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The power of one qubit in quantum simulation algorithms,

S. Polla (22 February 2024). Subsequent employment: Leiden University.

On quantum transport in flat-band materials,

D.O. Oriekhov (4 October 2023). Subsequent employment: Delft University of Technology.

On topological properties of massless fermions in a magnetic field,

G. Lemut (13 June 2023). Subsequent employment: Free University in Berlin.

Anyonic, cosmic, and chaotic: three faces of Majorana fermions,

Y.I. Cheipesh (17 November 2022). Subsequent employment: Orange Quantum Systems.

Optimization of quantum algorithms for near-term quantum computers,

X. Bonet-Monroig (2 November 2022). Subsequent employment: Leiden University.

On cluster algebras and topological string theory,

M. Semenyakin (15 September 2022). Subsequent employment: Perimeter Institute.

Strategies for braiding and ground-state preparation in digital quantum hardware,

Y. Herasymenko (20 April 2022). Subsequent employment: QuTech/QuSoft.

On the coexistence of Landau levels and superconductivity,

M.J. Pacholski (30 September 2021). Subsequent employment: Max Planck Institute in Dresden.

Methods to simulate fermions on quantum computers with hardware limitations,

M. Steudtner (20 November 2019). Subsequent employment: Free University in Berlin.

Applications of topology to Weyl semimetals and quantum computing,

T.E. O'Brien (20 June 2019). Subsequent employment: Leiden University/Google Quantum AI.

On transport properties of Majorana fermions in superconductors: free & interacting,

N.V. Gnezdilov (12 June 2019). Subsequent employment: Yale University.

Spin-momentum locking in oxide interfaces and in Weyl semimetals,

N. Bovenzi (23 October 2018). Subsequent employmet: SIRIS Academic.

Lattice models for Josephson junctions and graphene superlattices,

V.P. Ostroukh (27 June 2018). Subsequent employment: Delft University of Technology.

On the random-matrix theory of Majorana fermions in topological superconductors,

M. Marciani (21 June 2017). Subsequent employment: University of Lyon.

On transport properties of Weyl semimetals,

P.S. Baireuther (26 April 2017). Subsequent employment: Bosch Center for Artificial Intelligence.

On periodically driven quantum systems,

B.M. Tarasinski (20 September 2016). Subsequent employment: Delft University of Technology.

On electronic signatures of topological superconductivity,

M. Diez (8 September 2015). Subsequent employment: Blue Yonder Analytics.

Quantum computation with Majorana modes in superconducting circuits,

B. van Heck (6 May 2015). Subsequent employment: Yale University.

Signatures of Majorana zero-modes in nanowires, quantum spin Hall edges, and quantum dots,

S. Mi (22 April 2015). Subsequent employment: Aalto University.

On topological properties of superconducting nanowires,

D.I. Pikulin (26 November 2013). Subsequent employment: University of British Columbia.

Scattering theory of topological phase transitions,

I.C. Fulga (21 November 2013). Subsequent employment: Weizmann Institute.

Random-matrix theory and stroboscopic models of topological insulators and superconductors,

J.P. Dahlhaus (21 November 2012). Subsequent employment: UC Berkeley.

Dirac and Majorana edge states in graphene and topological superconductors,

A.R. Akhmerov (31 May 2011). Subsequent employment: Harvard University.

On localization of Dirac fermions by disorder,

M.V. Medvedyeva (3 May 2011). Subsequent employment: Göttingen University.

Anomalous diffusion of Dirac fermions,

C.W. Groth (8 December 2010). Subsequent employment: CEA Grenoble.

Light scattering by photonic crystals with a Dirac spectrum,

R.A. Sepkhanov (20 May 2009). Subsequent employment: ASML.

Scattering problems involving electrons, photons, and Dirac fermions,

I. Snyman (23 September 2008). Subsequent employment: National Institute for Theoretical Physics (NITheP).

Effects of spin-orbit coupling on quantum transport,

J.H. Bardarson (4 June 2008). Subsequent employment: Cornell University.

On dephasing and spin decay in open quantum dots,

B.D. Michaelis (16 November 2006). Subsequent employment: Rheinisch-Westfälisches Elektrizitätswerk (RWE).

On the production and transfer of entangled electrons and photons,

J.L. van Velsen (28 September 2005). Subsequent employment: Ministry of Justice.

Superconductivity in nanostructures: Andreev billiards and Josephson junction qubits,

M.C. Goorden (15 September 2005). Subsequent employment: University of Geneva.

Study of a stroboscopic model of a quantum dot,

A. Tajic (12 May 2005). Subsequent employment: Philips Research Laboratories.

Electron counting statistics in nanostructures,

M. Kindermann (3 September 2003). Subsequent employment: Massachusetts Institute of Technology.

On chaotic wave dynamics,

K.J.H. van Bemmel (6 December 2001). Subsequent employment: Statistics Netherlands.

On quantum optics of random media,

M. Patra (6 September 2000). Subsequent employment: Helsinki University of Technology.

Opto-electronic properties of disordered organic semiconductors,

M.C.J.M. Vissenberg (28 January 1999). Subsequent employment: Philips Research Laboratories.

Thermal and electrical phenomena in chaotic conductors,

S.A. van Langen (3 September 1998). Subsequent employment: Philips Research Laboratories.

On the transmission of light through random media,

J.C.J. Paasschens (16 October 1997). Subsequent employment: Philips Research Laboratories.

Induced superconductivity in microstructures,

J.A. Melsen (18 June 1997). Subsequent employment: IBM Nederland.

On the random-matrix theory of quantum transport,

P.W. Brouwer (11 June 1997). Subsequent employment: Harvard University.

Shot noise and electrical conduction in mesoscopic systems,

M.J.M. de Jong (21 June 1995). Subsequent employment: Philips Research Laboratories.

On the conductivity of strongly correlated low-dimensional systems,

B. Rejaei-Salmassi (23 March 1994). Subsequent employment: Delft University of Technology.

Coulomb-blockade oscillations in quantum dots and wires,

A.A.M. Staring (5 November 1992). Subsequent employment: Philips Research Laboratories.

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