When metals react, they lose electrons
to become stable and sometimes form a compound.
Now, electrons are negatively charged, and the nucleus
, due to the presence of protons, is positively charged.
As the atom of the metal
gets bigger in size, the valency shell, which holds the valency electron, becomes farther away from the nucleus.
The attraction between the valency electron (on the last shell) and the nucleus decreases, so the atom of this type of metal is considered to be reactive as the electron becomes easily lost due to weak forces pulling it towards the nucleus.
Yes, several chemical reactions are affected by magnetic or electric fields.
A chemical reaction. An electric field gradient ( electric potential)
This branch of chemistry is called electrochemistry.
i really don't know for sure but i think its yes
In an electrically neutral, there are as many oppositely charged particles as the electrons. Therefore, the net electrical charge come out to be zero.
When metals react, they lose electrons to become stable and sometimes form a compound
Yes, several chemical reactions are affected by magnetic or electric fields.
G. C. Akerlof has written: 'Bibliography of chemical reactions in electric discharges' -- subject(s): Bibliography, Chemical reactions, Electric discharges through gases
A chemical reaction. An electric field gradient ( electric potential)
The electrochemistry object of study are the chemical reactions in an electrolyte in the presence of an electric current.
This branch of chemistry is called electrochemistry.
Lightning
Electrochemistry is the study of chemical reactions that occur due to electric charges. The most notable and ubiquitous application is the battery.
Metals can be thought of as a lattice of metal ions surrounded by electrons. Again the force of attraction is electrostatic. These electrons are delocalised and metals get their conductiity from thir movement under an applied electric field. Positive metal ions in chemical compounds are surrounded by negativelly charged anions. The force between the oppositely charged ions is electrostatic.
i really don't know for sure but i think its yes
P. L. Spedding has written: 'Chemical engineering design' 'Chemical reactions in non-disruptive electric discharges'
In most cases, chemical energy stored in the battery produces the electric current. Rechargeable batteries are capable of taking electric currents and using them to reverse the chemical reactions, thus gaining more chemical energy that can be used readily.