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Specific heat of Copper metal:
Values given are in gram-calories(15deg) per gram per degree centigrade.
To convert to joules per gram per degree Centigrade, multiply by 4.185
At given temperature in degrees Celsius, specific heat is:
T: minus 253 : S.H. 0.0031
minus 253 to minus 153 : 0.0245
minus 213 : 0.029
minus 193 : 0.047
minus 188 to plus 20 : 0.0788
minus 79 to plus 18 : 0.0883
zero C : 0.0909
plus 20 : 0.0912
plus 15 to plus 100 : 0.09305
plus 50 0.0928
plus 100 : 0.0942
plus 200 : 0.0963
plus 900: 0.1259
Hope this helps * 1 year ago Lange Handbook of Chemistry
What else can I help you with?
Water has a temp of 4.184 and copper has a temp of 0.387. Does it takes more heat to raise the temp of the copper molecule?
These are not temperature numbers but specific heat numbers. They mean that it takes 4.184 Joules and 0.387 Joules respectively to raise water and copper of one gram by one degree celsius. So, as you can see, it takes a lot more heat to raise the temperature of water than it does of copper. Water has a very high specific heat.
Will concrete brick aluminum or copper take most energy to increase its temperature?
Copper will take the most energy to increase its temperature, followed by aluminum and then concrete brick. This is because copper has a higher specific heat capacity compared to aluminum and concrete brick, meaning it requires more energy to raise its temperature.
What substance will increase the most in temperature 100G?
Substances with a low specific heat capacity will experience the greatest increase in temperature when 100g of heat is added. This means that metals like copper or aluminum, which have low specific heat capacities, will increase in temperature the most compared to substances like water or sand which have higher specific heat capacities.
What substance would absorb the most heat energy with the least change in temperature water or copper?
Copper would absorb more heat energy with less change in temperature compared to water due to its higher specific heat capacity. This means that copper can absorb more heat per unit mass before its temperature noticeably increases, while water's temperature would rise more easily when absorbing heat.
Why iron is not a good conductor of heat if it compair to copper?
Copper has relatively easily available electron as compare to the iron because copper has bigger atomic size than iron which means the shielding effect in copper is more than iron so the electron of copper can conduct heat more easily and efficiently as compare to the electron of the iron which make iron not a good conductor of heat if it is compair to copper.
What is the specific heat of copper at STP?
The specific heat of copper at standard temperature and pressure (STP) is approximately 0.385 J/g°C. This means that it requires 0.385 joules of energy to raise the temperature of 1 gram of copper by 1 degree Celsius at STP.
What is the specific heat capacity of copper sulphate?
The specific heat capacity of copper sulfate varies with temperature. At room temperature, it is approximately 0.39 J/g°C.
What is the specific heat of copper ii sulfate?
The specific heat of copper(II) sulfate is approximately 0.39 J/g°C. This value represents the amount of heat required to raise the temperature of 1 gram of copper(II) sulfate by 1°C.
How much heat energy is required to raise the temperature of 0.365 of copper from 23.0 to 60.0 The specific heat of copper is 0.0920?
To calculate the heat energy required, you can use the formula: Q = mcΔT, where Q is the heat energy, m is the mass of the copper (0.365 kg), c is the specific heat capacity of copper (0.0920 J/g°C), and ΔT is the change in temperature (60.0°C - 23.0°C). First, convert the mass to grams and then plug the values into the formula to find the heat energy required.
Which Has An Greater Specific Heat Water or Copper?
Water has a greater specific heat capacity than copper. This means that water can absorb more heat energy before its temperature increases compared to copper. This property of water is why it is often used as a coolant in various applications.
What is coppers specific heat?
The specific heat of copper is 0.093 cal/g(C°) or 390 J/kg(C°).
What is the Specific heat capacity for copper?
The specific heat capacity of copper is approximately 0.385 J/g°C. This means that it takes 0.385 joules of energy to raise the temperature of 1 gram of copper by 1 degree Celsius. Copper has a relatively high specific heat capacity compared to other metals.
Does copper have a higher specific heat than water?
The specific heat of water is 4184 J kg-1 K-1 The specific heat of copper 385 J kg-1 K-1. So the answer is no.
Aluminum has a specific heat capacity more than twice that of copper Place equal masses of aluminum and copper wire in a flame and the one to undergo the fastest increase in temperature will be?
The copper wire will undergo the fastest increase in temperature because it has a lower specific heat capacity compared to aluminum. This means copper can absorb heat more quickly and reach a higher temperature faster than aluminum when exposed to the same amount of heat.
How much heat is absorbed by 60.0 grams of copper when it is heated from 293 Kelvin to 353 kelvin?
The specific heat capacity of copper is 0.385 J/g°C. You can use the formula Q = mcΔT, where Q is the heat absorbed, m is the mass, c is the specific heat capacity, and ΔT is the change in temperature. Plugging in the values, you can calculate the heat absorbed by the copper.
Water has a temp of 4.184 and copper has a temp of 0.387. Does it takes more heat to raise the temp of the copper molecule?
These are not temperature numbers but specific heat numbers. They mean that it takes 4.184 Joules and 0.387 Joules respectively to raise water and copper of one gram by one degree celsius. So, as you can see, it takes a lot more heat to raise the temperature of water than it does of copper. Water has a very high specific heat.
When 90 kJ is removed from a 2-kg copper bar its temperature drops from 200C to 85C. The specific heat of copper is?
You are supposed to divide the energy by the product of (mass x temperature difference).
