specific heat

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1. energy that raises the temperature of a body or substance.
2. estrus.
3. a rise in temperature.
4. to cause to increase in temperature.

Heat is associated with molecular motion, and is generated in various ways, including combustion, friction, chemical action, and radiation. The total absence of heat is absolute zero, at which all molecular activity ceases.
Body Heat. Heat Production. Body heat is the byproduct of the metabolic processes of the body. The hormones thyroxine and epinephrine increase metabolism and consequently increase body heat. Muscular activity also produces body heat. At complete rest (basal metabolism) the amount of heat produced from muscular activity may be as low as 25 per cent of the total body heat. During exercise or shivering the percentage may rise to 60 per cent. Body temperature is regulated by the thermostatic center in the hypothalamus. A body temperature above the normal range is called fever.
Heat Loss. Loss of body heat occurs in three ways: by radiation (heat waves), by conduction to air or objects in contact with the body, and by evaporation of perspiration. Some body heat is lost in exhalation of air and in elimination of urine and feces.
Applications of External Heat. Purposes. Local applications of heat may be used to provide warmth and promote comfort, rest, and relaxation. Heat is also applied locally to promote suppuration and drainage from an infected area by hastening the inflammatory process; to relieve congestion and swelling by dilating the blood vessels, thereby increasing circulation; and to improve repair of diseased or injured tissues by increasing local metabolism.
Effects. Factors that determine the physiologic action of heat include the type of heat used, length of time it is applied, age and general condition of the patient, and area of body surface to which the heat is applied. Moist heat is more penetrating than dry heat. Prolonged applications of heat produce an increase in skin secretions, resulting in a softening of the skin and a lowering of its resistance. Extreme heat produces constriction of the blood vessels; moderate heat produces vascular dilation. Repeated applications of heat will result in an increased tolerance to heat so that the individual may be burned without being aware of it. Elderly persons and infants are more susceptible to burns from high temperatures.

Heat applied to an infected area can localize the infection; for this reason, external heat should not be applied to the abdomen when appendicitis is suspected, because it may lead to rupture of the inflamed appendix.
heat exhaustion a disorder resulting from overexposure to heat or to the sun; long exposure to extreme heat or too much activity under a hot sun causes excessive sweating, which removes large amounts of salt and fluid from the body. When salt and fluid levels fall too far below normal, heat exhaustion may result. Called also heat prostration.
Symptoms. The early symptoms are headache and a feeling of weakness and dizziness, usually accompanied by nausea and vomiting. There may also be cramps in the muscles of the arms, legs, or abdomen. These first symptoms are similar to the early signs of sunstroke, or heat stroke, but the disorders are not the same and should be treated differently. In heat exhaustion, the person turns pale and perspires profusely. The skin is cool and moist, pulse and breathing are rapid, and body temperature remains at a normal level or slightly below (in sunstroke the body temperature may be dangerously elevated). The patient may seem confused and may find it difficult to coordinate body movements; loss of consciousness seldom occurs.
Treatment. In cases of heat exhaustion, the victim should lie quietly in a cool place until transported to an emergency facility. The restoration of normal blood volume will be a priority. Stabilization of electrolytes is also important. If the person is able to safely swallow, sips of cool replacement fluid should be provided. Measures to reduce body temperature are employed.

If the condition is accompanied by cramps, the pain may be relieved by lightly stretching the affected muscles in addition to administering replenishing fluids. In cases of severe heat exhaustion and cramps, hospitalization may be necessary. Serum electrolyte levels are monitored to guide adequate replacement.
Prevention. Heat exhaustion and other heat disorders may be prevented by avoiding long exposure to sun or heat. The elderly, the very young, individuals with chronic diseases, and athletes exercising in the sun are at high risk. When the weather is very hot, or when working in an extremely hot place, it is essential to maintain adequate hydration. Regular rest periods are necessary. In the event of weakness or dizziness, persons should stop working at once and rest in a cool place.

It is possible for indoor temperatures to exceed the outdoor temperature. Poor ventilation can lead to an unhealthy situation that contributes to heat exhaustion. For this reason, adequate temperature control indoors is important in prevention of serious health problems.
latent heat the amount of heat absorbed or given off by a body without changing temperature, as when it undergoes a change of state.
prickly heat (heat rash) miliaria.
specific heat the ratio of the heat capacity of a substance to that of water; it is equivalent to the amount of heat required to raise the temperature of one gram of the substance by one degree Celsius, since the corresponding value for water is defined as 1.0.

spe·cif·ic heat

the amount of heat required to raise any substance through 1°C of temperature, compared with that raising the same volume of water 1°C.

specific heat

The heat needed to raise the temperature of 1 g of a substance 1°C.
See also: heat
References in periodicals archive ?
Table 3 shows the fiber diameter changes by considering the polymer density and the specific heat capacity of polymer melt at constant pressure varying with the polymer temperature.
Vermiculite dosage (%) 0 4 6 8 10 Thermal conductivity (W/m*K) 1.154 0.891 0.814 0.724 0.57 Specific heat capacity (J/kg*K) 716.24 691.68 657.44 633.62 613.24 TABLE 3: Material parameters for different soils.
No Material Parameter 1 Fuel (carbonised Calorific value agro-waste briquettes) 2 Charcoal Calorific value 3 Water Density 4 Water Specific heat capacity 5 Granite rock Thermal conductivity 6 Air Thermal conductivity 7 Stainless steel Thermal conductivity 8 Glass wool Thermal conductivity 9 Flame Theoretical Maximum temperature 10 Cook stove Theoretical thermal efficiency 11 Cook stove Energy loss No Units Values Reference 1 MJ/kg 21.7 Kiwana, 2016 2 MJ/kg 29.8 Kiwana, 2016 3 g/ltr 1000 Global Alliance for 4 J/g.K 4.186 Clean Cookstoves, 2014 5 W.[m.sup.-1].
Keywords: density, specific heat capacity, thermal diffusivity, wood particle
The reason is attributed to the peak in specific heat capacity at the critical temperature of the second material used.
In Section 4, we will extend this formalism and introduce the effect of the external magnetic field to calculate the specific heat capacity of degenerate quark matter.
* substantial dependence of thermal conductivity and heat capacity of polyethylene insulation on temperature (e.g., specific heat capacity of polyethylene at temperature of 20[degrees]C is 2300 J/ kg x [degrees]C and at 80[degrees]C-3750 J/kg x [degrees]C) and the presence of elements of design with high specific thermal resistance (till 50[degrees]C x m/W) which changes the thermal conditions of insulation compared to the operation mode of the traditional oil-filled cables.
Melting area 55-61 [degrees]C Congealing area 61-55 [degrees]C Heat storage capacity 160 kJ/kg Specific heat capacity 2 kJ/kgK Volumetric expansion 12.5% Maximum operating temperature 80 [degrees]C B.
Water has a high specific heat capacity, which protects their hands.
The institute studied the thermal stability of sand at high temperatures and its specific heat capacity and tendency to agglomerate.
The physical properties of stainless steel's reflectivity and emissivity, thermal conductivity and specific heat capacity make it the ideal material for the fabrication of heat shields.