As for splitting/layering, the NP3 has 2 sound generating sections, the Piano section and the Sample Synth section. A new NP3 comes loaded with lots of sounds, but you can add and delete easily. Irrequieto, you can view lists of available NP3 sounds on the Nord website under "Piano Library," "Sample Library 2.0" and "Sample Library Archive." You can even listen to some of them. anotherscott Posts: 3181 Joined:, 04:50 Has thanked: 26 times Been thanked: 972 times Yes, you're right, the NP3 doesn't have the synth/organ controls, but you have to look more deeply and realize, not only are the controls missing, but virtually all the underlying electronics for those controls are missing as well, so there is no way to generate those sounds, regardless of whether or not you care about having the controls. Almost none of the synth parameters of the NS2 exist in the NP3. The organ engine (which does not use samples) does not exist on the NP3. The fact that the samples are the same is only one small piece of the puzzle. Besides different file format, the electronics to create the NS2 sounds don't all exist in the NP3. Programs are not compatible between the two. The available samples for the NS2 and NS3 are the same (so far, at least), but the programs are different. The ns2p files of NS2 are compatible with NP3? Anyone can attach the PROGRAM list of Nord Piano 3? I need also split and layer options (piano + pad for example). Nord Piano 3 have samples and programs similar to Nord Stage 2 EX? I don't like Nord Stage 3 program/samples, I like Nord Stage 2 EX programs/samples, I need to know if the programs and the samples of Nord Piano 3 are similar to NS2 or to NS3. By extrapolation, we expect all the group 2 elements to have an ns 2 electron configuration.Irrequieto wrote:I don't need the controls for organ / synth etc, i only need samples for pianos, synth and some organ. The next element down, magnesium, is expected to have exactly the same arrangement of electrons in the n = 3 principal shell: s 2. Beginning with beryllium, we see that its nearest preceding noble gas is helium and that the principal quantum number of its valence shell is n = 2.ī Thus beryllium has an s 2 electron configuration. Write the valence electron configuration of each element by first indicating the filled inner shells using the symbol for the nearest preceding noble gas and then listing the principal quantum number of its valence shell, its valence orbitals, and the number of valence electrons in each orbital as superscripts.Ī The group 2 elements are in the s block of the periodic table, and as group 2 elements, they all have two valence electrons.
Locate the nearest noble gas preceding each element and identify the principal quantum number of the valence shell of each element. Identify the block in the periodic table to which the group 2 elements belong.Use the periodic table to predict the valence electron configuration of all the elements of group 2 (beryllium, magnesium, calcium, strontium, barium, and radium).Īsked for: valence electron configurations For elements after No, the electron configurations are tentative. The electron configurations of the elements indicated in blue are also anomalous, but the reasons for the observed configurations are more complex. The electron configurations of elements indicated in red are exceptions due to the added stability associated with half-filled and filled subshells. As a result, the periodic table can be divided into “blocks” corresponding to the type of subshell that is being filled, as illustrated in Figure \(\PageIndex\): Electron Configurations of the Elements. Although the table was originally organized on the basis of physical and chemical similarities between the elements within groups, these similarities are ultimately attributable to orbital energy levels and the Pauli principle, which cause the individual subshells to be filled in a particular order. To correlate the arrangement of atoms in the periodic table results in blocks corresponding to filling of the ns, np, nd, and nf orbitalsĪs you have learned, the electron configurations of the elements explain the otherwise peculiar shape of the periodic table.
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