Math Is Fun Forum

Calyx

Gist

What Is a Calyx? In flowering plants (also called angiosperms), the part of the flower that surrounds the growing bud, often found at the base of the bloom, is called the calyx. The calyx is composed of one or more leaf-like structures called sepals.

Are sepals called calyx?

Collectively, the sepals are called the calyx (plural: calyces), the outermost whorl of parts that form a flower. The word calyx was adopted from the Latin calyx, not to be confused with calix 'cup, goblet'.

Summary

Calyx is the usually green outer whorl of a flower consisting of separate or fused sepals. The calyx serves primarily to protect the developing flower bud and, in some cases, to support the flower once it has bloomed. In some species, the calyx persists even when the fruit matures, as seen in persimmon, eggplant, strawberry, and tomato. Given that it is not directly involved in reproduction, the calyx is considered an accessory part of the flower.

There are commonly four distinct whorls of flower parts: (1) an outer calyx consisting of sepals; (2) the corolla, within the calyx and consisting of petals; (3) the male androecium, comprising the pollen-bearing stamens; and (4) the female gynoecium, at the center and consisting of the pistils, which hold ovules and one or more ovaries. A flower’s calyx and corolla (e.g., all the sepals and petals together) form the perianth, which serves to protect the reproductive organs and attract pollinators. The arrangement of floral organs, including the calyx, is typically in concentric whorls, with the sepals forming the outermost layer, though not every flower has every whorl. The numbers and arrangements of flower parts—including the number and degree of fusion of the sepals of the calyx—are key characteristics botanists use to identify flowering plant species.

The calyx exhibits a wide range of morphological diversity across different angiosperm species. In some flowers, the sepals are free and distinct, a condition known as aposepalous or polysepalous. In other species, the sepals are fused together, forming a tubular structure with lobes or teeth at the end, a condition referred to as synsepalous. The number of sepals in a calyx often corresponds to the number of petals, either directly (e.g., five sepals and five petals) or in multiples (e.g., four sepals and eight petals). In some species, the sepals are brightly colored and function as petals—for example, Clematis and Bougainvillea. In others, the petals and sepals are both present but are similar in color and appearance, as in the tulip tree (Liriodendron tulipifera) and Easter lily (Lilium longiflorum); in such cases, they are known as tepals.

Details

A sepal is a part of the flower of angiosperms (flowering plants). Usually green, sepals typically function as protection for the flower in bud, and often as support for the petals when in bloom. Collectively, the sepals are called the calyx.

Description

Sepals are usually green. The term tepal is usually applied when the parts of the perianth are difficult to distinguish, e.g. the petals and sepals share the same color or the petals are absent and the sepals are colorful. When the undifferentiated tepals resemble petals, they are referred to as "petaloid", as in petaloid monocots, orders of monocots with brightly colored tepals. Since they include Liliales, an alternative name is lilioid monocots. Examples of plants in which the term tepal is appropriate include genera such as Aloe and Tulipa. In contrast, genera such as Rosa and Phaseolus have well-distinguished sepals and petals.[citation needed]

The number of sepals in a flower is its merosity. Flower merosity is indicative of a plant's classification. The merosity of a eudicot flower is typically four or five. The merosity of a monocot or palaeodicot flower is three, or a multiple of three.

The development and form of the sepals vary considerably among flowering plants. They may be free (polysepalous) or fused together (gamosepalous). Often, the sepals are much reduced, appearing somewhat awn-like, or as scales, teeth, or ridges. Most often such structures protrude until the fruit is mature and falls off.

Examples of flowers with much-reduced perianths are found among the grasses.

In some flowers, the sepals are fused towards the base, forming a calyx tube (as in the families Lythraceae and Fabaceae). In other families (e.g. Rosaceae and Myrtaceae), a hypanthium includes the bases of sepals, petals, and the attachment points of the stamens.

Mechanical cues may be responsible for sepal growth and there is a strong evidence suggesting that microtubules are present and determine the tensile strength and direction of growth at a molecular level.

Morphology

Morphologically, both sepals and petals are modified leaves. The calyx (the sepals) and the corolla (the petals) are the outer sterile whorls of the flower, which together form the perianth. In some plants, such as Aristolochia, the calyx is the primary whorl, forming a flower up to 50 cm (20 in) wide, with one sepal growing to a slender ribbon with a length of up to 4 m (13 ft) in Aristolochia grandiflora, the largest of all calyces.

Function

Sepals typically function as protection for the flower in bud, and often as support for the petals when in bloom.

Similarly to ordinary leaves, sepals are capable of performing photosynthesis. However, photosynthesis in sepals occurs at a slower rate than in ordinary leaves due to sepals having a lower stomatal density which limits the spaces for gas exchange.

After flowering, most plants have no more use for the calyx, which withers or becomes vestigial, although in a few plants such as Lodoicea and Solanum melongena (aubergine, brinjal) the calyx grows along with the fruit, possibly to protect the attachment point. Some plants retain a thorny calyx, either dried or live, as protection for the fruit or seeds. Examples include species of Acaena, some of the Solanaceae (for example the tomatillo Physalis philadelphica), and the water caltrop, Trapa natans. In some species, the calyx not only persists after flowering but instead of withering, begins to grow until it forms a bladder-like enclosure around the fruit. This is an effective protection against some kinds of birds and insects, for example in Hibiscus trionum and in Physalis species. In some other plants, the calyx grows into an accessory fruit.

Additional Information:

Calyx Meaning

The outermost whorl of the flower is referred to as the calyx. Sepals are the functional units of the calyx, meaning that the calyx is a collection of sepals. The sepals are mostly green in colour and protect the inner structures of the flower from breakage, mechanical injury and desiccation. It supports the other internal structures of flowers such as the corolla, gynoecium and androecium. Corolla is the collection of petals, androecium is the male reproductive whorl and gynoecium is the female reproductive whorl of the flower.

The calyx is found just below the corolla. In some plants, the calyx and corolla are indistinguishable and are termed as perianth. Once the flower has bloomed, the calyx goes on to support the development of fruit. Sometimes, an additional whorl is found externally to the calyx that consists of a whorl of bracts that arise by the union of sepal appendages.

Forms of Calyx

* Polysepalous: When the calyx consists of sepals that are free from each other, it is referred to as polysepalous. E.g., Rose, Cassia
* Gamosepalous: When the sepals are fused in the calyx, it is referred to as gamosepalous. E.g., Datura
* Caducous: When the sepals of a flower wither or drop off, it is referred to as caducous. E.g., Poppy
* Petalloid: In petalloid conditions, the sepals of the flowers are coloured. E.g., Delphinium
* Persistent: In this form, the sepals do not wither and are persistent even in the fruits. E.g., Brinjal.

Functions of Calyx in Plants

The calyx serves several essential functions in the life cycle of a plant. These are:

* Protection: Primarily, the calyx is a protective covering for the developing flower bud, shielding it from physical damage, desiccation, and predation.
* Support: The calyx also provides structural support to the flower, holding its various components in place as it grows and develops. This support is crucial, especially in windy conditions, as it prevents the flower from dislodging or damaging.
* Regulation of Pollination: The sepals of the calyx can also play a role in attracting pollinators to the flower. In some plant species, the sepals' color, shape, and texture may aid in pollinator attraction, ultimately facilitating the transfer of pollen and ensuring successful fertilization, like in Petalloid Calyx.
* Water Regulation: The calyx also helps regulate the uptake and retention of water within the flower bud. The calyx prevents excessive water loss through transpiration and maintains optimal flower hydration.

The different types of calyx are:

* Polysepalous Calyx: This type of Calyx has sepals that are free and separate from each other. Polysepalous calyx examples are found in flowers like Hibiscus and Camellia, where individual sepals encircle the base of the flower, forming a protective shield around the developing bud.
* Gamosepalous Calyx: The sepals in this type are fused or united, forming a single structure. The Petunia is a classic example of a plant having a gamosepalous calyx.
* Caducous Calyx: Caducous Calyx is a calyx where the sepals eventually wither or fall off after the flower blooms. This can be seen in trees like the Maple, where the calyx serves its protective purpose during the bud's development and sheds away once the flower matures.
* Petalloid Calyx: Here, the sepals transform remarkably, adopting colors akin to petals. This phenomenon can be seen in plants like the Poinsettia, where the calyx protects and contributes to the flower's reproductive success by attracting pollinators like bright-colored petals.
* Persistent Calyx: The sepals remain even after the flower has bloomed. Instead of withering away, they stay attached to the developing fruit, offering continued support and protection. A notable example of this can be found in the Tomato plant, where the calyx persists even as the fruit ripens.

Laser Surgery

Gist

Laser surgery uses highly focused, intense light beams to treat, remove, or alter tissue with high precision, often serving as a minimally invasive alternative to traditional surgery. It commonly cuts, vaporizes, or coagulates tissue in various fields, including ophthalmology (LASIK), dermatology (skin lesions), and general surgery. Key benefits include faster recovery, reduced blood loss, and improved precision (LASIK: LASIK stands for Laser-Assisted In Situ Keratomileusis and is a procedure that permanently changes the shape of the cornea, the clear covering of the front of the eye, using an excimer laser.)

What is the laser surgery used for?

To help prevent blood loss by sealing small blood vessels. Refractive eye surgery. Dental procedures. To treat some skin conditions, including to remove warts, moles, tattoos, birthmarks, acne, scars, wrinkles, and unwanted hair.

Summary

Laser surgery is a type of surgery that uses special light beams instead of instruments for surgical procedures. LASER stands for "Light Amplification by the Stimulated Emission of Radiation." Lasers were first developed in 1960.

Newer laser modifications continue to have a large impact on medical and surgical practices. A large part of their impact has been seen in the treatment of various skin lesion and diseases.

What types of surgeries use lasers?

There are many indications for the use of lasers in surgery. The following are some of the more common indications:

* To remove tumors
* To help prevent blood loss by sealing small blood vessels
* To seal lymph vessels to help decrease swelling and decrease the spread of tumor cells
* To treat some skin conditions, including to remove or improve warts, moles, tattoos, birthmarks, scars, and wrinkles

How are lasers used during cancer surgery?

Laser surgery is a type of surgery that uses special light beams instead of instruments, such as scapels, to perform surgical procedures. There are several different types of lasers, each with characteristics that perform specific functions during surgery. Laser light can be delivered either continuously or intermittently and can be used with fiber optics to treat areas of the body that are often difficult to access. The following are some of the different types of laser used for cancer treatment:

* Carbon dioxide (CO2) lasers: Carbon dioxide (CO2) lasers can remove a very thin layer of tissue from the surface of the skin without removing deeper layers. The CO2 laser may be used to remove skin cancers and some precancerous cells.

* Neodymium:yttrium-aluminum-garnet (Nd:YAG) lasers: Neodymium:yttrium-aluminum-garnet (Nd:YAG) lasers can penetrate deeper into tissue and can cause blood to clot quickly. The laser light can be carried through optical fibers to reach less accessible internal parts of the body. For example, the Nd:YAG laser can be used to treat throat cancer.

* Laser-induced interstitial thermotherapy (LITT): Laser-induced interstitial thermotherapy (LITT) uses lasers to heat certain areas of the body. The lasers are directed to areas between organs (interstitial areas) that are near a tumor. The heat from the laser increases the temperature of the tumor, thereby shrinking, damaging, or destroying the cancer cells.

* Argon lasers: Argon lasers pass only through superficial layers of tissue such as skin. Photodynamic therapy (PDT) uses argon laser light to activate chemicals in the cancer cells.

Details

Laser surgery is a type of surgery that cuts tissue using a laser in contrast to using a scalpel.

Soft-tissue laser surgery is used in a variety of applications in humans (general surgery, neurosurgery, ENT, dentistry, orthodontics, and oral and maxillofacial surgery) as well as veterinary surgical fields. The primary uses of lasers in soft tissue surgery are to cut, ablate, vaporize, and coagulate. There are several different laser wavelengths used in soft tissue surgery. Different laser wavelengths and device settings (such as pulse duration and power) produce different effects on the tissue. Some commonly used lasers types in soft tissue surgery include erbium, diode, and CO2. Erbium lasers are excellent cutters, but provide minimal hemostasis. Diode lasers (hot tip) provide excellent hemostasis, but are slow cutters. CO2 lasers are both efficient at cutting and coagulating. Laser surgery is commonly used on the eye. Techniques used include LASIK, which is used to correct near and far-sightedness in vision, and photorefractive keratectomy, a procedure which permanently reshapes the cornea using an excimer laser to remove a small amount of the human tissue.

Effects

* Photochemical effect: clinically referred to as photodynamic therapy. Photosensitizer (photophrin II) is administered which is taken up by the tumor tissue and later irradiated by laser light resulting in highly toxic substances with resultant necrosis of the tumor. Photodynamic therapy is used in palliation of oesophageal and bronchial carcinoma and ablation of mucosal cancers of Gastrointestinal tract and urinary bladder.
* Photoablative effect: Used in eye surgeries like refractive surgery, band keratoplasty, and endartectomy of peripheral blood vessels.
* Photothermal effect: this property is used for endoscopic control of bleeding e.g. Bleeding peptic ulcers, oesophageal varices
* Photomechanical effect: used in intraluminal lithotripsy

Equipment

Surgical laser systems, sometimes called "laser scalpels", are differentiated not only by the wavelength, but also by the light delivery system: flexible fiber or articulated arm, as well as by other factors. Types of surgical lasers include carbon dioxide, argon, Nd:YAG laser, and potassium titanyl phosphate. CO2 lasers were the dominant soft-tissue surgical lasers as of 2010. (Nd:YAG (neodymium-doped yttrium aluminium garnet; Nd:Y3Al5O12) is a crystal that is used as a lasing medium for solid-state lasers.)

Applications:

Dermatology and plastic surgery

A range of lasers such as erbium, dye, Q switch lasers, and CO2 are used to treat various skin conditions including scars, vascular and pigmented lesions, and for photorejuvenation. The laser surgery for dermatology often bypasses the skin surface. The principle of laser surgery for dermatologic problems is based on SPTL (selective photothermolysis). The laser beam penetrates the skin until it encounters chromophore which absorbs the laser beam. After absorption of the laser beam, heat is generated to induce coagulation, necrosis of the targeted tissue, this results in the removal of unwanted tissue by laser surgery.

Laser resurfacing is a technique in which covalent bonds of a material are dissolved by a laser, a technique invented by aesthetic plastic surgeon Thomas L. Roberts, III using CO2 lasers in the 1990s.

Lasers are also used for laser-assisted lipectomy.

Eye surgery

Various types of laser surgery are used to treat refractive error. LASIK, in which a knife is used to cut a flap in the cornea, and a laser is used to reshape the layers underneath, is used to treat refractive error. IntraLASIK is a variant in which the flap is also cut with a laser. In photorefractive keratectomy (PRK, LASEK), the cornea is reshaped without first cutting a flap. In laser thermal keratoplasty, a ring of concentric burns is made in the cornea, which causes its surface to steepen, allowing better near vision. ReLEx SMILE is the latest advancement in laser vision correction technology. In SMILE surgery, ZEISS VisuMax femtosecond laser is used to make a small incision and to create a pre-calculated mini lens tissue (or lenticule) inside the cornea.

Lasers are also used to treat non-refractive conditions, such as phototherapeutic keratectomy (PTK) in which opacities and surface irregularities are removed from the cornea and laser coagulation in which a laser is used to cauterize blood vessels in the eye, to treat various conditions. Lasers can be used to repair tears in the retina.

Endovascular surgery

Laser endarterectomy is a technique in which an entire atheromatous plaque in the artery is excised. Other applications include laser assisted angioplasties and laser-assisted vascular anastomosis.

Foot and ankle surgery

Lasers are used to treat several disorders in foot and ankle surgery. They are used to remove benign and malignant tumors, treat bunions, debride ulcers and burns, excise epidermal nevi, blue rubber bleb nevi, and keloids, and the removal of hypertrophic scars and tattoos.

A carbon dioxide laser (CO2) is used in surgery to treat onychocryptosis (ingrown nails), onychauxis (club nails), onychogryposis (rams horn nail), and onychomycosis (fungus nail).

Gastro-intestinal tract

1) Peptic ulcer disease and oesophageal varices - Laser photoablation is done.
2) Coagulation of vascular malformations of stomach, duodenum, and colon.
3) Lasers can be effectively used to treat early gastric cancers provided they are less than 4 cm and without lymph node involvement. Lasers are also used in treating oral submucous fibrosis.
4) Palliative laser therapy is given in advanced oesophageal cancers with obstruction of lumen. Recanalisation of the lumen is done which allows the patient to resume a soft diet and maintain hydration.
5) Ablative laser therapy is used in advanced colorectal cancers to relieve obstruction and to control bleeding.
6) Laser surgery used in hemorrhoidectomy, and is a relatively popular and non-invasive method of hemorrhoid removal.
7) Laser-assisted liver resections have been done using carbon dioxide and Nd:YAG lasers.
8) The ablation of liver tumors can be achieved by selective photovaporization of the tumor.
9) Endoscopic laser lithotripsy is a safer modality compared to electrohydraulic lithotripsy.

Oral and dental surgery

The CO2 laser is used in oral and dental surgery for virtually all soft-tissue procedures, such as gingivectomies, vestibuloplasties, frenectomies, and operculectomies. The CO2 10,600 nm wavelength is safe around implants as it is reflected by titanium, and thus has been gaining popularity in the field of periodontology. The laser may also be effective in treating peri-implantitis.

Spine surgery

Laser spine surgery first began seeing clinical use in the 1980s and was primarily used within discectomy to treat lumbar disc disease under the notion that heating a bulging disc vaporized enough tissue to relieve pressure on the nerves and help alleviate pain.

Since that time, laser spine surgery has become one of the most marketed forms of minimally invasive spine surgery, despite the fact that it has never been studied in a controlled clinical trial to determine its effectiveness apart from disc decompression. Evidence-based data surrounding the use of lasers in spine surgery is limited and its safety and efficacy were poorly understood as of 2017.

Thoracic surgery

In thoracic surgery, surgical laser applications are most often used to remove pulmonary metastases and tumors of different primary localizations. Other areas of application are surgical sectioning of the parenchyma, anatomic segmental resections, removal of tumors from the thoracic wall and abrasion of the pleura parietalis. Since the introduction of surgical lasers, the amount of potentially surgically resectable pulmonary nodules has significantly increased. Compared to laser surgery, other conventional surgical methods such as segmental or wedge resections with surgical stapling will normally lead to a bigger loss of lung tissue, especially in patients with multiple pulmonary nodules methods.

Other advantages of laser surgery compared to conventional methods are that it leads to an improved postoperative lung function and that it gives the additional possibility to histologically analyze the removed material which would otherwise be destroyed through radiation or heat.

Hard tissues

Lasers are used to cut or ablate bones and teeth in dentistry.

Other surgery

The CO2 laser is also used in gynecology, genitourinary, general surgery, otorhinolaryngology, orthopedic, and neurosurgery.

Additional Information:

What is laser surgery?

Laser surgery is a type of surgery that uses special light beams instead of instruments for surgical procedures.

How does a laser work?

The functioning of a laser goes back to Albert Einstein's theory of stimulated emission of radiation. It also includes other theories that help explain local tissue damage. As the light beam hits the skin, the skin may either reflect the light away, scatter the light, absorb the light, or let the light pass right through the different layers of the skin.

Certain parts of the skin called chromophores absorb the light. When these chromophores absorb the light, physical, mechanical, chemical, or temperature changes may occur in the tissue.

There are many different types of lasers. They include the carbon dioxide laser, the YAG (neodymium, or yttrium aluminum garnet) laser, and the argon laser. Each one works differently and may be used for different treatment options. Laser light can be delivered either continuously or intermittently. The wavelength of the laser determines the target within the skin and the effect it may have.

What types of surgeries use lasers?

There are many reasons to use lasers in surgery. The following are some of the more common reasons:

* To shrink or destroy tumors
* To help prevent blood loss by sealing small blood vessels
* Refractive eye surgery
* Dental procedures
* To treat some skin conditions, including to remove warts, moles, tattoos, birthmarks, acne, scars, wrinkles, and unwanted hair.

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Corolla

Gist

A corolla is the collection of a flower's petals, often brightly colored to attract pollinators, forming the second whorl inside the sepals and surrounding the reproductive organs (stamens and pistils) to help with pollination and protect them. It comes from the Latin word for "wreath" or "crown" and can vary greatly in shape (bell, funnel, tubular) and fusion (fused or free) across different plants.

The corolla is the name given to the collective rings of petals around a flower and its reproductive organs. The corolla functions in aiding the reproduction process known as pollination. Pollination is when pollen is transferred between flowers resulting in fertilization.

Summary

Petals are modified leaves that form an inner whorl surrounding the reproductive parts of flowers. They are often brightly coloured or unusually shaped to attract pollinators. All of the petals of a flower are collectively known as the corolla. Petals are usually surrounded by an outer whorl of modified leaves called sepals, that collectively form the calyx and lie just beneath the corolla. The calyx and the corolla together make up the perianth, the non-reproductive portion of a flower. When the petals and sepals of a flower are difficult to distinguish, they are collectively called tepals. Examples of plants in which the term tepal is appropriate include genera such as Aloe and Tulipa. Conversely, genera such as Rosa and Phaseolus have well-distinguished sepals and petals. When the undifferentiated tepals resemble petals, they are referred to as "petaloid", as in petaloid monocots, orders of monocots with brightly coloured tepals. Since they include Liliales, an alternative name is lilioid monocots.

Although petals are usually the most conspicuous parts of animal-pollinated flowers, wind-pollinated species, such as the grasses, either have very small petals or lack them entirely (apetalous).

Corolla

The collection of all petals in a flower is referred to as the corolla. The role of the corolla in plant evolution has been studied extensively since Charles Darwin postulated a theory of the origin of elongated corollae and corolla tubes.

A corolla of separate petals, without fusion of individual segments, is apopetalous. If the petals are free from one another in the corolla, the plant is polypetalous or choripetalous; while if the petals are at least partially fused, it is gamopetalous or sympetalous. In the case of fused tepals, the term is syntepalous. Fused petals may form a tube, which is then known as a 'corolla tube'.

Details

A petal, in flowering plants, is a sterile floral part that usually functions as a visually conspicuous element of a flower. Petals are modified leaves and are often brightly colored or white to attract specific pollinators to the flower. Petals often come in multiples of three in monocots or in multiples of four or five in eudicots. Many horticultural flowers, such as roses and peonies, have been bred to have multiple layers of petals, resulting in showy, textured blooms.

Many flowers have two sets of sterile appendages, the petals and the sepals, that are attached below the fertile parts of the flower, the stamens and the pistils. All of the petals of a flower are collectively called the corolla, while all the sepals form the calyx. The calyx and the corolla together are referred to as the perianth. Like petals, sepals are modified leaves, but they are often green and somewhat rugged; they serve to protect and enclose the flower bud. Petals, by contrast, are often thinner and more delicate than sepals and come in a myriad of colors. In some flowers, such as many lilies and orchids, the petals and sepals are nearly indistinguishable in appearance; such undifferentiated structures are known as tepals.

The “petals” of certain members of the aster family (Asteraceae), such as those of daisies and sunflowers, are actually each individual flowers on a composite head. In more than half the members of the family, these ray flowers form in the outermost row or rows of the composite head and have a modified, mainly flat and elongate corolla that resembles an individual petal of most other flowers.

Additional Information:

Parts of a Flower

Plants are primarily divided into flowering and non-flowering classes based on whether they have flowers. A flower, a defining feature of flowering plants, is essentially an extension of the shoot used for reproduction.

The four primary components of most flowers are sepals, petals, stamens, and carpels. The female component of the flower is the carpels, while the male component is the stamens. Most flowers are hermaphrodites, meaning they have both male and female components. Others may be male or female and contain one of the two parts.

* Peduncle: The flower’s stalk is known as a peduncle.
* Receptacle: This is the area of the flower where the stalk is attached. It is tiny and is located at the centre of the flower’s base.
* Petals: This layer is located right above the sepal layer. The collection of petals is known as the corolla. Since their primary function is to draw pollinators, such as insects, butterflies, and other creatures, to the flower, they are often brightly coloured.
* Sepals: At the base of the petals, they are tiny, leaf-like components. They constitute the top whorl of the flower. Sepals are collectively referred to as the calyx. The primary purpose of the calyx and its sepals is to safeguard the flower before blooming (in the bud phase).
* Stamens: They are the male components of a flower. The androecium is a collection of many stamens. They are structurally separated into two parts:
* Filament: The extended, slender portion that connects the anther to the flower is called a filament.
* Anthers: The stamen’s head is where the pollen is produced, which is then transmitted to the pistil or other female sections of the same or different flower to induce fertilisation.
* Pistil: This constitutes the female components of a flower. The pistil consists of four parts: Style, Stigma, Ovary, and Ovules. The gynoecium is the term for a collection of pistils.

Corolla of Flower

What do you see when you first look at a flowering plant? Is it the flower, the stem, or the leaves? The brightly coloured petals of the flower are the most prominent part of most flowering plants. The corolla is the collective term for the arrangement of petals of flowers, which are frequently placed in a circle around the flower’s centre.

Most flowers include sepals, or little leaf-like structures, on the outside of the corolla that surround the petals before the flower develops. Most flowers have three more circles of structures added to the corolla that make up the entire flower. The first circle of structures inside the corolla is made up of many stamens and other male reproductive elements. The female reproductive part, known as the pistil, is located in a circle at the centre of the flower.

In this article, we will learn the corolla’s meaning, features, variations, and significant functions.

Meaning of Corolla

In plants, the term “corolla” refers to a collection of petals that strongly displays colour and encircles the stamen and carpel, the reproductive organs of a flower. Therefore, corolla or petals refers to the second whorl of a flower, which is internal to the calyx. Corollas can also be gamopetalous (fused) and polypetalous (free), just like the calyx.

Plants have a wide range of corolla shapes and colours. Corolla might be wheel-shaped, bell-shaped, tubular, or styled like a funnel. These corollas draw insects to the flower, and while at the flower, these insects participate in pollination.

Features of Corolla of Flower

* The important function of petals is to keep the vital flower components in their younger state.
* Due to the presence of specific pigments such as water-soluble anthocyanin, anthoxanthin, carotenoids, etc., corolla typically has a vibrant colour.
* The essential oil gives the petals their fragrance.
* Additionally, the petals have organs called nectaries that produce sugar-rich nectar to attract insects.
* Sepaloid has petals that are pale or green in colour. Examples are the Polyalthia and Annona species.
* The petals can occasionally be thicker while often being thin.
* The petal structure consists of two parts: the claw and the limb.
* The claw is the thin, stalk-like basal portion of a petal. All clawless bracts are sessile.
* A limb is the enlarged apex of the petals.
* Petals can have regular or irregular sizes and shapes.
* The corolla can have bilateral or radial symmetry.
* The edges of a petal might be whole, serrated, split, etc., much like a leaf lamina.

Functions of Corolla

Corolla performs three functional activities:

1. Pollination: The flower petals have a vibrant appearance and an aromatic fragrance that attracts everyone’s attention. Bees, birds, and other pollinating creatures thus aid in the fertilisation of flowers.

2. Storage: To draw pollinators, petals serve as storage for sugar-rich nectar.

3. Protection: The male (stamen) and female (carpel) reproductive elements of the flower, which are involved in fertilising the flower to generate fruits, are protected by the whorl of petals.

Conclusion

Thus, the group of petals collectively known as corolla is the most appealing feature of a flower due to its vibrant colours and fragrance. Although it does not directly participate in pollination, it indirectly can attract or deter specific pollinators.

Combination Quotes - I

1. A good head and a good heart are always a formidable combination. - Nelson Mandela

2. There are three principal means of acquiring knowledge... observation of nature, reflection, and experimentation. Observation collects facts; reflection combines them; experimentation verifies the result of that combination. - Denis Diderot

3. Software is a great combination between artistry and engineering. - Bill Gates

4. I believe myself to possess a most singular combination of qualities exactly fitted to make me pre-eminently a discoverer of the hidden realities of nature. - Ada Lovelace

5. God gave women intuition and femininity. Used properly, the combination easily jumbles the brain of any man I've ever met. - Farrah Fawcett

6. Mathematical reasoning may be regarded rather schematically as the exercise of a combination of two facilities, which we may call intuition and ingenuity. - Alan Turing

7. Tennis is a perfect combination of violent action taking place in an atmosphere of total tranquility. - Billie Jean King

8. The future of food security will depend on a combination of the ecological prudence of the past and the technological advances of today. - M. S. Swaminathan.

Time Zone

Gist

Time zones divide the world into 24 segments, each about 15 degrees of longitude wide, to standardize time, as the Earth rotates 15 degrees every hour. They create uniform local times, offset from Coordinated Universal Time (UTC), allowing for synchronized schedules despite different sunrises/sunsets, with political boundaries often adjusting ideal 15-degree lines for practicality and some regions using Daylight Saving Time (DST).

Time zones are primarily based on the Earth's rotation and its division into 24 longitudinal sections, with each representing one hour of the day. The prime meridian, located at Greenwich, England (Greenwich Mean Time or GMT), serves as the starting point for defining time zones.

Summary

A time zone is an area which observes a uniform standard time for legal, commercial, and social purposes. Time zones tend to follow the boundaries between countries and their subdivisions instead of strictly following longitude, because it is convenient for areas in frequent communication to keep the same time.

Each time zone is defined by a standard offset from Coordinated Universal Time (UTC). The offsets range from UTC−12:00 to UTC+14:00, and are usually a whole number of hours, but a few zones are offset by an additional 30 or 45 minutes, such as in India and Nepal. Some areas in a time zone may use a different offset for part of the year, typically one hour ahead during spring and summer, a practice known as daylight saving time (DST).

Details

Time zone is a zone on the terrestrial globe that is approximately 15° longitude wide and extends from pole to pole and within which a uniform clock time is used. Time zones are the functional basis of standard time and were introduced in the late 19th century as railways connected places that had differing local times.

Different time zones occur because of the way in which Earth spins. Earth rotates 360 degrees every 24 hours, and therefore different parts of the planet experience daylight and darkness at different times. To coordinate time with daylight, the globe is divided into 24 segments, each 15 degrees of longitude apart. The prime meridian in Greenwich, England, serves as the starting point for these divisions, creating a global framework for timekeeping.

While the theoretical model of time zones is straightforward, practical adjustments are often made to accommodate political, social, and economic factors. For instance, some regions have chosen to adopt time offsets of 30 or 45 minutes instead of the standard one-hour difference. These adjustments are made to better align with local solar time or to unify time within a country, as seen in places such as Newfoundland, Iran, and India.

Before the concept of time zones, each locality set its time based on the Sun’s position, leading to a chaotic array of local times. This system became impractical with the advent of rapid railway transportation in the late 19th century, which required a more uniform timekeeping system to avoid confusion in scheduling. The introduction of standard time zones was a solution to this problem, allowing regions to adopt a consistent time standard.

International Date Line is an imaginary line extending between the North Pole and the South Pole and arbitrarily demarcating each calendar day from the next. It corresponds along most of its length to the 180th meridian of longitude but deviates eastward through the Bering Strait to avoid dividing Siberia and then deviates westward to include the Aleutian Islands with Alaska. South of the Equator, another eastward deviation allows certain island groups to have the same day as New Zealand.

The International Date Line is a consequence of the worldwide use of timekeeping systems arranged so that local noon corresponds approximately to the time at which the sun crosses the local meridian of longitude. A traveler going completely around the world while carrying a clock that he advanced or set back by one hour whenever he entered a new time zone and a calendar that he advanced by one day whenever his clock indicated midnight would find on returning to his starting point that the date according to his own experience was different by one day from that kept by persons who had remained at the starting point. The International Date Line provides a standard means of making the needed readjustment: travelers moving eastward across the line set their calendars back one day, and those traveling westward set theirs a day ahead.

Coordinated Universal Time (UTC) is the international basis of civil and scientific time, which was introduced on January 1, 1960. The unit of UTC is the atomic second, and UTC is widely broadcast by radio signals. These signals ultimately furnish the basis for the setting of all public and private clocks. Since January 1, 1972, UTC has been modified by adding “leap seconds” when necessary.

UTC serves to accommodate the timekeeping differences that arise between atomic time (which is derived from atomic clocks) and solar time (which is derived from astronomical measurements of Earth’s rotation on its axis relative to the Sun). UTC is thus kept within an exact number of seconds of International Atomic Time and is also kept within 0.9 second of the solar time denoted UT1. Because of the irregular slowing of Earth’s rate of rotation by tidal friction and other forces, there is now about one more (atomic clock-derived) second in a solar year than there are UT1 seconds. To remedy this discrepancy, UTC is kept within 0.9 second of UT1 by adding a leap second to UTC as needed; the last minute of December or June is made to contain 61 seconds. The slowing of Earth’s rotation varies irregularly, and so the number of leap seconds by which UTC must be retarded to keep it in epoch with UT1 cannot be predicted years in advance. Impending leap seconds for UTC are announced at least eight weeks in advance by the International Earth Rotation and Reference Systems Service at the Paris Observatory, however.

Universal Time (UT), the mean solar time of the Greenwich meridian (0° longitude). Universal Time replaced the designation Greenwich Mean Time in 1928; it is now used to denote the solar time (q.v. : quod vide : which see) when an accuracy of about one second suffices. In 1955 the International Astronomical Union defined several categories of Universal Time of successively increasing accuracy. UT0 represents the initial values of Universal Time obtained by optical observations of star transits at various astronomical observatories. These values differ slightly from each other because of the effects of polar motion (q.v.). UT1, which gives the precise angular coordinate of the Earth about its spin axis, is obtained by correcting UT0 for the effects of polar motion. Finally, an empirical correction to take account of annual changes in the Earth’s speed of rotation is added to UT1 to convert it into UT2. Coordinated Universal Time (q.v.), the international basis of civil and scientific time, is obtained from an atomic clock that is adjusted in epoch so as to remain close to UT1; in this way, the solar time that is indicated by Universal Time is kept in close coordination with atomic time.

Standard Time, the time of a region or country that is established by law or general usage as civil time.

The concept was adopted in the late 19th century in an attempt to end the confusion that was caused by each community’s use of its own solar time. Some such standard became increasingly necessary with the development of rapid railway transportation and the consequent confusion of schedules that used scores of different local times kept in separate communities. (Local time varies continuously with change in longitude.) The need for a standard time was felt most particularly in the United States and Canada, where long-distance railway routes passed through places that differed by several hours in local time. Sir Sandford Fleming, a Canadian railway planner and engineer, outlined a plan for worldwide standard time in the late 1870s. Following this initiative, in 1884 delegates from 27 countries met in Washington, D.C., and agreed on a system basically the same as that now in use.

The present system employs 24 standard meridians of longitude (lines running from the North Pole to the South Pole, at right angles to the Equator) 15° apart, starting with the prime meridian through Greenwich, England. These meridians are theoretically the centres of 24 Standard Time zones, although in practice the zones often are subdivided or altered in shape for the convenience of inhabitants; a notable example of such alteration is the eastward extension of the International Date Line around the Pacific island country of Kiribati. Time is the same throughout each zone and differs from the international basis of legal and scientific time, Coordinated Universal Time, by an integral number of hours; minutes and seconds are the same. In a few regions, however, the legal time kept is not that of one of the 24 Standard Time zones, because half-hour or quarter-hour differences are in effect there. In addition, Daylight Saving Time is a common system by which time is advanced one hour from Standard Time, typically to extend daylight hours during conventional waking time and in most cases for part of the year (usually in summer).

Additional Information

Data spotlights represent data and statistics from a specific period of time, and do not reflect ongoing data collection. As individual spotlights are static stories, they are not subject to the Bureau of Transportation Statistics (BTS) web standards and may not be updated after their publication date. Please contact BTS to request updated information.

Before the establishment of time zones in 1883, there were more than 144 local times in North America. The resulting time differences between adjacent towns and cities were not critical when it took days to travel from place to place. With the proliferation of railroads, faster travel became possible across large geographies, and travelers could sometimes arrive at an earlier local time than they had departed. Due to this lack of time standardization, train scheduling proved difficult to coordinate, resulting in missed connections and collisions. As a result, the major railroad companies began to operate on a coordinated system of four time zones starting in 1883.

Because the development of standardized time was transportation-driven, the government coordination of time zones was handled by transportation agencies. In 1918, the federal organization in charge of railroad regulation — the Interstate Commerce Commission (ICC) — was given the power to address coordination concerns. That year, five time zones were officially adopted as the US entered World War I: the Eastern, Central, Mountain, Pacific, and Alaska zones, all of which are still in use today. However, the need for coordination among all transportation modes became increasingly important after World War II. When the Department of Transportation was created by Congress in 1966, it was assigned “the responsibility of regulating, fostering, and promoting widespread and uniform adoption and observance of standardized time” within each time zone.

Daylight Saving Time (DST) was enacted as a legal requirement by the Uniform Time Act of 1966. Motivated by transportation improvements, this act mandated standard time within the existing time zones and established a permanent system of uniform DST, including the dates and times for twice yearly transitions.  While State governments cannot independently change time zones or the length of DST, they can exempt themselves from DST, independent of DOT authority or permission. Nonetheless, DST is observed uniformly across the nation except in American Samoa, Guam, Northern Mariana Islands, Puerto Rico, the Virgin Islands, Hawaii, and most of Arizona.

Today, the Department of Transportation continues to oversee standard time due to its historical and contemporary importance in transportation and associated commercial activity. Time zone boundaries, established by law, can only be changed by the Secretary of Transportation upon a determination that the proposed adjustment serves the “convenience of commerce.” Per DOT policy, a petition requesting such a change must come from the highest political authorities in a State or locality. Several communities have requested changes to their time zone designation over the past two decades, the most recent being Mercer County, North Dakota in 2010, which chose to switch from Mountain to Central Time. Authorizing these changes and keeping track of the legally designated time zone for each area of the U.S. are key facets of the DOT’s oversight of uniform time observance, time zones, and DST.

In 2019, the Bureau of Transportation Statistics (BTS), in coordination with the Office of the General Counsel, created a digital geographic representation of the official written time zone delineations defined in the Code of Federal Regulations (CFR), Title 49, Subtitle A, Part 71 - Standard Time Zone Boundaries. Currently the United States and its territories have 9 time zone boundaries: Atlantic, Eastern, Central, Mountain, Pacific, Alaska, Hawaii–Aleutian, Samoa, and Chamorro.

The DOT Time Zone Boundary Geospatial layer is the verified digital representation of the current time zone delineations as written in the CFR, and is part of the National Transportation Atlas Database (NTAD). This layer provides the American public with detailed, reliable, and authoritative information on time-related authorities and time zone boundaries.