table 3.7 in prentice hall chemistry That's going to depend on the pressure of the sample
as well as its temperature.
At NTP (standard temperature and pressure), which is 0 degrees Celsius and 1 atm pressure, the volume occupied by 1 gram of helium would be approximately 22.4 liters. This value is based on the ideal gas law and the molar mass of helium.
The mass of water at 25 degrees Celsius, without knowing the volume, cannot be determined. Mass is dependent on both volume and density, and without the volume of water given, it is not possible to calculate its mass.
No, grams are unit of mass, not temperature. Temperature is measured in °C (degrees celsius) or for scientific work in 'K' K = °C + 273.15
an ohm meter concerning electrical impedance
A body found at 34 degrees Celsius (93.2 degrees Fahrenheit) is likely to have been dead for several hours, as the normal human body temperature is around 37 degrees Celsius (98.6 degrees Fahrenheit). The rate of cooling depends on various factors, including the environment and body mass. Generally, a body cools at a rate of about 1-1.5 degrees Celsius per hour in a typical room temperature environment. Therefore, if the body is at 34 degrees Celsius, it may have been dead for approximately 2-3 hours, but this can vary significantly based on conditions.
Liters measure volume. Grams are a measure of mass, degrees Celsius are a measure of temperature, and meters are a measure of length.
Well, let's think about this in a calm and simple way. The mass of 5 liters of air at 20 degrees Celsius would depend on the density of air at that temperature. Air has a density of about 1.225 kg/m³ at 20 degrees Celsius, so you can calculate the mass by multiplying the volume (5 liters = 0.005 m³) by the density. Remember, it's all about taking your time and enjoying the process of learning something new.
The mass of 5 liters of air at 20 degrees Celsius can be calculated using the ideal gas law equation: (PV = nRT), where (P) is the pressure, (V) is the volume, (n) is the number of moles, (R) is the ideal gas constant, and (T) is the temperature in Kelvin. Given that air density is approximately 1.2 kg/m³ at 20 degrees Celsius, you can calculate the mass by converting liters to cubic meters and then using density formula.
1kg = 1000g ice will have volume: Density = mass /volume Volume = mass / density Volume = 1000/0.92 Volume = 1,086.95ml = 1,087ml 1,087 ml = 1.087 liters.
The mass of 29, 35 mL of water at 4 Celsius degrees is 29,349 178 2 g.
Kilograms and Kelvin (or degrees Celsius).
Due to more volume mass, it will take longer, but the 2 liters with double mass will eventually heat up the same 10 FIVE degrees with the same energy amount.
no it isn't
1.0 gramme
At NTP (standard temperature and pressure), which is 0 degrees Celsius and 1 atm pressure, the volume occupied by 1 gram of helium would be approximately 22.4 liters. This value is based on the ideal gas law and the molar mass of helium.
8.8kg...i guessed
The mass of water at 25 degrees Celsius, without knowing the volume, cannot be determined. Mass is dependent on both volume and density, and without the volume of water given, it is not possible to calculate its mass.