2.1. Injectors

The injector linac consists of a 250 MeV high-current linac, an electron/positron converter and a 900 MeV main linac. When we started work on the design, positrons were expected to be more appropriate than electrons in overcoming instabilities in the storage ring. Considering the experience at the ESRF, however, we decided to start commissioning with electrons and remove the e⁻/e⁺ converter. The linac has 26 accelerator columns which are of the 2π/3 travelling-wave and constant-gradient type. The average accelerating field is designed to be higher than 16 MV m⁻¹. One high-power klystron of 80 MW (Toshiba E3712) supplies microwaves to two accelerator columns. A modulator provides the klystron with a pulsed electric power of 190 MW of 4 µs width and at a repetition rate of 60 Hz. The beam commissioning started on 1 August and we succeeded in accelerating the beam to the final energy of 1 GeV on 8 August. However, the final energy of the beam was reached when the beam was injected into the synchrotron in December.

The booster synchrotron has 64 bending magnets, 80 quadrupole and 60 sextupole magnets and 80 steerers. The integrated field strength was measured for all bending magnets and the r.m.s. distribution is 8 × 10⁻⁴. All the magnets were aligned within an accuracy of 0.2 mm. Power supplies for these magnets are operated at 1 Hz. The typical time structure of the output current is as follows: 0.15 s flat-bottom for beam injection, 0.4 s ramping, 0.15 s flat-top for beam extraction, and 0.3 s falling. The tracking accuracy of the bending-magnet power supply is better than 1 × 10⁻⁴.

The RF system of the synchrotron consists of eight five-cell cavities, waveguides, two 508.58 MHz klystrons (Toshiba E3786) and their power supplies. The required maximum RF power is 1.69 MW at 8 GeV. The RF voltage changes from 8 to 18.7 MV during electron acceleration from 1 to 8 GeV. The five-cell cavity is made of OFHC copper and has an effective shunt impedance of 21 MΩ. The beam-position monitors are located at upstream positions of 80 quadrupole magnets. Four signal-processing systems are used for 80 beam-position monitors and it takes less than 30 ms to obtain all position data.

Installation of the synchrotron was completed in October and commissioning was started on 10 December 1996. We succeeded in extracting the 8 GeV electron beam to a beam dump on 27 January 1997.

2.2. Storage ring

The storage ring is a fourfold symmetric ring in its final form and the magnet lattice is of a Chasman–Green type with the modification of the inclusion of four long straight sections. In order to realize this ring we designed the storage ring to be composed of two types of unit cell, i.e. the normal cell and the straight cell. As shown in Fig. 3, the former consists of two bending magnets, ten quadrupole magnets and seven sextupole magnets and has a dispersion-free space of length 6 m (Fig. 3a). On the other hand, the latter has no bending magnet but has the same arrangement (Fig. 3b) of the focusing magnets as that of the normal cell; thereby both cells have approximately the same beam-dynamical property. In the first phase of operation, the storage ring will have a lattice structure of 4  × (11 normal cells + 1 straight cell) and be approximately 48-fold symmetric from a beam dynamical point of view. In this case, the operating mode of the storage ring is such that the β-function has low and high values alternately at neighbouring straight sections. In the second phase we will change the magnet arrangement of the straight cell to achieve a long dispersion-free space (Fig. 3c).

Figure 3 The arrangement of the magnets in (a) a normal cell and (b) a straight cell of the storage ring. The straight cell will be converted into a long straight section by rearranging the focusing magnets. (c) An example of a magnet arrangement in a long straight section. BM1–BM2: bending magnets; Q1–Q10: quadrupole magnets; S1–S7: sextupole magnets; ID: insertion device; CR1–CR2: crotches; AB1–AB2: absorbers.

The storage ring has 88 bending magnets, 480 quadrupole magnets and 336 sextupole magnets. Their measured r.m.s. distributions of integrated field strength and gradient are better than 5 × 10⁻⁴. The performance of the low-emittance ring depends strongly on the high quality of these magnets and their precise alignment. The magnetic centres of all the focusing magnets on the common girder are aligned within an accuracy of 0.05 mm. All bending magnets and common girders are aligned within 0.1 mm accuracy around the whole ring. The final surveying was completed in January 1997 and the standard deviation of the alignment errors found to be 0.04 mm. This accuracy was confirmed by using the injected electron beam during commissioning of the storage ring.

Three RF stations are installed. Each station is composed of eight single-cell cavities of the bell-shape type. The frequency of the higher-order mode (HOM) for each cavity can be controlled using two movable tuners and a plunger, keeping the fundamental frequency of 508.58 MHz constant. Then, HOM frequencies which could generate coupled-bunch instability can be well separated from cavity to cavity, so that the threshold current for coupled-bunch instability becomes higher than 200 mA.

A precise timing system coupling the injectors and the storage ring is needed for single-bunch or for few-bunch operation. By using optical fibres with low temperature-dependence and newly developed E/O (electrical to optical) and O/E modules, precise timing with time jitter of less than 10 ps is achieved.

The vacuum system for each unit cell consists of two bending-magnet chambers, three straight-section chambers, each of which is for the focusing magnets on one girder, two crotch chambers, one dummy chamber for an insertion device to be built in the future, and other components. All the chambers are made of aluminium alloy. The pumping system is based on non-evaporable getter strips, and sputter-ion pumps and distributed ion pumps are used as supplementary pumps. The final vacuum pressure reaches below 10 nPa.

Two beam-position monitors are welded directly to each straight-section chamber, giving a total number of 288. The beam-current monitors and a tune monitor are installed in the straight sections, together with absorbers, in order to avoid unnecessary irradiation by synchrotron radiation. Two types of current monitors are developed: one is a DC monitor of parametric current transformer type and is used to measure the DC component of the stored current with a resolution of 5 µA; the other is a pulse transformer with a signal processor to measure the charge of one bunch. The tune monitor consists of a beam shaker and its signal source, an amplifier, pick-up electrodes, signal-processing circuits and a spectrum analyser. All these monitors have been shown to work extremely well during storage-ring commissioning.

3.1. Beamlines

As can be seen in Fig. 3, SPring-8 has 44 straight sections, 40 of which are standard straight sections of length 6 m and four are long straight sections. One standard straight section is used for the injection of the electron beam, and four are used for the installation of RF stations. One standard straight section is reserved for the future installation of harmonic RF cavities to make the bunch width shorter. Therefore, 38 straight sections can be used to accommodate IDs, four of which will be long IDs. In addition to the beamlines from these IDs, we decided to build 23 beamlines from the bending magnets, so that 61 beamlines can be installed at SPring-8. Table 2 lists the beamlines at SPring-8.

A beamline is composed of three parts: a front-end channel, a transfer channel with the optical system, and the experimental stations. The front-end channels of all beamlines are installed in the storage-ring tunnel, whereas the transfer channels and the experimental stations are installed in hutches in the experimental hall. Most of the components of the front-end channels and the transfer channels are standardized.

The beamlines are divided into four groups according to the source types and source points, i.e. beamlines from IDs installed at low-β sections, those from IDs at high-β sections, those from IDs at the long straight sections, and beamlines from bending magnets.

The beamlines are also classified by users into four groups: public beamlines, contract beamlines, JAERI/RIKEN beamlines, and beamlines for R&D and machine study. The public beamlines are constructed by SPring-8 and are open for use by general users not only from Japan but worldwide. Institutions and industries can have their own beamlines, which are classified as contract beamlines, individually or in groups at Spring-8. In this case about 30% of the beam time should be open for general users. On the other hand, JAERI and RIKEN have the privilege as the constructor of Spring-8 to have beamlines (JAERI/RIKEN beamlines) for their own use. The Research Centre for Nuclear Physics, Osaka University, is proposing to build a `laser electron photon beamline' to study quark-nuclear physics using Compton backscattered laser photons from 8 GeV electrons.

In Table 3 are listed the beamlines under construction at SPring-8. There are 26 beamlines, i.e. 11 public, five contract, six JAERI/RIKEN, two R&D and two for machine study, and outlines of them are listed in Table 3.

3.2. IDs

IDs are the key technology for third-generation synchrotron radiation sources, especially for SPring-8. Most of the excellent features of synchrotron radiation, such as high brilliance, tunability over a wide energy range, polarization, coherence, small beam size, and short time structure of the beam, are also realized by IDs, in particular by undulators. New types of IDs have been developed at Spring-8 (Kitamura, 1998), as listed in Table 3.

The development of in-vacuum undulators has allowed us to obtain X-rays of energy up to 100 keV so that the serious problems of excessive heat-load can be substantially overcome. For example, an in-vacuum undulator with a period length λ_u = 32 mm can generate X-rays in the energy ranges 5.2–18 keV (first), 15.5–45 keV (third), and 26–60 keV (fifth) with brilliance higher than 10¹⁸ photons s⁻¹ mm⁻² mrad⁻² (0.1% bandwidth)⁻¹ by changing the gap from 25 mm to 8 mm. The performance of the first in-vacuum undulator shows that the brilliance of seventh harmonics is 80% of that calculated for the ideal undulator. As listed in Table 3, in-vacuum undulators are employed in the beamlines BL09XU, BL10XU, BL39XU, BL41XU and BL41XU.

An in-vacuum undulator has a vertical magnetic field and provides X-rays linearly polarized in the horizontal plane. A second type of in-vacuum undulator which generates a horizontal magnetic field has been developed at Spring-8 (BL45XU). A helical undulator, on the other hand, applies vertical and horizontal magnetic fields with an equal period length, and the electron beam therefore makes a spiral trajectory generating circularly polarized photons. It should be pointed out that the fundamental radiation travels along the axis of the helical undulator while higher harmonics radiation travels in off-axis directions. In the case where higher harmonics are not needed, it is an advantage to use this type of undulator. At Spring-8 the helical undulator is mainly applied to generate soft X-rays of several hundreds of eV. A twin-helical undulator, which consists of two identical helical undulators having opposite helicities and five kicker magnets, is used in BL25SU. In this undulator the helicity of the radiation is changed at a frequency of 10 Hz by switching five kicker magnets. Figure-8 undulators are another type of helical undulator used in BL27SU. This undulator is composed of horizontal and vertical undulators with period lengths of λ_u and 2λ_u, respectively. Then the radiations with opposite helicities interfere with each other to give linear polarization in the horizontal plane. The advantage of the Figure-8 undulator is that only the fundamental radiation travels along the undulator axis.

A variable-polarization undulator used in BL23SU is another type of undulator. In this undulator the upper and lower arrays of permanent magnets are split into two parts and each diagonal pair can be moved independently. The polarization of resulting radiation depends on the relative phase of the two pairs, whereas the energy can be changed by changing the gap. The relative phase is altered mechanically so that the helicity can be changed rapidly.

4.1. Accelerators

Commissioning of the storage ring commenced on 14 March 1997. Test operation of the whole accelerator system had been carried out for a week before the commissioning. On 14 March we injected the beam from the synchrotron to the storage ring. Soon after, we observed the first turn of the beam in the ring. Then we spent five days for fine adjustment of the beam-transport line from the synchrotron to the injection section of the ring. On 21 March we started again with on-axis injection and, after a beam-energy correction and tune survey, the sextupole magnets were excited. We observed 24 turns of the beam. On 25 March we started operation of the RF system. After a fine adjustment of the phase and frequency we succeeded in storing a beam of 0.05 mA. The lifetime of the beam was 7 h. On the next day, 26 March, we succeeded in observing the first synchrotron radiation from the front end of BM beamline BL02B1. We then made efforts to correct the closed orbit distortion (COD) and to increase the stored current. A target current of 20 mA was achieved on 17 April with a lifetime of 3 h.

Test operation of the in-vacuum undulator (BL47XU) was started on 22 April and we succeeded in observing the first radiation from the front end of BL47XU on 23 April. The spot size of the photon beam was ∼1 mm and did not move when the gap was changed from 50 mm to 20 mm.

The test operation of the accelerators for machine studies was continued during May and June. The beam lifetime at 20 mA has reached 30 h and it is now clear that the performance of the machine is extremely satisfactory.

4.2. Beamlines

The with-beam test of two beamlines, BL02B1 and BL47XU, was undertaken in June and we succeeded in extracting radiation direct to the experimental stations. In addition, two BM beamlines, BL01B1 and BL04B1, and three ID beamlines, BL09XU, BL41XU and BL45XU, were subsequently commissioned in July. We succeeded in extracting the photon beams to the experimental stations in all the beamlines and began performance testing of the monochromators. Preliminary data have now been obtained on BL02B1 and BL04B1 (Noda, 1998).