The nucleus of a sulfur atom wil have 16 Neutron and two Hydrogen atoms can form covalent bond with sulfur.
What is Covalent bond ?A covalent bond is an electron exchange that causes the production of electron pairs between atoms.
Covalent bonding is a stable equilibrium of the attractive and repulsive forces between two atoms that occurs when they share electrons. Bonding pairs or sharing pairs are other names for these electron pairs.
Sulfur and hydrogen combine to form H₂S as a result (Hydrogen Sulphide).
H₂S is a moderately polar molecule due to its bent geometrical structure and the little difference in electronegativity between sulfur (2.58) and hydrogen (2.2), which results in a non-zero dipole moment.
Therefore, The nucleus of a sulfur atom wil have 16 Neutron and two Hydrogen atoms can form covalent bond with sulfur.
Learn more about Bonding here ;
https://brainly.com/question/13559242
#SPJ2
What is the change in energy if the electron from part a now drops to the ground state?what is the wavelength λ of the photon that has been released in part b?
The change in energy when the electron drops to the ground state can be calculated. The wavelength of the released photon can be determined using the equation: wavelength = hc / energy.
Explanation:When an electron drops from a higher energy level to the ground state, it releases energy in the form of a photon. The change in energy can be calculated by taking the difference between the initial energy and the energy of the ground state. The wavelength of the photon can be determined using the equation:
wavelength = hc / energy
where h is Planck's constant (6.626 x 10^-34 J s), c is the speed of light (3.00 x 10^8 m/s), and energy is the change in energy calculated earlier.
Which element would release the most energy while adding an electron to a neutral atom in the gas phase?
Helium has a density of 1.79 x 10-4 g/mL at standard temperature and pressure. A balloon has a volume of 6.3 liters. Calculate the mass of helium that it would take to fill the balloon.
35,000 g
1.1 x 10-3 g
2.8 x 10-5 g
1.1 g
The mass of helium that it would take to fill the balloon is 1.1 grams.
What is the relation between mass and density?Relation between the mass of any substance and their density will be represented as:
Density = Mass / Volume
Given that,
Density of helium gas = 1.79 × 10⁻⁴ g/mL
Volume of balloon in which gas is present = 6.3L = 6300 mL
On putting all these values, we get
Mass = (1.79 × 10⁻⁴ g/mL)(6300mL) = 1.12 grams
Hence required mass of helium is 1.1 g.
To know more about density & mass, visit the below link:
https://brainly.com/question/406690
#SPJ2
Air is 21% oxygen by volume. Oxygen has a density of 1.31 g/L. What is the volume in liters of a room that holds enough air to contain 55kg of oxygen?
Answer:
199,927.29 L is the volume air that holds enough air to contain 55 kg of oxygen.
Explanation:
Density of oxygen = 1.31 g/L
Mass of oxygen gas,m = 55 kg = 55,000 g
Volume of the oxygen gas = V
Volume of the air = [tex]V_a[/tex]
[tex]Density=\frac{Mass}{Volume}[/tex]
[tex]1.31 g/L=\frac{55,000 g}{V}[/tex]
V = 41.984.732 L
Air is 21% oxygen by volume.That is in 100 L of air 21 L of oxygen is present.
So, when oxygen gas is 41.984.732 L the volume of the air will be:
[tex]21\%=\frac{41.984.732 L}{V_a}\times 100[/tex]
[tex]V_a=199,927.29 L[/tex]
199,927.29 L is the volume air that holds enough air to contain 55 kg of oxygen.
The volume of the room that can hold enough air containing 55 Kg of oxygen is 199927.29 L
We'll begin by converting 55 kg of oxygen to grams (g). This can be obtained as follow:
1 Kg = 1000 g
Therefore,
55 kg = 55 × 1000
55 Kg = 55000 gNext, we shall determine the volume of oxygen. This can be obtained as follow:
Mass of oxygen = 55000 kg
Density of oxygen = 1.31 g/L
Volume of oxygen =?[tex]Density = \frac{mass}{volume} \\\\1.31 = \frac{55000 }{volume}[/tex]
Cross multiply
1.31 × Volume = 55000
Divide both side by 1.31
Volume = 55000 / 1.31
Volume of oxygen = 41984.73 LFinally, we shall determine the volume of the room by calculating the volume of air. This can be obtained as follow:
Volume of oxygen = 41984.73 L
Percentage of oxygen in air = 21%
Volume of air =?[tex]Percentage of oxygen =\frac{volume of oxygen}{Volume of air} * 100[/tex]
21% = [tex]\frac{41984.73}{Volume of air}[/tex]
[tex]0.21 = \frac{41984.73}{Volume of air }[/tex]
Cross multiply
0.21 × Volume of air = 41984.73
Divide both side by 0.21
[tex]Volume of air = \frac{41984.73}{0.21}\\\\[/tex]
Volume of air = 199927.29 LTherefore, we can conclude that the volume of the room that can hold enough air containing 55 Kg of oxygen is 199927.29 L
Learn more: https://brainly.com/question/24611641
A solution of cough syrup contains 5.00% active ingredient by volume. If the total volume of the bottle is 11.0 mL , how many milliliters of active ingredient are in the bottle?
Taking into account the definition of percentage in volume, 0.55 mL of active ingredient are in the bottle.
In first place, every solution consists of two classes of components: the solvent and the solute.
The solvent of a solution is the component that is capable of dissolving others and is usually the component present in greater quantity.
The solute is the component that is dissolved in the solvent and is usually present in smaller quantities. A solution can contain more than one solute.
On the other side, the concentration of a solution is the amount of solute in a given amount of solution.
The percentage in volume (% v / v) is a measure of the concentration that indicates the volume of solute per 100 units of volume of the solution and can be calculated mathematically by means of the expression:
[tex]percentage in volume=\frac{solute volume}{solution volume}x100[/tex]
In this case:
percentage in volume= 5 %solute volume= ?solution volume= 11 mLReplacing in the expresion for percentage in volume:
[tex]5=\frac{solute volume}{11 mL}x100[/tex]
Solving:
5× 11 mL= solute volume×100
55 mL=solute volume×100
55 mL÷100= solute volume
0.55 mL= solute volume
Finally, 0.55 mL of active ingredient are in the bottle.
Learn more:
https://brainly.com/question/1713808https://brainly.com/question/14571931?referrer=searchResultsTo find the amount of active ingredient in the cough syrup, you multiply the percentage concentration (5.00%) by the total volume of the syrup (11.0 mL) and divide by 100, yielding 0.55 mL of active ingredient.
Explanation:To calculate the amount of active ingredient in a cough syrup solution, we use the percentage concentration by volume, which in this case is 5.00% v/v. This means that for every 100 mL of the total solution, there are 5 mL of the active ingredient. Given that the total volume of the cough syrup bottle is 11.0 mL, we can determine the volume of active ingredient using the following calculation:
Volume of active ingredient = Percentage concentration × Total volume / 100
Volume of active ingredient = 5.00% × 11.0 mL / 100 = 0.55 mL
Therefore, there are 0.55 milliliters of active ingredient in the 11.0 mL bottle of cough syrup.
What happens if you cool the crystallization solution in a container of ice that is too big?
what is the molar mass of potassium
94.0, is the answer for sure
What is the atomic number of an element that has 43 protons and 50 neutrons?
Draw two lewis structures for a compound with the formula c4h10. no atom bears a charge, and all carbon atoms have complete octets.
The valence shell electrons of a molecule are shown in an extremely simplified manner by a Lewis structure.
Butane is an alkane represented by C4H10. All the bonds in this situation are single bonds, since this substance is an alkane. Two shared electrons are present in every bond. Each carbon atom requires 8 electrons around it in order to follow the octet rule.
The octet rule was fulfilled by the hydrogen bonds, eliminating the necessity for the electron dots. Straight-chained butane is the initial structure. The y-chained isobutane is the second structure.
The Lewis structures for a compound with the formula C₄H₁₀ is attached in the image below.
Learn more about Lewis structures, here:
https://brainly.com/question/29603042
#SPJ6
List and describe the steps of the scientific method.
The boiling point of a liquid is 64 °c and the enthalpy change for the conversion of this liquid to the gas is 32.21 kj/mole. what is the entropy change for vaporization, δsvap?
Entropy change of vaporization is simply the ratio of enthalpy change and the temperature in Kelvin.
Temperature = 64 + 273.15 = 337.15 K
Hence,
δsvap = (32.21 kJ / mole) / 337.15 K
δsvap = 0.0955 kJ / mole K = 95.5 J / mole K
Answer:
[tex]\Delta S_{vap}=0.096\frac{kJ}{mol*K} =96\frac{J}{mol*K}[/tex]
Explanation:
Hello,
In this case, the entropy of vaporization (conversion from liquid to gas) is mathematically defined in terms of enthalpy and the boiling temperature in K as shown below:
[tex]\Delta S_{vap}=\frac{\Delta H_{vap}}{T_b}[/tex]
Thus, for the given data we obtain:
[tex]\Delta S_{vap}=\frac{32.21kJ/mol}{(64+273.15)K} \\\\\Delta S_{vap}=0.096\frac{kJ}{mol*K} =96\frac{J}{mol*K}[/tex]
Best regards.
Water is formed when two hydrogen atoms bond to an oxygen atom.
The hydrogen and the oxygen in this example are different
A) complexes.
B) compounds.
C) elements.
D) mixtures.
Write the symbol for the ion formed when each element gains electrons and attains a noble-gas electron configuration. Br, H, Se.
Explanation:
When an atom gain electrons then it acquires a negative charge whereas when an atom loses electrons then it acquires a positive charge.
For example, atomic number of bromine is 35 and its electronic distribution is 2, 8, 18, 7. So, in order to gain stability bromine accepts one electrons and thus it acquires a negative charge as [tex]Br^{-}[/tex].
Therefore, the symbol for the ion formed when each given element gains electrons and attains a noble-gas electron configuration are as follows.
Br changes into [tex]Br^{-}[/tex].H changes into [tex]H^{-}[/tex].Se changes into [tex]Se^{2-}[/tex].
what type of equation is Cu + 2AgNO3=Cu(NO3)2 + 2Ag?
The given equation is a double-replacement reaction where solid copper reacts with an aqueous solution of silver nitrate to produce a solution of copper(II) nitrate and solid silver.
Explanation:The given equation is a chemical equation, specifically a double-replacement reaction. In this type of reaction, the cations are swapped between two compounds. In this case, solid copper (Cu) reacts with an aqueous solution of silver nitrate (AgNO3) to produce a solution of copper(II) nitrate (Cu(NO3)2) and solid silver (Ag). The balanced equation for this reaction is:
Cu + 2AgNO3 = Cu(NO3)2 + 2Ag
Typically, water runs through the baseboard copper tubing and, therefore, fresh hot water is constantly running through the piping. However, consider a pipe where water was allowed to sit in the pipe. The hot water cools as it sits in the pipe. What is the temprature change, (ΔT), of the water if 190.0 g of water sat in the copper pipe from part A, releasing 2284 J of energy to the pipe? The specific heat of water is 4.184 (J/g)⋅∘C
The temperature change (ΔT) of the water after sitting in the copper pipe can be found using the formula for heat transfer (q = mcΔT), considering that the water releases 2284 J of energy. Thus, ΔT = 2284 / (190.0 * 4.184).
Explanation:The temperature change of water in the copper pipe can be determined by using the formula for heat transfer (q = mcΔT), where q is heat in joules, m is the mass in grams, c is the specific heat capacity, and ΔT is the temperature change in degrees Celsius. Here, the initial temperature of the water is not given, but we know that the water releases 2284 J of energy. Plugging in the mass (190.0 g), the specific heat of water (4.184 J/g °C), and the heat (2284 J) into the formula, we get the equation
2284 = 190 * 4.184 * ΔT.
Solving for ΔT, we get ΔT = 2284 / (190.0 * 4.184), which should provide the temperature change of the water after sitting in the copper pipe.
Learn more about Heat Transfer here:https://brainly.com/question/13433948
#SPJ12
For most compounds in which a nitrogen atom bears no formal charge, the valence of this nitrogen atom is
Answer:
3
Explanation:
Hello,
In this case, as nitrogen is not bearing any formal charge, we apply its mathematical definition to find such oxidation state:
Formal charge= # of valence electrons - # of lone-pair electrons - 1/2 # of bond pair electrons
Since no formal charge is born, no lone-pair electrons are formed and 6 bond pair electrons are always present for the nitrogen to complete the octate, the valence turns out into:
# of valence electrons = 0 + 0 + 1/2 * 6
# of valence electrons = 3
Best regards.
A teacher listed the following two processes. • Process 1: water changing to ice in a freezer • Process 2: steam coming out of a kettle filled with hot of water Which table correctly identifies the change of state taking place in each example?
What kind of reaction adds water to break large molecules into subunits?
What is the henry's law constant for co2 at 20∘c? express your answer to three significant figures and include the appropriate units?
The value of Henry’s law constant for [tex]{\text{C}}{{\text{O}}_{\text{2}}}[/tex] at [tex]20{\text{ }}^\circ {\text{C}}[/tex] is [tex]\boxed{3.70 \times {{10}^{ - 2}}{\text{ L}} \cdot {\text{atm}} \cdot {\text{mo}}{{\text{l}}^{ - 1}}}[/tex].
Further explanation:
Solubility
It is that property of substance by virtue of which it becomes able to dissolve in other substances. It is measured in terms of the maximum amount of solute that can be dissolved in the given amount of solvent.
Henry’s Law
According to this law, solubility of gas dissolved in the liquid is directly related to the partial pressure of gas. High partial pressure means high solubility and vice-versa.
Mathematically,
[tex]{{\text{S}}_{{\text{gas}}}} \propto {{\text{P}}_{{\text{gas}}}}[/tex] …… (1)
To remove the proportionality constant in equation (1), constant known as Henry’s constant is incorporated and equation (1) modifies to,
[tex]{{\text{S}}_{{\text{gas}}}} = {{\text{k}}_{\text{H}}}{\mathbf{ \times }}\;{{\text{P}}_{{\text{gas}}}}[/tex] …… (2)
Here,
[tex]{{\text{S}}_{{\text{gas}}}}[/tex] is the solubility of gas.
[tex]{{\text{k}}_{\text{H}}}[/tex] is Henry’s constant.
[tex]{{\text{P}}_{{\text{gas}}}}[/tex] is the pressure of gas.
Equation (2) can be rearranged in order to calculate Henry’s constant [tex]\left( {{{\text{k}}_{\text{H}}}} \right)[/tex] and equation (2) becomes,
[tex]{{\text{k}}_{\text{H}}} = \dfrac{{{{\text{S}}_{{\text{gas}}}}}}{{{{\text{P}}_{{\text{gas}}}}}}\;[/tex] …… (3)
At [tex]20{\text{ }}^\circ {\text{C}}[/tex] , the value of Henry’s law constant for [tex]{\text{C}}{{\text{O}}_{\text{2}}}[/tex] up to three significant figures is [tex]3.70 \times {10^{ - 2}}{\text{ L}} \cdot {\text{atm}} \cdot {\text{mo}}{{\text{l}}^{ - 1}}[/tex].
Learn more:
What is the concentration of alcohol in terms of molarity? https://brainly.com/question/9013318 Determine whether solubility will increase, decrease or remains the same: https://brainly.com/question/2802008
Answer details:
Grade: Senior School
Subject: Chemistry
Chapter: Solutions
Keywords: solubility, gas, Henry’s law, partial pressure, solubility, dissolve, CO2, three significant figures, [tex]3.70*10^-2 L atm/mol,[/tex] high partial pressure, high solubility.
The Henry's law constant for CO₂ at 20°C is 3.91 × 10⁻² M/atm. The pressure required to achieve a CO₂ concentration of 6.90 × 10⁻² M at 20°C is approximately 23.4 atm.
Part A - To answer the question, we need to understand that Henry's Law states that the concentration of a gas in a liquid is directly proportional to the partial pressure of that gas above the liquid. The law is represented by the equation:
C = kH * P
where C is the concentration of the gas, kH is the Henry's law constant, and P is the partial pressure of the gas.
Given that the Henry's law constant for CO₂ in water at 25°C is 3.4 × 10⁻² M/atm, we can use interpolated values to find the constant at 20°C. Experimentally, at 20°C, the Henry's law constant for CO₂ is found to be 3.91 × 10⁻² M/atm.
Therefore, the Henry's law constant for CO₂ at 20°C is 3.91 × 10⁻² M/atm.
Part B: Pressure Required for CO₂ Concentration
To find the pressure required to achieve a CO₂ concentration of 6.90 × 10⁻² M at 20°C, we can use Henry's Law:
pCO₂ = KH × [CO₂]
where pCO₂ is the partial pressure of CO₂, KH is the Henry's Law constant, and [CO₂] is the concentration of CO₂ in moles per liter.
Rearranging the equation to solve for pCO2:
pCO₂ = KH × [CO₂] = 3.39 × 10² L·atm/mol × 6.90 × 10⁻² mol/L ≈ 23.4 atm
So, the pressure required to achieve a CO₂ concentration of 6.90 × 10⁻² M at 20°C is approximately 23.4 atm.
Complete Question - Part A What is the Henry's law constant for CO₂ at 20°C? Express your answer to three significant figures and include the appropriate units. Part B What pressure is required to achieve CO₂ concentration of 6.90x10⁻² M at 20°C? Express your answer to three significant figures and include the appropriate units.
Determine the number of atoms in 1.70 ml of mercury. (the density of mercury is 13.5 g/ml.)
To determine the number of atoms in 1.70ml of mercury, we have to determine the moles of mercury.
First find the mass in grams by using the formula:
Mass = volume x density
(1.70 mL Hg) x (13.5 g/mL) = 22.95 g Hg
Now find number of moles;
(22.95 g Hg) x (1 mol Hg/200.59 g/mol) = 0.1144 mol
Hg
For number of atoms multiply with Avogardro's number that is 6.023 x 10²³
(0.1144 mol Hg) x (6.023 x 10²³ atoms/mol) = 6.89
x 10²² atoms Hg
So, there is 6.89 x 10²² atoms of mercury are present in 1.70ml of mercury.
Etahnol has a density of 0.79 g/mL. What is the volume, in quarts, of 1.65 kg of alcohol?
Formaldehyde, ch2o, is used as an embalming agent. draw the structure of ch2o including lone pairs.formaldehyde, ch2o, is used as an embalming agent. draw the structure of ch2o including lone pairs.formaldehyde, ch2o, is used as an embalming agent. draw the structure of ch2o including lone pairs.
The structure of formaldehyde (CH2O) features a carbon atom double-bonded to an oxygen atom with two lone pairs, and two hydrogen atoms single-bonded to the carbon, resulting in a trigonal planar molecular geometry with bond angles around 120°.
Explanation:Formaldehyde, with the chemical formula CH2O, is a simple aldehyde commonly used as an embalming agent and preservative. In its Lewis structure, the carbon atom is double-bonded to the oxygen, which also has two lone pairs of electrons, creating a region of high electron density. This double bond contributes to the molecule's trigonal planar geometry, with bond angles close to 120°. Each of the two hydrogen atoms is single-bonded to the carbon atom, completing the tetrahedral geometry around the carbon atom. The molecular structure is depicted as:
:O:
H-C-H
The oxygen atom has two lone pairs of electrons, and there are three regions of bonding around the carbon atom, which has no lone pairs, providing an acceptable Lewis electron structure for formaldehyde.
What are groups 1, 2, and 3 examples of on a periodic table of elements?
A) Metals
B) Nonmetals
C) Metalloids
D) Noble gass
Answer:
A) Metals
Explanation: They mainly explain metals in "periodic table" well it's in it too.
How many atoms are in 80.16g of calcium?
You are about to perform some intricate electrical studies on single skeletal muscle fibers from a gastronemius muscle. but first, you must prepare 6l of a 170 mm nacl solution in which to bath the isolated muscle during your studies. how many grams of nacl must you weigh out on the lab balance to prepare this bath solution? (hint: the molecular weight of nacl is 58.44 grams/mole).
To prepare a 6L solution of 170 mM NaCl, you need to calculate the moles required and use the molecular weight of NaCl to convert to grams. Multiply the molarity by the volume to get moles, and then multiply by the molecular weight to get 59.6088 grams.
Explanation:To prepare a 170 mM NaCl solution, you will need to calculate the number of grams of NaCl required. First, you need to understand the concentration units. Here, 170 mM (millimolar) indicates 170 millimoles of NaCl are needed per liter of solution. To find out how many millimoles you need for 6 liters, you multiply 170 mmol/L by 6 L, yielding 1020 mmol, or 1.020 mol since 1000 mmol is equivalent to 1 mol.
Next, you use the molecular weight of NaCl, which is 58.44 g/mol, to convert moles to grams. The calculation is:
1.020 mol × 58.44 g/mol = 59.6088 gTherefore, you would need to weigh out 59.6088 grams of NaCl and dissolve it in enough water to make the total volume up to 6 liters.
Using the mass of a proton 1.0073 amu and assuming it's diameter is1.0x10^-15, calculate the density of a proton in g/cm^3. I'm not sure about how to convert amu to grams. Thanksfor the help!!
What would you predict is worse based on your knowledge of quantum theory - a weak beam of ultraviolet light, or an intense beam of infrared light?
Answer : Amongst the given choices a weak beam of ultraviolet light is considered to be the worst as compared to others.
The wavelength of UV light is from 10 nm to 400 nm, and its energy varies from 3 eV to 124 eV.
As a single beam of UV light will have much energy in each photon which is emitted. The damage done by UV rays is observed to be very harmful in human cells and may cause many diseases. UV rays can also damage the eyes as more than 99% of UV radiation is absorbed by the front of the eyes. It can also lead to ultimate blindness. Therefore, it is considered to be much worse than an intense beam of infrared light.
When solid potassium chlorate is heated, it decomposes to form solid potassium chloride and oxygen gas. express your answer as a balanced chemical equation. identify all of the phases in your answer?
A 10.0 gram piece of metal is placed in an insulated calorimeter containing 250.0 grams of water initially at 20.0°c. if the final temperature of the mixture is 25.0°c, what is the heat change of piece of metal? 5230 j â5230 j 209 j â209 j 5440 j
How do electrons differ from protons and neutrons?
A.
They do not move.
B.
They are larger.
C.
They are not in a fixed position.
D.
They are located in the nucleus
Answer:
Option c, They are not in a fixed position.
Explanation:
As per Bohr's model of atomic atoms,
Electrons revolve around around the nucleus in a fixed path or energy level. Electrons revolving in these energy levels do not radiate energy.
Therefore, electrons are not present in a fixed position. They present outside the nucleus.
Mass of protons and neutrons are same whereas electrons are smaller.
Among the given options, options c best describe the difference between electrons from protons and neutrons.