Lollipop Insertion
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Lollipop Insertion
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A display of rainbow-swirl lollipops
^ "Lollipop" . How Products are Made . Advameg Inc. 2007 . Retrieved 2007-08-19 .
^ Myers, Dan (2015-08-12). "Pop or Soda? Hero or Sub? 13 Regional Food Names Around America" . The Daily Meal . Retrieved 2021-08-02 .
^ "Lolly definition and meaning | Collins English Dictionary" . www.collinsdictionary.com . Retrieved 2021-08-02 .
^ Fromme, Alison (July–August 2005). "Edible insects" . Smithsonian National Zoological Park. Archived from the original on 2005-11-11 . Retrieved 2007-03-24 .
^ News, Deseret (1994-07-10). "KIDS ARE SUCKERS FOR LOLLIPOP THAT SPINS AROUND AND COSTS $4" . Deseret News . Retrieved 2021-08-02 .
^ St. James, Janet (February 8, 2007). "Lollipop Diet helps woman shed pounds" . WFAA News (Dallas/Fort Worth, Texas). Archived from the original on May 13, 2007 . Retrieved 2007-03-24 .
^ "Actiq Buccal: Uses, Side Effects, Interactions, Pictures, Warnings & Dosing - WebMD" . www.webmd.com . Retrieved 2021-08-02 .
^ Jump up to: a b "The History of Lollipop candy" . CandyFavorites.com . Retrieved 2013-12-27 .
^ Pearce, Food For Thought: Extraordinary Little Chronicles of the World , (2004) page 183.
^ "Lollipops and Candy Suckers – Retro Candy from" . CandyCrate.com. Archived from the original on 2014-02-13 . Retrieved 2013-12-27 .
^ Oxford English Dictionary, Second Edition, 1933
^ Harper, Douglas. "lollipop" . Online Etymology Dictionary . Retrieved 17 January 2012 .
^ Hubschmannova, Milena; Kalinin, Valdemar; Kenrick, Donald (2000). What is the Romani Language? . ISBN 9781902806068 . Retrieved 2013-12-27 .
^ McGhee, Harold (2004). On Food and Cooking . Scribner. pp. 647–712.
^ Jump up to: a b Roos, Y.H (2010). "Glass Transition Temperature and Its Relevance in Food Processing". Annual Review of Food Science and Technology . 1 : 470–491. doi : 10.1146/annurev.food.102308.124139 . PMID 22129345 .
Injection , infusion (into tissue/blood)
A lollipop is a type of sugar candy usually consisting of hard candy mounted on a stick and intended for sucking or licking . [1] Different informal terms are used in different places, including lolly , sucker , sticky-pop , etc. [2] [3] Lollipops are available in many flavors and shapes.
Lollipops are available in a number of colors and flavors, particularly fruit flavors. With numerous companies producing lollipops, the candy now comes in dozens of flavors and many different shapes. Lollipops can range from very small candies bought in bulk and given away as a courtesy at banks , barbershops , and other locations, to very large treats made from candy canes twisted into a spiral shape.
Most lollipops are eaten at room temperature, but " ice lollipops ", "ice lollies", or "popsicles" are frozen water-based lollipops. Similar confections on a stick made of ice cream , often with a flavored coating, are usually not called by this name.
Some lollipops contain fillings, such as bubble gum or soft candy. Some novelty lollipops have more unusual items, such as mealworm larvae , embedded in the candy. [4]
Other novelty lollipops have non-edible centers, such as a flashing light embedded within the candy; there is also a trend, principally in North America, [5] of lollipops with sticks attached to a motorized device that makes the candy spin around in one's mouth.
In the Nordic countries , Germany , and the Netherlands , some lollipops are flavored with salmiak .
Lollipops can be used to carry medicines.
Some lollipops have been marketed for use as diet aids , although their effectiveness is untested, and anecdotal cases of weight loss may be due to the power of suggestion . [6] Flavored lollipops containing medicine are intended to give children medicine without fuss.
Actiq is a powerful analgesic lollipop whose active ingredient is fentanyl . Often, patients utilizing large amounts of opioid pain medication take Actiq lozenges on a handle in order to control breakthrough cancer pain. [7]
The idea of an edible candy on a stick is very simple, and it is probable that the lollipop has been invented and reinvented numerous times. [8] The first confectioneries that closely resemble what we call lollipops date to the Middle Ages , when the nobility would often eat boiled sugar with the aid of sticks or handles. [8]
The invention of the modern lollipop is still something of a mystery but a number of American companies in the early 20th century have laid claim to it. According to the book Food for Thought: Extraordinary Little Chronicles of the World , they were invented by George Smith of New Haven , Connecticut , who started making large hard candies mounted on sticks in 1908. He named them after a racehorse of the time, Lolly Pop [9] - and trademarked the lollipop name in 1931. [10]
The term 'lollipop' was recorded by English lexicographer Francis Grose in 1796. [11] The term may have derived from the term "lolly" (tongue) and "pop" (slap). The first references to the lollipop in its modern context date to the 1920s. [12] Alternatively, it may be a word of Romany origin being related to the Roma tradition of selling candy apples on a stick. Red apple in the Romany language is loli phaba . [13]
The main ingredient in a standard lollipop is sugar. Sugars are fully hydrated carbon chains, meaning that there is a water molecule attached to each carbon. Sugars come in two forms; straight-chain and ring form. When sugars are in straight-chain form, aldehyde and ketone groups are open which leaves them very susceptible to reaction. In this state, sugars are unstable. In ring form, sugars are stable and therefore exist in this form in most foods, including lollipops.
Sugar is a very versatile ingredient and is used in a wide variety of food products. Sugar interacts differently depending on the presence of other ingredients and on various treatments. When heated enough to break the molecules apart, sugar generates a complex flavor, changes the color, and creates a pleasing aroma. [14] Sugar can form two types of solids in foods; crystalline and glassy amorphous. Crystalline solids can be found in food products such as fondant, fudge, and butter creams, while glassy amorphous solids can be found in products such as lollipops, marshmallows, and caramels. Glassy amorphous solids result when moderate sugar concentrations (50% solutions) are heated to high temperatures, eliminating nearly all moisture. The final moisture content is around 1%-2%, whereas the final moisture content in crystalline candies is 8%-12%. The non-crystalline nature of glassy amorphous solids is due to the presence of inhibitors in the solution. Without an inhibitor, crystallization would occur spontaneously and rapidly as sugar cools due to its high concentration. Some common inhibitors used in lollipop production are corn syrup, cream of tartar, honey, and butter.
The second most important ingredient in lollipop production is water. Although the moisture content falls to less than 2% at the end of the lollipop making process, water is required at the start of the process. All other ingredients used in the process of lollipop production are optional. The use of inhibitors is dependent on the type of sugar used. The amount of inhibitor in the lollipop is usually small in comparison to the amount of sugar used. Additional flavors, colorings, and inclusions (like bubble gum or a tootsie roll) can be added to the final product, but are not a part of the main structure of a simple lollipop.
While the main functional ingredients of a lollipop are quite simple, the process of making such confections can be complex. The formation and physical state of the glassy amorphous structure used in the creation of the lollipop is an involved chemical process. The first step in making lollipops after mixing the main ingredients is the heating process. During heating, the molecules increase in their translational mobility and therefore begin to resemble liquids. [15] Although many hard candies are heated to about 310˚F, the temperature that the solution is heated to is dependent on the specific volume and contents of the mixture. After heating is complete, the solution can then be cooled. The final cooled solution is a supersaturated due to the moisture content dropping below 2%. Supersaturated or supercooled liquids are also formed due to inhibitors preventing crystallization. They are unstable because crystallization is a favored reaction in this case. During the cooling process, the most important physicochemical characteristic of lollipops, the glass transition process, occurs.
Glass transition is the solid-liquid transformation of amorphous material. It is a reversible change of the solid and liquid states of supercooled liquids. Glass transition occurs approximately 100˚C-150˚C below the equilibrium melting temperature of a pure substance. [15] This dynamic transition is not a change of state, but a change of phase. It can be looked at in terms of a change in the molecular motion of the liquid, not a change in the molecular order itself. This transition from liquid to solid is what defines the physical appearance of a standard lollipop. The result of the glass transition is a kinetically static state of a supercooled liquid. Prior to this, as stated before, the liquid was unstable.
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1 School of Environment and Energy, South China University of Technology, Guangzhou, 510006, P. R. China.
2 Guangdong Provincial Key Laboratory of Atmospheric Environment and Pollution Control, South China University of Technology, Guangzhou, 510006, P. R. China.
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In this work, a novel lollipop nanostructure of Co 3 O 4 @MnO 2 composite is prepared as anode material in lithium-ion batteries (LIBs). Cobalt metal-organic framework (ZIF-67) is grown on the open end of MnO 2 nanotubes via a self-assembly process. The obtained ZIF-67@MnO 2 is then converted to Co 3 O 4 @MnO 2 by a simple annealing treatment in air. Scanning electron microscopy, transmission electron microscopy, and X-ray diffraction characterizations indicate that the prepared Co 3 O 4 @MnO 2 takes a lollipop nanostructure with a stick of ≈100 nm in diameter, consisting of MnO 2 nanotube, and a head part of ≈1 µm, consisting of Co 3 O 4 nanoparticles. The charge-discharge tests illustrate that this unique novel configuration endows the resulting Co 3 O 4 @MnO 2 with excellent electrochemical performances, delivering a capacity of 1080 mAh g -1 at 300 mA g -1 after 160 cycles, and 696 mAh g -1 at 1 A g -1 after 210 cycles, compared with 404 mAh g -1 and 590 for pure Co 3 O 4 polyhedrons and pure MnO 2 nanotubes at 300 mA g -1 after 160 cycles, respectively. The lollipop configuration consisting of porous Co 3 O 4 polyhedron and MnO 2 nanotube shows excellent structural stability and facilitates lithium insertion/extraction, leading to excellent cyclic stability and rate capacity of Co 3 O 4 @MnO 2 -based LIBs.
Keywords:
cobalt metal-organic framework (ZIF-67); lithium-ion batteries; lollipop nanostructures; self-assembly reaction.
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