Emanuel Lodewijk Elte

Emanuel Lodewijk Elte (16 March 1881 in Amsterdam – 9 April 1943 in Sobibór)^[1] was a Dutch mathematician. He is noted for discovering and classifying semiregular polytopes in dimensions four and higher.

Elte's father Hartog Elte was headmaster of a school in Amsterdam. Emanuel Elte married Rebecca Stork in 1912 in Amsterdam, when he was a teacher at a high school in that city. By 1943 the family lived in Haarlem. When on January 30 of that year a German officer was shot in that town, in reprisal a hundred inhabitants of Haarlem were transported to the Camp Vught, including Elte and his family. As Jews, he and his wife were further deported to Sobibór, where they were murdered; his two children were murdered at Auschwitz.^[1]

Elte's semiregular polytopes of the first kind edit

His work rediscovered the finite semiregular polytopes of Thorold Gosset, and further allowing not only regular facets, but recursively also allowing one or two semiregular ones. These were enumerated in his 1912 book, The Semiregular Polytopes of the Hyperspaces.^[2] He called them semiregular polytopes of the first kind, limiting his search to one or two types of regular or semiregular k-faces. These polytopes and more were rediscovered again by Coxeter, and renamed as a part of a larger class of uniform polytopes.^[3] In the process he discovered all the main representatives of the exceptional E_n family of polytopes, save only 1₄₂ which did not satisfy his definition of semiregularity.

Summary of the semiregular polytopes of the first kind^[4]
n	Elte notation	Vertices	Edges	Faces	Cells	Facets	Schläfli symbol	Coxeter symbol
Polyhedra (Archimedean solids)
3	tT	12	18	4p₃+4p₆			t{3,3}
	tC	24	36	6p₈+8p₃			t{4,3}
	tO	24	36	6p₄+8p₆			t{3,4}
	tD	60	90	20p₃+12p₁₀			t{5,3}
	tI	60	90	20p₆+12p₅			t{3,5}
	TT = O	6	12	(4+4)p₃			r{3,3} = {3^1,1}	0₁₁
	CO	12	24	6p₄+8p₃			r{3,4}
	ID	30	60	20p₃+12p₅			r{3,5}
	P_q	2q	4q	2p_q+qp₄			t{2,q}
	AP_q	2q	4q	2p_q+2qp₃			s{2,2q}
semiregular 4-polytopes
4	tC₅	10	30	(10+20)p₃	5O+5T		r{3,3,3} = {3^2,1}	0₂₁
	tC₈	32	96	64p₃+24p₄	8CO+16T		r{4,3,3}
	tC₁₆=C₂₄(*)	48	96	96p₃	(16+8)O		r{3,3,4}
	tC₂₄	96	288	96p₃ + 144p₄	24CO + 24C		r{3,4,3}
	tC₆₀₀	720	3600	(1200 + 2400)p₃	600O + 120I		r{3,3,5}
	tC₁₂₀	1200	3600	2400p₃ + 720p₅	120ID+600T		r{5,3,3}
	HM₄ = C₁₆(*)	8	24	32p₃	(8+8)T		{3,3^1,1}	1₁₁
	–	30	60	20p₃ + 20p₆	(5 + 5)tT		2t{3,3,3}
	–	288	576	192p₃ + 144p₈	(24 + 24)tC		2t{3,4,3}
	–	20	60	40p₃ + 30p₄	10T + 20P₃		t_0,3{3,3,3}
	–	144	576	384p₃ + 288p₄	48O + 192P₃		t_0,3{3,4,3}
	–	q²	2q²	q²p₄ + 2qp_q	(q + q)P_q		2t{q,2,q}
semiregular 5-polytopes
5	S₅¹	15	60	(20+60)p₃	30T+15O	6C₅+6tC₅	r{3,3,3,3} = {3^3,1}	0₃₁
	S₅²	20	90	120p₃	30T+30O	(6+6)C₅	2r{3,3,3,3} = {3^2,2}	0₂₂
	HM₅	16	80	160p₃	(80+40)T	16C₅+10C₁₆	{3,3^2,1}	1₂₁
	Cr₅¹	40	240	(80+320)p₃	160T+80O	32tC₅+10C₁₆	r{3,3,3,4}
	Cr₅²	80	480	(320+320)p₃	80T+200O	32tC₅+10C₂₄	2r{3,3,3,4}
semiregular 6-polytopes
6	S₆¹ (*)						r{3⁵} = {3^4,1}	0₄₁
	S₆² (*)						2r{3⁵} = {3^3,2}	0₃₂
	HM₆	32	240	640p₃	(160+480)T	32S₅+12HM₅	{3,3^3,1}	1₃₁
	V₂₇	27	216	720p₃	1080T	72S₅+27HM₅	{3,3,3^2,1}	2₂₁
	V₇₂	72	720	2160p₃	2160T	(27+27)HM₆	{3,3^2,2}	1₂₂
semiregular 7-polytopes
7	S₇¹ (*)						r{3⁶} = {3^5,1}	0₅₁
	S₇² (*)						2r{3⁶} = {3^4,2}	0₄₂
	S₇³ (*)						3r{3⁶} = {3^3,3}	0₃₃
	HM₇(*)	64	672	2240p₃	(560+2240)T	64S₆+14HM₆	{3,3^4,1}	1₄₁
	V₅₆	56	756	4032p₃	10080T	576S₆+126Cr₆	{3,3,3,3^2,1}	3₂₁
	V₁₂₆	126	2016	10080p₃	20160T	576S₆+56V₂₇	{3,3,3^3,1}	2₃₁
	V₅₇₆	576	10080	40320p₃	(30240+20160)T	126HM₆+56V₇₂	{3,3^3,2}	1₃₂
semiregular 8-polytopes
8	S₈¹ (*)						r{3⁷} = {3^6,1}	0₆₁
	S₈² (*)						2r{3⁷} = {3^5,2}	0₅₂
	S₈³ (*)						3r{3⁷} = {3^4,3}	0₄₃
	HM₈(*)	128	1792	7168p₃	(1792+8960)T	128S₇+16HM₇	{3,3^5,1}	1₅₁
	V₂₁₆₀	2160	69120	483840p₃	1209600T	17280S₇+240V₁₂₆	{3,3,3^4,1}	2₄₁
	V₂₄₀	240	6720	60480p₃	241920T	17280S₇+2160Cr₇	{3,3,3,3,3^2,1}	4₂₁