You do it by finding Uuh in the periodic table and knowing that it will have chemical properties that are similar to those in the group with it. Here is a periodic table on the web. Find element #116 and observe the other elements in the same group (O, S, Se, Te, Po). We know little about Uuh BUT we can make educated guesses regarding some of its chemical properties by knowing the chemistry of, for example, S. Look for the fluoride(s) of S or hydrides of O, S, Se to make those guesses. Here is the site.

http://www.webelements.com/

Please help me find the highest hydride and highest fluoride of ununhexium. And please EXPLAIN how did you do it..I copletely don't understand how to do it.

I know that Uuh is in Group 16 and period 7..but what then?

Ununhexium (Uuh) is now known as Livermorium (Lv) with the atomic number 116. It belongs to Group 16 and Period 7 of the periodic table. As we know little about Livermorium's specific chemical properties, we can make educated guesses by observing the trends and properties of other elements in the same group (Group 16, also known as chalcogens).

For determining the hydrides and fluorides, let's look at the general chemical properties of the Group 16 elements. Group 16 elements form compounds with hydrogen called hydrides with the general formula H2X, where X is the Group 16 element. Thus, for Livermorium, we can expect the highest hydride to be H2Lv.

Now let's look at the fluorides of Group 16 elements. These elements form fluorides with the general formula XF6, where X is the Group 16 element. Thus, for Livermorium, we can expect the highest fluoride to be LvF6.

Keep in mind that these are educated guesses based on the chemical properties and trends of the elements in Group 16. The actual properties of Livermorium may differ due to its highly unstable nature and short half-life. The synthesis and study of Livermorium and its compounds have been very limited.

To find the highest hydride and highest fluoride of ununhexium (Uuh), we can refer to the elements in the same group on the periodic table and their corresponding hydrides and fluorides.

1. Start by opening the website http://www.webelements.com/ for the periodic table.
2. Locate ununhexium (Uuh) in the periodic table. As you mentioned, Uuh is in Group 16 and period 7.
3. In the same group (Group 16) as Uuh, you mentioned the elements are: O (oxygen), S (sulfur), Se (selenium), Te (tellurium), and Po (polonium).
4. Click on each of these elements, one by one, to observe their chemical properties and compounds.
5. Look for the hydrides and fluorides of each element to make educated guesses about Uuh's possible hydrides and fluorides.

For finding the highest hydride of Uuh:
- Oxygen (O) forms hydrides called oxides, with the highest being water (H2O).
- Sulfur (S) forms hydrides called sulfides, with hydrogen sulfide (H2S) being a common example.
- Selenium (Se) forms hydrides called selenides, with hydrogen selenide (H2Se) being known.
- Tellurium (Te) forms hydrides called tellurides, with hydrogen telluride (H2Te) being one example.
- Polonium (Po) forms polonides, but there are limited examples available.

Considering these patterns, it is reasonable to expect that ununhexium (Uuh) would form a hydride called ununhexium hydride (UuhH2).

For finding the highest fluoride of Uuh:
- Sulfur (S) forms fluorides, such as sulfur hexafluoride (SF6) being a well-known compound.
- Oxygen (O) forms fluorides, such as oxygen difluoride (OF2) being an example.
- Selenium (Se) forms fluorides, such as selenium hexafluoride (SeF6).
- Tellurium (Te) forms fluorides, but the highest fluoride is not well-known.
- Polonium (Po) forms polonium hexafluoride (PoF6).

Based on these patterns, it is reasonable to predict that ununhexium (Uuh) would likely form a fluoride called ununhexium hexafluoride (UuhF6).

Please note that these are educated guesses based on the general trends and properties of elements in the same group. Since ununhexium (Uuh) is a highly unstable and synthetic element, there is limited experimental data available to confirm its chemical properties and compounds.

To find the highest hydride and highest fluoride of ununhexium (Uuh), we can use the periodic table and the chemistry of elements in the same group and period.

First, let's locate ununhexium on the periodic table. Since we know it is in Group 16 and period 7, let's focus on those sections. Scroll down on the website you provided (http://www.webelements.com/) or try searching for "periodic table" on any search engine. Look for the element with atomic number 116.

Once you find Uuh, take note of the other elements in the same group (Group 16). In this case, it is O (oxygen), S (sulfur), Se (selenium), Te (tellurium), and Po (polonium). These elements have similar chemical properties due to being in the same group, and we can use their compounds as a reference to make educated guesses about Uuh's properties.

To determine the highest hydride of Uuh, we can look at the hydrides of the elements in the same group. Hydrides are compounds formed by the combination of an element with hydrogen.

For example, oxygen forms the hydride H2O (water), sulfur forms H2S (hydrogen sulfide), selenium forms H2Se (selenium hydride), and tellurium forms H2Te (tellurium hydride). From this pattern, we can make an educated guess that the highest hydride of Uuh could be UuhH2.

Similarly, to determine the highest fluoride of Uuh, we can look at the fluorides of the elements in Group 16. Fluorides are compounds formed by the combination of an element with fluorine.

For example, oxygen forms OF2 (oxygen difluoride), sulfur forms SF6 (sulfur hexafluoride), selenium forms SeF6 (selenium hexafluoride), and tellurium forms TeF6 (tellurium hexafluoride). From this pattern, we can make an educated guess that the highest fluoride of Uuh could be UuhF6.

It's important to note that these are educated guesses based on the chemistry of similar elements in the same group. Since Uuh is a superheavy synthetic element, its properties are not yet well-known, and it may behave differently from its lighter group members. Further research and experimental data would be needed to confirm these predictions.

Remember, the periodic table is a useful tool to understand and predict chemical properties, but it is also important to consider experimental data and additional research for accurate information on newly discovered elements.