consisting of non-reproductive structures such as
petals; and the reproductive or sexual parts. A stereotypical, or complete, flower is made up of four kinds of structures arranged in sets called whorls. They grow around the tip of a short stalk or axis, called a
receptacle. The four main whorls (starting from the base of the flower and working upwards) are the
calyx,
petals,
androecium, and
gynoecium.
Vegetative The non-reproductive or vegetative part of the flower, known collectively as the
perianth, consists of calyx (the modified outer leaves), and the petals. The receptacle is the thickened part of the flower stalk, called the pedicel, which supports all of the other flower structures.
Calyx The
sepals, collectively called the calyx, are modified leaves that occur on the outermost whorl of the flower. They are leaf-like, in that they have a broad base,
pores,
green pigment, and may have analogous
outgrowths from the stem. Sepals are often waxy, tough, and grow quickly to protect the flower as it develops. Although they sometimes
fall off at maturity, sepals more commonly persist to protect the fruit and aid in its dispersal. The sepals in some flowers may be partially or completely
fused together.
Petals The
petals, collectively called the corolla, are almost or completely fibreless leaf-like structures that form the innermost whorl of the perianth. They are often delicate and thin and are usually coloured, shaped, or scented, to encourage and facilitate pollination. The petals may be
fused together. Petals often feature
UV patterns invisible to humans but visible to pollinators. In some flowers, petals and sepals are
indistinguishable from one another.
Reproductive All flowering plants are
heterosporous, that is, every individual plant produces two types of
spores. Spores are formed from
mature plants, which contain
two sets of chromosomes, and are divided into microspores and megaspores—the precursors to pollen and embryo sacs respectively. Pollen and embryo sacs are the male and female
gametophytes, sex cell-producing structures, and contain just one set of chromosomes. Microspores are produced by
meiosis inside anthers, the male part of flowers, and megaspores are produced inside
ovules contained within the
ovary. As with all heterosporous plants, the gametophytes also develop
inside the spores. File:Anther-schematic.png|Diagram of anther in cross section. 1: Filament; 2: Theca; 3: Connective (conducting vessels in red); 4: Pollen sac File:Ovule-Gymno-Angio-en (cropped).svg|Diagram of angiosperm ovule
Male The
androecium is the whorl of male parts called stamens, which produce
pollen. Stamens consist typically of an
anther, made up of four pollen sacs arranged in two sheaths called
thecae, connected to a
filament, or stalk. The anther contains microspores which become pollen, the male
gametophyte, after undergoing
meiosis. Although they exhibit the widest variation among floral organs, the androecium is usually confined just to one whorl and to two whorls only in rare cases.
Female The
gynoecium, consisting of one or more
carpels, is the female part of the flower and found on the innermost whorl. Each carpel consists of: a
stigma, which receives pollen; a
style, the stalk; and an
ovary, which contains the
ovules, and the female gametophytes by extension. Carpels may be fused together and are often described collectively as a pistil. Inside the ovary, the ovules are attached to the
placenta by structures called funiculi.
Variation Although most plants have flowers with four whorls—protective leaves, petals, male parts, and female parts—and their typical sub-structures, they vary greatly between flowering plants. This variation encompasses all aspects of flowers, including size, shape, and colour. Flowers range in size from (
duckweed) to in diameter (
corpse flower). Additionally, the four main parts of a flower are generally defined by their positions and not by their function. Many flowers lack some parts, have parts that are modified for other functions, or contain parts that look like what is typically another part. In some flowers, organs such as stamens, stigmas, and sepals are modified to resemble petals. This is most common in cultivation (such as of
roses), where flowers with many additional "petals" are found to be more attractive. Most flowers have symmetry. When the flower is bisected through the central axis from any point and symmetrical halves are produced, the flower is said to be
regular (as in
sedges). This is an example of
radial symmetry. If there is only one plane of symmetry (as in
orchids), the flower is said to be irregular. If, in very rare cases, they have no symmetry at all they are called asymmetric. Floral symmetry is a key driver of diversity in flower morphology, because it is one of the main features derived through flower-plant coevolution. Irregular flowers often coevolve with specific pollinators, while radially symmetric flowers tend to attract a wider range of pollinators. In the majority of species, individual flowers have both female parts and male parts — such flowers are described as being perfect, bisexual, or
hermaphrodite. In some species of plants, the flowers are imperfect or unisexual: having only either male or female parts. If unisexual male and female flowers appear on the same plant, the species is called
monoecious. However, if an individual plant is either female or male, the species is called
dioecious. Many flowers have
nectaries, which are glands that produce nectar: a sugary fluid used to attract pollinators. Their shape varies between different plants, are they not considered as an organ on their own. Some flowers are lacking or have only a highly reduced stalk, and so are
attached directly to the plant. There are several structures, found in some plants, that resemble flowers or floral organs. These include:
coronas, crown-like outgrowths; and pseudonectaries, that look like nectaries but do not contain nectar. In plants where disease has taken hold,
phyllody—leafy flower parts—may occur. File:Monoecy dioecy en.svg|Hermaphrodite flowers have both sexes, monoecious plants have sexes on different flowers, and dioecious plants have either just female or just male flowers. File:Hyndrangea phyllody (cropped).png|Healthy (left) and infected (right)
Hydrangea flower.
Phytoplasma has caused the flower to develop
leaves in place of petals.
Inflorescence inflorescence is made up of many small flowers grouped closely together to look like a single flower (a
pseudanthium). In plants that have more than one flower on an axis, the collective cluster of flowers is called an inflorescence. Some inflorescences are composed of many small flowers arranged in a formation that resembles a single flower. These are known as
pseudanthia. A single
daisy or
sunflower, for example, is not a flower but an inflorescence composed of numerous florets, or tiny flowers. An inflorescence may include specialised stems and modified leaves known called
bracts, as well as smaller bracteoles.
Floral diagrams and formulae ''|upright=.5 A floral formula is a way to represent the structure of a flower using letters, numbers, and symbols in a compact way. It can represent both a
group of species or a particular species, and usually gives ranges for the numbers of different organs. The format of floral formulae differs in different parts of the world, but the formulae all convey the same information.
Floral diagrams are schematic diagrams that can be used to show important features of flowers, including the relative positions of the various organs, the presence of organ fusion and symmetry, and structural details.
Colour In contrast to the mostly green vegetative parts of plants, flowers are often colourful. This includes the petals and, in some plants, the stamens, anthers, stigmas, ovaries, pollen, styles, and even nectar. These colours are produced mainly by
biological pigments, which are molecules that can absorb and retain energy from light. Specific pigments, and so colours, provide different benefits to the plant. These benefits include protecting the plant against degradation and guiding pollinators—both general and specific—to the plant. Colour, or colour effects, may also be produced by
structural coloration, in which colour is produced by tiny surface structures interfering with waves of light. This includes
iridescence (as in some
tulips) and
photonic crystals (as in
edelweiss), which diffract light using tiny grooves. The colour of flowers can also change; sometimes this acts as a signal to pollinators (as in
Viola cornuta). Change may also occur as a result of temperature;
pH, as in the
anthoxanthins found in
Hydrangea; metals; sugars; and cell shape. == Development ==